PMID-sentid Pub_year Sent_text comp_official_name comp_offset protein_name organism prot_offset 9570805-0 1998 A neuronal form of the cell adhesion molecule L1 contains a tyrosine-based signal required for sorting to the axonal growth cone. Tyrosine 60-68 L1 cell adhesion molecule Homo sapiens 46-48 9570805-10 1998 These data demonstrate that the neuronal form of L1 carries the tyrosine-based sorting signal YRSLE, which is critical for sorting L1 to the axonal growth cone. Tyrosine 64-72 L1 cell adhesion molecule Homo sapiens 49-51 9570805-10 1998 These data demonstrate that the neuronal form of L1 carries the tyrosine-based sorting signal YRSLE, which is critical for sorting L1 to the axonal growth cone. Tyrosine 64-72 L1 cell adhesion molecule Homo sapiens 131-133 9450593-6 1998 In addition, the water plant"s radium laden iron filters contributed 7 Bq L-1 and 60 Bq L-1 of 222Rn to the finished water in What Cheer, Iowa, and Wellman, Iowa, respectively. Iron 44-48 L1 cell adhesion molecule Homo sapiens 74-100 9521656-2 1998 Here we report the processing of a number of ubiquitin derivatives by two human UCH isozymes (isozymes L1 and L3) and find that these enzymes show little discrimination based on the P1" amino acid, except that proline is cleaved slowly. Proline 210-217 L1 cell adhesion molecule Homo sapiens 103-112 9450593-6 1998 In addition, the water plant"s radium laden iron filters contributed 7 Bq L-1 and 60 Bq L-1 of 222Rn to the finished water in What Cheer, Iowa, and Wellman, Iowa, respectively. Water 17-22 L1 cell adhesion molecule Homo sapiens 74-100 9396761-8 1997 Our findings suggest that physiological levels of calcium will impose a hierarchy of integrin binding to L1 such that alphavbeta3 or active alphaIIbbeta3 > alphavbeta1 > alpha5beta1. Calcium 50-57 L1 cell adhesion molecule Homo sapiens 105-107 9268105-2 1997 The two nonsense mutations (Gln440Ter and Gln1042Ter) result most likely in functional null-alleles and complete absence of L1CAM at the cell surface. gln440ter 28-37 L1 cell adhesion molecule Homo sapiens 124-129 9371782-4 1997 These findings suggest a general mechanism for the patterning of cell contact based on external signals that regulate tyrosine phosphorylation of L1CAM members and modulate their binding to ankyrin. Tyrosine 118-126 L1 cell adhesion molecule Homo sapiens 146-151 9396761-4 1997 Mutation of the single Arg-Gly-Asp (RGD) motif in human L1-Ig6 effectively abrogated binding by the aforementioned integrins. Arginine 23-26 L1 cell adhesion molecule Homo sapiens 56-62 9396761-4 1997 Mutation of the single Arg-Gly-Asp (RGD) motif in human L1-Ig6 effectively abrogated binding by the aforementioned integrins. Glycine 27-30 L1 cell adhesion molecule Homo sapiens 56-62 9396761-4 1997 Mutation of the single Arg-Gly-Asp (RGD) motif in human L1-Ig6 effectively abrogated binding by the aforementioned integrins. Aspartic Acid 31-34 L1 cell adhesion molecule Homo sapiens 56-62 9396761-6 1997 Whereas beta3 integrin binding to L1-Ig6 was evident in the presence of either Ca2+, Mg2+, or Mn2+, a corresponding interaction with the beta1 integrins was only observed in the presence of Mn2+. magnesium ion 85-89 L1 cell adhesion molecule Homo sapiens 34-40 9396761-6 1997 Whereas beta3 integrin binding to L1-Ig6 was evident in the presence of either Ca2+, Mg2+, or Mn2+, a corresponding interaction with the beta1 integrins was only observed in the presence of Mn2+. Manganese(2+) 94-98 L1 cell adhesion molecule Homo sapiens 34-40 9028334-2 1997 2-BDB-TcAMP is a reversible and competitive inhibitor (Ki = 5.5 mumol/L) of cAMP hydrolysis by PDE4a, 8-BDB-TcAMP irreversibly inactivates the enzyme in a time- and concentration-dependent manner with a second order rate constant of 0.022 mmol/L-1 min-1. 2-((4-bromo-2,3-dioxobutyl)thio)-adenosine 3'5'-cyclic monophosphate 0-11 L1 cell adhesion molecule Homo sapiens 244-253 9028334-2 1997 2-BDB-TcAMP is a reversible and competitive inhibitor (Ki = 5.5 mumol/L) of cAMP hydrolysis by PDE4a, 8-BDB-TcAMP irreversibly inactivates the enzyme in a time- and concentration-dependent manner with a second order rate constant of 0.022 mmol/L-1 min-1. Cyclic AMP 7-11 L1 cell adhesion molecule Homo sapiens 244-253 9028334-2 1997 2-BDB-TcAMP is a reversible and competitive inhibitor (Ki = 5.5 mumol/L) of cAMP hydrolysis by PDE4a, 8-BDB-TcAMP irreversibly inactivates the enzyme in a time- and concentration-dependent manner with a second order rate constant of 0.022 mmol/L-1 min-1. 8-((4-bromo-2,3-dioxobutyl)thio)-adenosine 3',5'-cyclic monophosphate 102-113 L1 cell adhesion molecule Homo sapiens 244-253 8897095-2 1996 We report herein a novel stereoselective synthetic route to L-1 and L-2, derivatives of 3-MPt and 3-MPc suitably protected for solid phase peptide synthesis. Peptides 139-146 L1 cell adhesion molecule Homo sapiens 60-71 9118141-5 1996 This mutation from adenine to guanine results in an amino acid change from lysine to glutamic acid at residue 655 of the L1CAM protein, which belongs to the fibronectin type III domain. Adenine 19-26 L1 cell adhesion molecule Homo sapiens 121-126 9118141-5 1996 This mutation from adenine to guanine results in an amino acid change from lysine to glutamic acid at residue 655 of the L1CAM protein, which belongs to the fibronectin type III domain. Guanine 30-37 L1 cell adhesion molecule Homo sapiens 121-126 8897095-6 1996 Conversion of L-7 to L-1 was accomplished in a one-pot sequence consisting of three steps: hydrolysis of the thiolacetate, formation of the thioether and hydrolysis of the methyl ester. Thien-2-ylacetate 109-121 L1 cell adhesion molecule Homo sapiens 21-24 8897095-6 1996 Conversion of L-7 to L-1 was accomplished in a one-pot sequence consisting of three steps: hydrolysis of the thiolacetate, formation of the thioether and hydrolysis of the methyl ester. Sulfides 140-149 L1 cell adhesion molecule Homo sapiens 21-24 8897095-6 1996 Conversion of L-7 to L-1 was accomplished in a one-pot sequence consisting of three steps: hydrolysis of the thiolacetate, formation of the thioether and hydrolysis of the methyl ester. methyl ester 172-184 L1 cell adhesion molecule Homo sapiens 21-24 8832713-3 1996 Chelation of Re-188 by stannous reduction of perrhenate in the presence of acyclic ligands such as L1 and L2 (L1 = ethylenediamine, L2 = 1,4,8,11-tetraazaundecane) proceeded in acceptable yield (50-90%) under aqueous conditions (pH 11; 20-100 degrees C, 30 min) in a single step. perrhenate 45-55 L1 cell adhesion molecule Homo sapiens 99-108 8832713-3 1996 Chelation of Re-188 by stannous reduction of perrhenate in the presence of acyclic ligands such as L1 and L2 (L1 = ethylenediamine, L2 = 1,4,8,11-tetraazaundecane) proceeded in acceptable yield (50-90%) under aqueous conditions (pH 11; 20-100 degrees C, 30 min) in a single step. ethylenediamine 115-130 L1 cell adhesion molecule Homo sapiens 99-108 8832713-3 1996 Chelation of Re-188 by stannous reduction of perrhenate in the presence of acyclic ligands such as L1 and L2 (L1 = ethylenediamine, L2 = 1,4,8,11-tetraazaundecane) proceeded in acceptable yield (50-90%) under aqueous conditions (pH 11; 20-100 degrees C, 30 min) in a single step. 8,11-tetraazaundecane 141-162 L1 cell adhesion molecule Homo sapiens 99-108 7591019-5 1995 In response to glucose ingestion microalbuminuric patients showed slight hyperglycemia (area under the curve, 928 +/- 43 versus 784 +/-19 nmol/L-1/2h-1, P < .02) and a marked hyperinsulinemia (26.8 +/- 3.3 versus 49.8 +/- 3.7 nmol/L-1/2h-1, P < 0.01). Glucose 15-22 L1 cell adhesion molecule Homo sapiens 143-151 8622793-6 1995 In six patients, tissue bicarbonate concentration increased from 18 to 20 meq L-1 (p < 0.05), indicating a 40-50% attenuation of the increase in hydrogen ion (H+) by nonbicarbonate buffering mechanisms. Bicarbonates 24-35 L1 cell adhesion molecule Homo sapiens 78-81 8622793-9 1995 Marked increases in H+ were seen when baseline bicarbonate decreased below 10 meq L-1. Bicarbonates 47-58 L1 cell adhesion molecule Homo sapiens 82-85 8582443-5 1995 Fasting plasma homocysteine concentrations (mean +/- SD) were significantly higher in postmenopausal women as compared to premenopausal women (12 +/- 4 mumol L-1 and 10 +/- 3 mumol L-1, respectively) as well as postmethionine plasma homocysteine concentrations (46 +/- 16 mumol L-1 and 32 +/- 9 mumol L-1, respectively). Homocysteine 15-27 L1 cell adhesion molecule Homo sapiens 158-184 7591019-5 1995 In response to glucose ingestion microalbuminuric patients showed slight hyperglycemia (area under the curve, 928 +/- 43 versus 784 +/-19 nmol/L-1/2h-1, P < .02) and a marked hyperinsulinemia (26.8 +/- 3.3 versus 49.8 +/- 3.7 nmol/L-1/2h-1, P < 0.01). Glucose 15-22 L1 cell adhesion molecule Homo sapiens 234-242 7473216-6 1995 for a dilute (40 g l-1) solution of glucose (LG, 230 mosmol kg-1) was 17 +/- 1 min. Glucose 36-43 L1 cell adhesion molecule Homo sapiens 19-22 7473216-8 1995 A concentrated (188 g l-1) glucose polymer solution (HP, 237 mosmol kg-1) emptied faster (t1/2 = 64 +/- 8 min) than the corresponding isoenergetic glucose solution (HG, 1300 mosmol kg-1, t1/2 = 130 +/- 18 min). Glucose 27-34 L1 cell adhesion molecule Homo sapiens 22-25 8091799-3 1994 The mean peak plasma inorganic fluoride concentration in the sevoflurane group was 19.5 +/- 13.4 mumol/L 1 hour after anesthesia, which decreased to preanesthetic levels 24 hours after anesthesia. inorganic fluoride 21-39 L1 cell adhesion molecule Homo sapiens 103-106 7767531-7 1995 Variables on the first and second parts of the control (C1 and C2) and lidocaine nights (L1 and L2) were compared during non-rapid eye movement sleep using the analysis of variance. Lidocaine 71-80 L1 cell adhesion molecule Homo sapiens 89-98 8091799-3 1994 The mean peak plasma inorganic fluoride concentration in the sevoflurane group was 19.5 +/- 13.4 mumol/L 1 hour after anesthesia, which decreased to preanesthetic levels 24 hours after anesthesia. Sevoflurane 61-72 L1 cell adhesion molecule Homo sapiens 103-106 8416964-5 1993 Two major peaks (L1 and L2) containing 3H- or 14C-labeled peptides were detected by reverse-phase high pressure liquid chromatography of the digest. Tritium 39-41 L1 cell adhesion molecule Homo sapiens 17-26 8455031-3 1993 Two Na(+)-independent L-like systems (L1 and L2), common to leucine and aromatic amino acids, were characterized kinetically. Leucine 60-67 L1 cell adhesion molecule Homo sapiens 38-47 8455031-3 1993 Two Na(+)-independent L-like systems (L1 and L2), common to leucine and aromatic amino acids, were characterized kinetically. Amino Acids, Aromatic 72-92 L1 cell adhesion molecule Homo sapiens 38-47 8312861-1 1993 In order to detect immunoreactive schizophyllan (SPG), one of the beta-1,3-glucans in solution, a murine anti-schizophyllan monoclonal antibody, SPG1-HS, was used as a primary antibody for solid-phase enzyme-linked immunosorbent assay (ELISA). Sizofiran 34-47 L1 cell adhesion molecule Homo sapiens 145-149 8472271-1 1993 OBJECTIVE: Calcium transients in muscles from patients with end stage heart failure consist of two components (L1 and L2) at physiological extracellular calcium concentrations ([Ca2+]o); the second component (L2) can appear in normal human myocardium at high [Ca2+]o. Calcium 11-18 L1 cell adhesion molecule Homo sapiens 111-120 8416964-5 1993 Two major peaks (L1 and L2) containing 3H- or 14C-labeled peptides were detected by reverse-phase high pressure liquid chromatography of the digest. Carbon-14 46-49 L1 cell adhesion molecule Homo sapiens 17-26 1527157-7 1992 Metabolic measurements showed that the increase of malondialdehyde measured in the coronary sinus 20 minutes after reperfusion was significantly (p = 0.014) less in the trimetazidine group (from 1.60 +/- 0.11 to 1.79 +/- 0.2 mumol/L-1) than in the placebo group (from 1.17 +/- 0.11 to 2.84 +/- 0.58 mumol/L-1). Trimetazidine 169-182 L1 cell adhesion molecule Homo sapiens 231-234 1527157-7 1992 Metabolic measurements showed that the increase of malondialdehyde measured in the coronary sinus 20 minutes after reperfusion was significantly (p = 0.014) less in the trimetazidine group (from 1.60 +/- 0.11 to 1.79 +/- 0.2 mumol/L-1) than in the placebo group (from 1.17 +/- 0.11 to 2.84 +/- 0.58 mumol/L-1). Trimetazidine 169-182 L1 cell adhesion molecule Homo sapiens 305-308 1593621-10 1992 Instead our results indicate that in the absence of efficient late protein synthesis 3" end formation occurs preferentially at the L1 and L4 poly(A) addition sites. Poly A 141-148 L1 cell adhesion molecule Homo sapiens 131-140 1321161-1 1992 This study evaluated the effect of L-1-oleoyl-2-acetyl-sn-3-glycerol (OAG) on ouabain-sensitive Na,K-dependent oxygen consumption (Na,K-QO2) in intact renal proximal tubule cells (RPTC). 1-oleoyl-2-acetylglycerol 70-73 L1 cell adhesion molecule Homo sapiens 35-38 1321161-1 1992 This study evaluated the effect of L-1-oleoyl-2-acetyl-sn-3-glycerol (OAG) on ouabain-sensitive Na,K-dependent oxygen consumption (Na,K-QO2) in intact renal proximal tubule cells (RPTC). Ouabain 78-85 L1 cell adhesion molecule Homo sapiens 35-38 1321161-1 1992 This study evaluated the effect of L-1-oleoyl-2-acetyl-sn-3-glycerol (OAG) on ouabain-sensitive Na,K-dependent oxygen consumption (Na,K-QO2) in intact renal proximal tubule cells (RPTC). Oxygen 111-117 L1 cell adhesion molecule Homo sapiens 35-38 1655409-7 1991 The protection at the L1 and R1 sites extends 12-13 bp beyond the Mu-host junctions as seen by DNase I and methidiumpropyl-EDTA.Fe(II) [MPE.Fe(II)] foot-printing, indicating Mu A contacts with the flanking host sequences in the transpososome but not on linear DNA; furthermore, hydroxyl radical footprinting shows an unprecedentedly large enhancement on the continuous strand, 2 bp beyond the nick site outside the Mu right end, which suggests that an altered DNA structure is induced upon Type 1 complex formation. methidiumpropyl-edta 107-127 L1 cell adhesion molecule Homo sapiens 22-31 1655409-7 1991 The protection at the L1 and R1 sites extends 12-13 bp beyond the Mu-host junctions as seen by DNase I and methidiumpropyl-EDTA.Fe(II) [MPE.Fe(II)] foot-printing, indicating Mu A contacts with the flanking host sequences in the transpososome but not on linear DNA; furthermore, hydroxyl radical footprinting shows an unprecedentedly large enhancement on the continuous strand, 2 bp beyond the nick site outside the Mu right end, which suggests that an altered DNA structure is induced upon Type 1 complex formation. ammonium ferrous sulfate 128-134 L1 cell adhesion molecule Homo sapiens 22-31 1655409-7 1991 The protection at the L1 and R1 sites extends 12-13 bp beyond the Mu-host junctions as seen by DNase I and methidiumpropyl-EDTA.Fe(II) [MPE.Fe(II)] foot-printing, indicating Mu A contacts with the flanking host sequences in the transpososome but not on linear DNA; furthermore, hydroxyl radical footprinting shows an unprecedentedly large enhancement on the continuous strand, 2 bp beyond the nick site outside the Mu right end, which suggests that an altered DNA structure is induced upon Type 1 complex formation. ammonium ferrous sulfate 140-146 L1 cell adhesion molecule Homo sapiens 22-31 1655409-7 1991 The protection at the L1 and R1 sites extends 12-13 bp beyond the Mu-host junctions as seen by DNase I and methidiumpropyl-EDTA.Fe(II) [MPE.Fe(II)] foot-printing, indicating Mu A contacts with the flanking host sequences in the transpososome but not on linear DNA; furthermore, hydroxyl radical footprinting shows an unprecedentedly large enhancement on the continuous strand, 2 bp beyond the nick site outside the Mu right end, which suggests that an altered DNA structure is induced upon Type 1 complex formation. Hydroxyl Radical 278-294 L1 cell adhesion molecule Homo sapiens 22-31 33812129-7 2021 Catalytic studies showed that the Ag-TiO2/RGO photocathode possessed a remarkable PEC CO2 reduction activity and selective production of CH3OH with a yield of 85 mumol L-1 cm-2, the quantum efficiency of 20% and Faradic efficiency of 60.5% at onset potential of -0.7 V. A plausible PEC CO2 reduction mechanism over Ag-TiO2/RGO photocathode is schematically demonstrated. ag-tio2 34-41 L1 cell adhesion molecule Homo sapiens 168-176 1724584-2 1991 A comparative evaluation of L-1 (acridanon) and amixin (fluorenon) showed L-1 to have more marked interferon-inducing properties. acridanon 33-42 L1 cell adhesion molecule Homo sapiens 74-77 1724584-2 1991 A comparative evaluation of L-1 (acridanon) and amixin (fluorenon) showed L-1 to have more marked interferon-inducing properties. Tilorone 48-54 L1 cell adhesion molecule Homo sapiens 74-77 1724584-2 1991 A comparative evaluation of L-1 (acridanon) and amixin (fluorenon) showed L-1 to have more marked interferon-inducing properties. fluoreneone 56-65 L1 cell adhesion molecule Homo sapiens 74-77 1724584-4 1991 L-1 induced IF synthesis most actively after subcutaneous inoculation, amixin after oral administration. Tilorone 71-77 L1 cell adhesion molecule Homo sapiens 0-3 2212309-10 1990 In both species, ADP growth as a function of stimulus level is approximately 1 with covaried stimuli; more gradual with the level of f2 (L 2) alone increasing and steeper when the level of f1 (L 1) alone is increased. Adenosine Diphosphate 17-20 L1 cell adhesion molecule Homo sapiens 180-196 1825965-5 1991 Preliminary studies using this technique show that basal skin water loss is significantly diminished in patients with established diabetic neuropathy (0.91 +/- 0.18 g (+/- SD) cm-2 h-1) compared with normal subjects (1.21 +/- 0.39 g cm-2 h-1; p = 0.04) and non-neuropathic diabetic subjects (1.32 +/- 0.48 g cm-2 h-1; p = 0.04), and that local sweating induced by iontophoresis of 10 g l-1 acetylcholine is significantly reduced in diabetic subjects up to 5 min of recording (0.95 +/- 0.43 vs 1.26 +/- 0.40 mg; p = 0.02). Water 62-67 L1 cell adhesion molecule Homo sapiens 386-389 2222041-3 1990 After simple clamping of the aorta, oxygen tension decreased significantly distal to the clamping site both after occlusion of the thoracic aorta at T3-4 (group 1) and after occlusion of the abdominal aorta at L-1 (group 2). Oxygen 36-42 L1 cell adhesion molecule Homo sapiens 210-213 33812129-7 2021 Catalytic studies showed that the Ag-TiO2/RGO photocathode possessed a remarkable PEC CO2 reduction activity and selective production of CH3OH with a yield of 85 mumol L-1 cm-2, the quantum efficiency of 20% and Faradic efficiency of 60.5% at onset potential of -0.7 V. A plausible PEC CO2 reduction mechanism over Ag-TiO2/RGO photocathode is schematically demonstrated. rgo photocathode 42-58 L1 cell adhesion molecule Homo sapiens 168-176 33812129-7 2021 Catalytic studies showed that the Ag-TiO2/RGO photocathode possessed a remarkable PEC CO2 reduction activity and selective production of CH3OH with a yield of 85 mumol L-1 cm-2, the quantum efficiency of 20% and Faradic efficiency of 60.5% at onset potential of -0.7 V. A plausible PEC CO2 reduction mechanism over Ag-TiO2/RGO photocathode is schematically demonstrated. Methanol 137-142 L1 cell adhesion molecule Homo sapiens 168-176 33812129-7 2021 Catalytic studies showed that the Ag-TiO2/RGO photocathode possessed a remarkable PEC CO2 reduction activity and selective production of CH3OH with a yield of 85 mumol L-1 cm-2, the quantum efficiency of 20% and Faradic efficiency of 60.5% at onset potential of -0.7 V. A plausible PEC CO2 reduction mechanism over Ag-TiO2/RGO photocathode is schematically demonstrated. rgo 42-45 L1 cell adhesion molecule Homo sapiens 168-176 33812129-7 2021 Catalytic studies showed that the Ag-TiO2/RGO photocathode possessed a remarkable PEC CO2 reduction activity and selective production of CH3OH with a yield of 85 mumol L-1 cm-2, the quantum efficiency of 20% and Faradic efficiency of 60.5% at onset potential of -0.7 V. A plausible PEC CO2 reduction mechanism over Ag-TiO2/RGO photocathode is schematically demonstrated. photocathode 46-58 L1 cell adhesion molecule Homo sapiens 168-176 33818537-2 2021 The finding of a potential correlation between high L1CAM expression and recurrent/metastatic disease in luminal A and B breast carcinomas may be helpful for risk stratification and open opportunities for targeted therapies. Phenobarbital 105-112 L1 cell adhesion molecule Homo sapiens 52-57 32889469-8 2021 After 25 days of treatment, a conversion of chlorinated organic compounds (COCs) of 50% was achieved (VL/Wsoil = 2, CPS = 40 g L-1, 40 C), whereas the application of PS activated by alkali and temperature (40 C) led to promising results. cocs 75-79 L1 cell adhesion molecule Homo sapiens 127-137 32797872-4 2020 Calibration curves were obtained for chlorpyrifos and carbaryl, with a useful concentration range from 0.24 to 20 mug L-1 for carbaryl and from 2.00 to 45 mug L-1 for chlorpyrifos. Chlorpyrifos 37-49 L1 cell adhesion molecule Homo sapiens 118-121 32797872-4 2020 Calibration curves were obtained for chlorpyrifos and carbaryl, with a useful concentration range from 0.24 to 20 mug L-1 for carbaryl and from 2.00 to 45 mug L-1 for chlorpyrifos. Carbaryl 54-62 L1 cell adhesion molecule Homo sapiens 118-121 32797872-4 2020 Calibration curves were obtained for chlorpyrifos and carbaryl, with a useful concentration range from 0.24 to 20 mug L-1 for carbaryl and from 2.00 to 45 mug L-1 for chlorpyrifos. Carbaryl 54-62 L1 cell adhesion molecule Homo sapiens 159-162 32797882-1 2020 An analytical method was developed for the direct determination of total mercury in natural waters at low ng L-1 level by inductively coupled plasma mass spectrometry (ICP-MS). Mercury 73-80 L1 cell adhesion molecule Homo sapiens 109-112 32797882-7 2020 The analysis of natural water samples showed that total mercury levels ranged from concentrations lower than the method detection limit (2.0 ng L-1) to 10.9 ng L-1. Water 24-29 L1 cell adhesion molecule Homo sapiens 160-163 32797882-7 2020 The analysis of natural water samples showed that total mercury levels ranged from concentrations lower than the method detection limit (2.0 ng L-1) to 10.9 ng L-1. Mercury 56-63 L1 cell adhesion molecule Homo sapiens 144-147 32797882-7 2020 The analysis of natural water samples showed that total mercury levels ranged from concentrations lower than the method detection limit (2.0 ng L-1) to 10.9 ng L-1. Mercury 56-63 L1 cell adhesion molecule Homo sapiens 160-163 32797882-9 2020 To our knowledge, the developed method is the first ICP-MS method for the analysis of humic-rich natural water samples at ng L-1 concentrations without the need for hyphenated techniques or preconcentration procedures. Water 105-110 L1 cell adhesion molecule Homo sapiens 125-128 34537431-5 2022 LOD and LOQ varied from 1.60 ng L-1 (estradiol, E2) to 23.2 ng L-1 (dimethylphthalate, DMP) and from 5.33 ng L-1 (E2) to 77.3 ng L-1 (DMP). Unithiol 134-137 L1 cell adhesion molecule Homo sapiens 109-132 34662577-4 2022 Average Mn and Cu concentrations in groundwater were 19.92 mug L-1 and 7.05 mug L-1 with an increasing trend from west to east, whereas Fe concentration in central regions was much higher (34.23 mug L-1). Copper 15-17 L1 cell adhesion molecule Homo sapiens 63-72 34771652-0 2021 Inhibiting Lysine Demethylase 1A Improves L1CAM-Specific CAR T Cell Therapy by Unleashing Antigen-Independent Killing via the FAS-FASL Axis. Lysine 11-17 L1 cell adhesion molecule Homo sapiens 42-47 34600928-5 2022 Annual average TP concentrations (deposition rates) were 0.07 (0.61), 0.49 (3.22), 0.17 (1.07) and 0.01 (0.20) mg L-1 (kg ha-1 yr-1), at CD, SF, YT and GG, respectively. tp 15-17 L1 cell adhesion molecule Homo sapiens 114-131 34855343-3 2021 The hierarchical nanoparticles (MPH-NP@A) are composed of pH-sensitive hyaluronic acid-acetal-PTX prodrugs (HA-ace-PTX(SH)) chaperoned by alphaPD-L1 and metalloproteinase-9 (MMP-9)-responsive outer shells, which could be fast cleaved to release alphaPD-L1 in the tumor microenvironment (TME). Hyaluronic Acid 71-86 L1 cell adhesion molecule Homo sapiens 146-172 34855343-3 2021 The hierarchical nanoparticles (MPH-NP@A) are composed of pH-sensitive hyaluronic acid-acetal-PTX prodrugs (HA-ace-PTX(SH)) chaperoned by alphaPD-L1 and metalloproteinase-9 (MMP-9)-responsive outer shells, which could be fast cleaved to release alphaPD-L1 in the tumor microenvironment (TME). Paclitaxel 94-97 L1 cell adhesion molecule Homo sapiens 146-172 34855343-3 2021 The hierarchical nanoparticles (MPH-NP@A) are composed of pH-sensitive hyaluronic acid-acetal-PTX prodrugs (HA-ace-PTX(SH)) chaperoned by alphaPD-L1 and metalloproteinase-9 (MMP-9)-responsive outer shells, which could be fast cleaved to release alphaPD-L1 in the tumor microenvironment (TME). Paclitaxel 115-118 L1 cell adhesion molecule Homo sapiens 146-172 34155585-11 2021 In addition, compared with 2004, UDS decreased by 85% in 2016, and the contribution of UDS to BOD and F. coli decreased by 0.7 mg L-1 and 887 cfu L-1, respectively. uds 87-90 L1 cell adhesion molecule Homo sapiens 130-149 34700330-1 2021 Two luminescent Cd(II)-organic frameworks (Cd2(L1)(tdc)2(H2O))n (1) and (Cd(L2)0.5(tdc))n (2) (L1 = 1,5-bis(1-(pyridine-4-ylmethyl)-1H-benzo(d)imidazol-2-yl)pentane, L2 = 1,6-bis(1-(pyridine-4-ylmethyl)-1H-benzo(d)imidazol-2-yl)hexane, and H2tdc = 2,5-thiophenedicarboxylic acid) were hydrothermally synthesized and characterized. Water 57-60 L1 cell adhesion molecule Homo sapiens 43-49 34668076-7 2021 The calibration curve showed a linear range of 1 to 70 microg L-1 and 1 to 70 micromol L-1 for Zn2+ and UA, respectively. Zinc 95-99 L1 cell adhesion molecule Homo sapiens 62-71 34668076-7 2021 The calibration curve showed a linear range of 1 to 70 microg L-1 and 1 to 70 micromol L-1 for Zn2+ and UA, respectively. Uric Acid 104-106 L1 cell adhesion molecule Homo sapiens 62-71 34668076-9 2021 The detection limits for Zn2+ and UA were 0.10 microg L-1 and 0.28 micromol L-1, respectively. Zinc 25-29 L1 cell adhesion molecule Homo sapiens 54-63 35381537-6 2022 The sensor was successfully used for detection of curcumin in the ranges of 0.1-1 micromol L-1 and 1-30 micromol L-1, with acceptable detection limit (30 nmol L-1). Curcumin 50-58 L1 cell adhesion molecule Homo sapiens 91-100 34760204-4 2021 In(tcpp) exhibits high sensitivity and selectivity for turn-on detection of F- and turn-off detection of PFOA with a detection limit of 1.3 mug L-1 and 19 mug L-1, respectively. tetracarboxyphenylporphine 3-7 L1 cell adhesion molecule Homo sapiens 144-154 34465086-4 2021 Slope analysis indicated that Th(IV) was extracted as different species under different HNO3 concentrations, in which the slopes were 2.08 +- 0.20, 1.61 +- 0.03, and 1.54 +- 0.03 for L1 and 2.37 +- 0.22, 2.07 +- 0.17, and 1.76 +- 0.18 for L2 under 0.1, 1.0, and 3.0 M HNO3, respectively. Nitric Acid 88-92 L1 cell adhesion molecule Homo sapiens 183-191 34465086-4 2021 Slope analysis indicated that Th(IV) was extracted as different species under different HNO3 concentrations, in which the slopes were 2.08 +- 0.20, 1.61 +- 0.03, and 1.54 +- 0.03 for L1 and 2.37 +- 0.22, 2.07 +- 0.17, and 1.76 +- 0.18 for L2 under 0.1, 1.0, and 3.0 M HNO3, respectively. Nitric Acid 268-272 L1 cell adhesion molecule Homo sapiens 183-191 34465086-5 2021 A continuous variation method (Job plot) illustrated a 1.5:1 ligand/thorium (L/Th) ratio in a methanol phase, indicating that L1/L2 and Th(IV) could form mixed 1:1 and 2:1 L/Th extracted complexes. Thorium 68-75 L1 cell adhesion molecule Homo sapiens 126-131 34465086-5 2021 A continuous variation method (Job plot) illustrated a 1.5:1 ligand/thorium (L/Th) ratio in a methanol phase, indicating that L1/L2 and Th(IV) could form mixed 1:1 and 2:1 L/Th extracted complexes. Thorium 79-81 L1 cell adhesion molecule Homo sapiens 126-131 34465086-5 2021 A continuous variation method (Job plot) illustrated a 1.5:1 ligand/thorium (L/Th) ratio in a methanol phase, indicating that L1/L2 and Th(IV) could form mixed 1:1 and 2:1 L/Th extracted complexes. Methanol 94-102 L1 cell adhesion molecule Homo sapiens 126-131 34085518-1 2021 The synthesis of argentivorous molecules (L1and L2) having two chromophores (4-(anthracen-9-yl)benzyl or 4-(pyren-1-yl)benzyl groups) and two benzyl groups and the fluorescence properties of their silver complexes in a solution and the solid state are reported. Silver 197-203 L1 cell adhesion molecule Homo sapiens 42-50 34078883-2 2021 Here, we find that vascular endothelial cells (ECs) with persistent DNA damage induced by irradiation and Dox treatment exhibit a fibrotic phenotype (endothelial-mesenchymal transition, EndMT) correlating with the colocalization of L1CAM and persistent DNA damage foci. Doxorubicin 106-109 L1 cell adhesion molecule Homo sapiens 232-237 34078883-6 2021 We show that cardiomyopathy patient-derived cardiovascular ECs with persistent DNA damage show upregulated L1CAM and EndMT, indicating clinical applicability of Ab417. ab417 161-166 L1 cell adhesion molecule Homo sapiens 107-112 35526683-4 2022 Experimental results showed that after 46 days of operation, the steady flux of the O-LPM systems were 1.87-fold and 1.74-fold higher than that of the conventional D-LPM systems under Mn2+ concentration of 0.3 mg L-1 and 1.5 mg L-1, respectively. Manganese(2+) 184-188 L1 cell adhesion molecule Homo sapiens 213-224 34380733-6 2021 Mechanistically, we find that CWH43 deletion leads to decreased N-glycosylation of L1CAM, decreased association of L1CAM with cell membrane lipid microdomains, increased L1CAM cleavage by plasmin, and increased shedding of cleaved L1CAM in the cerebrospinal fluid. Nitrogen 64-65 L1 cell adhesion molecule Homo sapiens 83-88 35429348-0 2022 L1CAM expression as a predictor of platinum response in high-risk endometrial carcinoma. Platinum 35-43 L1 cell adhesion molecule Homo sapiens 0-5 35429348-5 2022 The association between L1CAM and clinicopathologic features and L1CAM additive value in predicting platinum response were determined. Platinum 100-108 L1 cell adhesion molecule Homo sapiens 24-29 35429348-5 2022 The association between L1CAM and clinicopathologic features and L1CAM additive value in predicting platinum response were determined. Platinum 100-108 L1 cell adhesion molecule Homo sapiens 65-70 35429348-6 2022 The effect of L1CAM gene silencing on response to carboplatin was functionally tested on primary L1CAM-expressing cells. Carboplatin 50-61 L1 cell adhesion molecule Homo sapiens 14-19 35429348-7 2022 Increased L1CAM expression at both genetic and protein level correlated with high-grade, non-endometrioid histology and poor response to platinum treatment. Platinum 137-145 L1 cell adhesion molecule Homo sapiens 10-15 35429348-8 2022 A predictive model adding L1CAM to prognostic clinical variables significantly improved platinum response prediction (C-index 78.1%, p=0.012). Platinum 88-96 L1 cell adhesion molecule Homo sapiens 26-31 35429348-10 2022 In vitro, inhibition of L1CAM significantly increased cell sensitivity to carboplatin, supporting a mechanistic link between L1CAM expression and response to platinum in EC cells. Carboplatin 74-85 L1 cell adhesion molecule Homo sapiens 24-29 35429348-10 2022 In vitro, inhibition of L1CAM significantly increased cell sensitivity to carboplatin, supporting a mechanistic link between L1CAM expression and response to platinum in EC cells. Carboplatin 74-85 L1 cell adhesion molecule Homo sapiens 125-130 35429348-10 2022 In vitro, inhibition of L1CAM significantly increased cell sensitivity to carboplatin, supporting a mechanistic link between L1CAM expression and response to platinum in EC cells. Platinum 158-166 L1 cell adhesion molecule Homo sapiens 125-130 35348910-7 2022 p65 displayed the highest specificity (93.8%), while L1CAM had the highest sensitivity (92.3%) in detecting ZFTA fusions. zfta 108-112 L1 cell adhesion molecule Homo sapiens 53-58 35240169-6 2022 This decrease in current (DeltaI) had a linear relationship with the nitrite concentration in the range of 0.1 to 1 mg L-1 and 1 to 10 mg L-1, which was corresponding to the sensitivities of 48.62 and 2.24 muA mM-1 cm-2, respectively. Nitrites 69-76 L1 cell adhesion molecule Homo sapiens 119-128 35339545-3 2022 Our results showed that this material had superior catalytic performances with a complete removal of 4-CP (50 mg L-1) and Cr(VI) (10 mg L-1) within 60 and 1 min, respectively. chromium hexavalent ion 122-128 L1 cell adhesion molecule Homo sapiens 136-156 35278443-10 2022 Using the same tartaric acid/Cr(VI) molar ratio (6:1) and pH 3.0, the Cr(VI) present in the effluent was totally reduced (below detection limit) in 360 min (k = 1.93 x 10-2 mg L- 1 min- 1), showing similar kinetic behavior as the process with the synthetic matrix. Chromium 70-72 L1 cell adhesion molecule Homo sapiens 176-187 35266301-8 2022 Under these optimal conditions, the limits of detection and limits of quantitation determined were in the range of 0.5-2.8 mug L-1 and 1.5-9 mug L-1 , for water, urine and plasma samples, respectively. Water 155-160 L1 cell adhesion molecule Homo sapiens 127-140 35473609-0 2022 Tryptophan hydroxylase 1 drives glioma progression by modulating the serotonin/L1CAM/NF-kappaB signaling pathway. Serotonin 69-78 L1 cell adhesion molecule Homo sapiens 79-84 35397913-6 2022 For cadmium the above mentioned figure of merits were 0.3-980, 0.9969, 0.15 mug L-1 and 2.4%, respectively. Cadmium 4-11 L1 cell adhesion molecule Homo sapiens 80-89 35473609-10 2022 The elevated serotonin levels then augmented the NF-kappaB signaling pathway through the upregulation of the L1-cell adhesion molecule (L1CAM), thereby contributing to cellular proliferation, invasive migration, and drug resistance. Serotonin 13-22 L1 cell adhesion molecule Homo sapiens 109-134 35473609-10 2022 The elevated serotonin levels then augmented the NF-kappaB signaling pathway through the upregulation of the L1-cell adhesion molecule (L1CAM), thereby contributing to cellular proliferation, invasive migration, and drug resistance. Serotonin 13-22 L1 cell adhesion molecule Homo sapiens 136-141 35473609-12 2022 CONCLUSION: Taken together, these data suggested that TPH-1 facilitated cellular proliferation, migration, and chemoresistance in glioma through the serotonin/L1CAM/NF-kappaB pathway. Serotonin 149-158 L1 cell adhesion molecule Homo sapiens 159-164 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. ab-29 36-41 L1 cell adhesion molecule Homo sapiens 111-120 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. ab-29 36-41 L1 cell adhesion molecule Homo sapiens 193-202 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. ab-29 36-41 L1 cell adhesion molecule Homo sapiens 229-238 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. cadmium sulfide 72-75 L1 cell adhesion molecule Homo sapiens 111-120 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. cadmium sulfide 72-75 L1 cell adhesion molecule Homo sapiens 193-202 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. cadmium sulfide 72-75 L1 cell adhesion molecule Homo sapiens 229-238 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. titanium dioxide 76-80 L1 cell adhesion molecule Homo sapiens 111-120 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. titanium dioxide 76-80 L1 cell adhesion molecule Homo sapiens 193-202 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. titanium dioxide 76-80 L1 cell adhesion molecule Homo sapiens 229-238 35388044-9 2022 The observed decolorization rate of AB-29 is also higher in the case of CdS-TiO2 photocatalyst ~ 5.8 x 10-4mol L-1 min-1) as compared to the reported decolorization rate of CdS ~ 4.5 x 10-4mol L-1 min-1 and TiO2 ~ 0.67 x 10-4mol L-1 min-1. titanium dioxide 207-211 L1 cell adhesion molecule Homo sapiens 111-120 35234668-7 2022 APPROACH: In this work, we proposed a novel ADTF, which solves the dynamic system in the L1-norm space (L1-ADTF), so as to restrict the outlier influence. adtf 44-48 L1 cell adhesion molecule Homo sapiens 104-111 35040385-0 2022 Inhibiting L1CAM Reverses Cisplatin Resistance of Triple Negative Breast Cancer Cells by Blocking AKT Signaling Pathway. Cisplatin 26-35 L1 cell adhesion molecule Homo sapiens 11-16 35040385-4 2022 Moreover, SC79 (an AKT activator) increased the DDP-resistance of MDA-MB-231/DDP cells, which was reversed by L1CAM inhibition. Cisplatin 48-51 L1 cell adhesion molecule Homo sapiens 110-115 35243964-7 2022 After one session of RF treatment, the mean zygomatic length ratio (L1/L2) from the middle third of the face significantly increased in the 4th week (by 49.68%, P = .047). arginylphenylalanine 21-23 L1 cell adhesion molecule Homo sapiens 68-73 35517416-7 2022 The effect of Integrin beta1 and L1 cell adhesion molecule (L1CAM) on cisplatin resistance was detected by MTS and the signal pathways involved were analyzed by Western blotting. Cisplatin 70-79 L1 cell adhesion molecule Homo sapiens 33-58 35517416-7 2022 The effect of Integrin beta1 and L1 cell adhesion molecule (L1CAM) on cisplatin resistance was detected by MTS and the signal pathways involved were analyzed by Western blotting. Cisplatin 70-79 L1 cell adhesion molecule Homo sapiens 60-65 35517416-12 2022 Simultaneous knockdown of Integrin beta1 and L1CAM reduced the cisplatin resistance of ESCC cells. Cisplatin 63-72 L1 cell adhesion molecule Homo sapiens 45-50 35517416-13 2022 Further studies showed that knockdown of Integrin beta1 and L1CAM suppressed the activity of Akt signaling with or without cisplatin treatment. Cisplatin 123-132 L1 cell adhesion molecule Homo sapiens 60-65 2562992-4 1989 In both early and late stages of infection, either polyadenylation site (L1 or L3) is capable of being utilized when presented as the only operational poly(A) site. Poly A 151-158 L1 cell adhesion molecule Homo sapiens 73-81 35244146-9 2022 The Tyr-based motif is conserved in human L1CAM but had not previously been assigned a function. Tyrosine 4-7 L1 cell adhesion molecule Homo sapiens 42-47 2777544-3 1989 The average concentration of Th found in the blood serum and urine of subjects from normal environments is 7.9 ng L-1 and 2.7 ng L-1, respectively. Thorium 0-2 L1 cell adhesion molecule Homo sapiens 114-123 2777544-3 1989 The average concentration of Th found in the blood serum and urine of subjects from normal environments is 7.9 ng L-1 and 2.7 ng L-1, respectively. Thorium 0-2 L1 cell adhesion molecule Homo sapiens 114-117 2506926-9 1989 Protein-mediated 3-O-methyl-alpha-D-glucopyranoside (3OMG) uptake by intact human red blood cells (lacking intracellular sugar) at ice temperature in isotonic KCl containing 2 mM MgCl2, 2 mM EGTA, and 5 mM Tris-HCl, pH 7.4 (KCl medium), is characterized by a Km(app) of 0.4 +/- 0.1 mM and a Vmax of 114 +/- 20 mumol L-1 min-1. 3-O-Methyl-D-glucopyranose 17-51 L1 cell adhesion molecule Homo sapiens 316-325 2506926-10 1989 Lysis of red cells in 40 volumes of EGTA-containing hypotonic medium and resealing in 10 volumes of KCl medium increase the Km(app) and Vmax for uptake to 7.1 +/- 1.8 mM and 841 +/- 191 mumol L-1 min-1, respectively. Potassium Chloride 100-103 L1 cell adhesion molecule Homo sapiens 192-201 2506926-11 1989 Addition of ATP (4 mM) to the resealing medium restores Michaelis and velocity constants for zero-trans 3OMG uptake to 0.42 +/- 0.11 mM and 110 +/- 15 mumol L-1 min-1, respectively. Adenosine Triphosphate 12-15 L1 cell adhesion molecule Homo sapiens 157-166 2713497-2 1989 The 125I-labeled antibody bound to 4 to 5 x 10(3) and 2.5 to 3 x 10(3) antigenic sites on K1K1 and K1K2 erythrocytes, respectively, with an affinity constant of 5 x 10(8) mol/L-1. Iodine-125 4-8 L1 cell adhesion molecule Homo sapiens 175-178 7194491-1 1981 L-1-tosylamido-2-phenylethyl chloromethyl ketone (TPCK) was found to inhibit several aspects of arachidonic acid (20:4) metabolism in human platelets; the primary effect being inhibition of thromboxane synthetase. Arachidonic Acid 96-112 L1 cell adhesion molecule Homo sapiens 0-3 4074620-2 1985 Plasma concentrations ranged from 35-68 microgram l-1 for doxepin and 65-131 microgram l-1 for N-desmethyldoxepin. desmethyldoxepin 95-113 L1 cell adhesion molecule Homo sapiens 87-90 4074620-4 1985 Only N-desmethyldoxepin (15 microgram l-1) was detectable in the infant"s plasma sampled after 43 days of maternal therapy. desmethyldoxepin 5-23 L1 cell adhesion molecule Homo sapiens 38-41 6895979-2 1982 Single doses of 0.1 mg of fentanyl were given epidurally via an indwelling catheter inserted between L1/L2 or L2/L3 or, in the case of 7 patients with multiple rib fractures, between Th8/Th9. Fentanyl 26-34 L1 cell adhesion molecule Homo sapiens 101-106 4065357-3 1985 Ryanodine strongly reduced the twitch and both components of the intracellular aequorin luminescence signal (L1 and L2), which normally accompanies contraction. Ryanodine 0-9 L1 cell adhesion molecule Homo sapiens 109-118 6411837-5 1983 Glucosamine/galactosamine molar ratios of disc proteoglycan were higher in the L1/L2 disc than the L4/L5 disc. Glucosamine 0-11 L1 cell adhesion molecule Homo sapiens 79-84 6411837-5 1983 Glucosamine/galactosamine molar ratios of disc proteoglycan were higher in the L1/L2 disc than the L4/L5 disc. Galactosamine 12-25 L1 cell adhesion molecule Homo sapiens 79-84 413278-1 1977 Lipoxygenase isoenzymes L-1 (optimum pH 9.0) and L-2 (pH 6.5) were incubated with linoleic acid. Linoleic Acid 82-95 L1 cell adhesion molecule Homo sapiens 24-27 413278-4 1977 L-1 yielded hexanal (greater than 90% at pH 7 and 70% at pH 8.5). n-hexanal 12-19 L1 cell adhesion molecule Homo sapiens 0-3 33667423-5 2021 Formalin-fixed paraffin-embedded tissues derived from patients were used for immunohistochemical staining of L1CAM, BAP1, MTAP, and HEG1 in 51 uterine AT cases, 34 pleural or peritoneal MM cases, and for next-generation sequencing of the TRAF7 gene in 44 AT cases and 21 MM cases. Formaldehyde 0-8 L1 cell adhesion molecule Homo sapiens 109-114 33984774-4 2021 With an initial RhB and Cr(VI) concentration of 7 mg L-1 and 5 mg L-1, the catalyst 10Ag@C-TCZ achieved a simultaneous removal of 95.2% and 95.5% within 120 min, respectively. chromium hexavalent ion 24-30 L1 cell adhesion molecule Homo sapiens 53-62 33984774-4 2021 With an initial RhB and Cr(VI) concentration of 7 mg L-1 and 5 mg L-1, the catalyst 10Ag@C-TCZ achieved a simultaneous removal of 95.2% and 95.5% within 120 min, respectively. c-tcz 89-94 L1 cell adhesion molecule Homo sapiens 53-62 33677269-8 2021 Under these conditions 100% MCPA removal was achieved (to the limit of HPLC detection) after 45 min irradiation at a degradation rate of ~1 mg L-1 min-1 (nphoton = 4.4), which also resulted in a ~83% reduction in CMP formation when compared to a system with no H2O2 present. 2-Methyl-4-chlorophenoxyacetic Acid 28-32 L1 cell adhesion molecule Homo sapiens 143-152 33677269-8 2021 Under these conditions 100% MCPA removal was achieved (to the limit of HPLC detection) after 45 min irradiation at a degradation rate of ~1 mg L-1 min-1 (nphoton = 4.4), which also resulted in a ~83% reduction in CMP formation when compared to a system with no H2O2 present. 4-chloro-2-cresol 213-216 L1 cell adhesion molecule Homo sapiens 143-152 33677269-8 2021 Under these conditions 100% MCPA removal was achieved (to the limit of HPLC detection) after 45 min irradiation at a degradation rate of ~1 mg L-1 min-1 (nphoton = 4.4), which also resulted in a ~83% reduction in CMP formation when compared to a system with no H2O2 present. Hydrogen Peroxide 261-265 L1 cell adhesion molecule Homo sapiens 143-152 33677279-7 2021 AnMBR was able to produce permeate water with an average COD of 51 +- 8 mg L-1 at an HRT of 2 d during the summer period with an average temperature of 24 C. The effluent COD increased to 67 +- 10 mg L-1 and reached 91 +- 5 mg L-1 for HRT 1 d and 12 h respectively for the same temperature range. Water 35-40 L1 cell adhesion molecule Homo sapiens 201-231 33082000-8 2021 The results showed that the optimum values for applied current, pH, initial pharmaceutical concentration and electrolysis time were respectively 300 mA, 7, 30 mg L-1 and 100 min, resulting 99.60% of SU removal. Sulfasalazine 199-201 L1 cell adhesion molecule Homo sapiens 162-177 32627394-6 2021 This method showed good linearity for bisphenol A in the range of 0.033-1000 mug L-1 , with the coefficient of determination of 0.9984. bisphenol A 38-49 L1 cell adhesion molecule Homo sapiens 81-84 33712944-6 2021 Suspended particles and phosphates proved to be important parameters with concentrations approximately lower than 88 mg L-1 and 11 mg L-1, respectively, for a good biodiversity index of zooplankton. Phosphates 24-34 L1 cell adhesion molecule Homo sapiens 120-137 33360623-2 2021 Stearic acid (SA) was used for the esterification of SPG with two degrees of substitutions (SA-SPG0.5 and SA-SPG1). stearic acid 0-12 L1 cell adhesion molecule Homo sapiens 109-113 33360623-2 2021 Stearic acid (SA) was used for the esterification of SPG with two degrees of substitutions (SA-SPG0.5 and SA-SPG1). stearic acid 14-16 L1 cell adhesion molecule Homo sapiens 109-113 33655629-7 2021 With the addition of the DCMD-2, the ammonia concentration was improved from 3 g L-1 to 7.8 +- 0.2 g L-1 , which was further enhanced to 26.3 +- 3.0 g L-1 after five batches of operation. Ammonia 37-44 L1 cell adhesion molecule Homo sapiens 81-91 32858384-4 2021 Under the optimized conditions, the M-HAzo based method exhibited good performance in terms of linear range (0.3-50.0 mug L-1), detection limit (0.08-0.50 mug L-1), accuracy (recovery of 78.0-115.0%) and repeatability (relative standard deviation of 2.9-7.8%). m-hazo 36-42 L1 cell adhesion molecule Homo sapiens 122-125 32858384-4 2021 Under the optimized conditions, the M-HAzo based method exhibited good performance in terms of linear range (0.3-50.0 mug L-1), detection limit (0.08-0.50 mug L-1), accuracy (recovery of 78.0-115.0%) and repeatability (relative standard deviation of 2.9-7.8%). m-hazo 36-42 L1 cell adhesion molecule Homo sapiens 159-162 33245078-6 2021 The limit of detection and limit of quantitation of Gly were found to be 5 mug L-1 and 10 mug L-1, respectively. glyphosate 52-55 L1 cell adhesion molecule Homo sapiens 79-89 33231936-2 2021 When O 2 and H 2 O are present, (1-methyl-1H-benzo[d]imidazole-2-carbonyl)amide ( HL1" ) is first formed and crystallized as [Co III ( L1 ) 2 ( L1" )]Cl 2 2H 2 O ( 4 ) before fusion of H L1" with L1 giving 1-methyl-N-(1-methyl-1H-benzo[d]imidazol-2-carbonyl)-1H-benzo[d]imidazol-2-carboxamide ( HL2"" ) forming one-dimensional (1D) chain of [Co II 3 ( L2"" ) 2 Cl 4 ] n ( 5 ). h 2 o 13-18 L1 cell adhesion molecule Homo sapiens 126-147 32679416-3 2020 Taking an adsorption time of 15 min, detection limits of 0.04 mug L -1 and 0.2 mug L-1and 7.9 mug L-1and enrichment factors of 145 and 110 were obtained for Mn(II) and Zn(II), respectively.The method was successfully applied to the analysis of Mn(II) and Zn(II) in foods and vegetables. Manganese(2+) 157-163 L1 cell adhesion molecule Homo sapiens 83-93 32996287-3 2021 The model shows that this system can achieve a biomass productivity of ~1.7 g L -1 hr -1 but is limited by a competitive trade-off between O 2 gas/liquid mass transfer and CO 2 transport to the cathode. Oxygen 139-142 L1 cell adhesion molecule Homo sapiens 78-88 32996287-3 2021 The model shows that this system can achieve a biomass productivity of ~1.7 g L -1 hr -1 but is limited by a competitive trade-off between O 2 gas/liquid mass transfer and CO 2 transport to the cathode. Carbon Dioxide 172-176 L1 cell adhesion molecule Homo sapiens 78-88 32818693-8 2020 The absence of a matrix effect was confirmed by the standard addition method, and the copper content in three artisanal cachacas from different geographical origins was estimated as lower than 2.93 mg L-1. Copper 86-92 L1 cell adhesion molecule Homo sapiens 201-204 32854085-6 2020 Good linearity (R2 > 0.99) ranges of 0.05 to 5 mg L-1 for nitrite and 1 to 50 mg L-1 for nitrate were obtained and detection limits of 50 mug L-1 for nitrite and 0.32 mg L-1 for nitrate were achieved. Nitrites 58-65 L1 cell adhesion molecule Homo sapiens 50-53 32854085-6 2020 Good linearity (R2 > 0.99) ranges of 0.05 to 5 mg L-1 for nitrite and 1 to 50 mg L-1 for nitrate were obtained and detection limits of 50 mug L-1 for nitrite and 0.32 mg L-1 for nitrate were achieved. Nitrates 89-96 L1 cell adhesion molecule Homo sapiens 81-84 32854085-6 2020 Good linearity (R2 > 0.99) ranges of 0.05 to 5 mg L-1 for nitrite and 1 to 50 mg L-1 for nitrate were obtained and detection limits of 50 mug L-1 for nitrite and 0.32 mg L-1 for nitrate were achieved. Nitrates 89-96 L1 cell adhesion molecule Homo sapiens 81-84 32854085-6 2020 Good linearity (R2 > 0.99) ranges of 0.05 to 5 mg L-1 for nitrite and 1 to 50 mg L-1 for nitrate were obtained and detection limits of 50 mug L-1 for nitrite and 0.32 mg L-1 for nitrate were achieved. Nitrates 89-96 L1 cell adhesion molecule Homo sapiens 81-84 32854085-6 2020 Good linearity (R2 > 0.99) ranges of 0.05 to 5 mg L-1 for nitrite and 1 to 50 mg L-1 for nitrate were obtained and detection limits of 50 mug L-1 for nitrite and 0.32 mg L-1 for nitrate were achieved. Nitrates 178-185 L1 cell adhesion molecule Homo sapiens 50-53 32854085-6 2020 Good linearity (R2 > 0.99) ranges of 0.05 to 5 mg L-1 for nitrite and 1 to 50 mg L-1 for nitrate were obtained and detection limits of 50 mug L-1 for nitrite and 0.32 mg L-1 for nitrate were achieved. Nitrates 178-185 L1 cell adhesion molecule Homo sapiens 81-84 32854085-6 2020 Good linearity (R2 > 0.99) ranges of 0.05 to 5 mg L-1 for nitrite and 1 to 50 mg L-1 for nitrate were obtained and detection limits of 50 mug L-1 for nitrite and 0.32 mg L-1 for nitrate were achieved. Nitrates 178-185 L1 cell adhesion molecule Homo sapiens 81-84 32854085-6 2020 Good linearity (R2 > 0.99) ranges of 0.05 to 5 mg L-1 for nitrite and 1 to 50 mg L-1 for nitrate were obtained and detection limits of 50 mug L-1 for nitrite and 0.32 mg L-1 for nitrate were achieved. Nitrates 178-185 L1 cell adhesion molecule Homo sapiens 81-84 33228979-6 2021 The area under the curve analyses indicated differences in cumulative cortisol levels (mg L-1 min-1) amongst the groups: control 37.9 (33.3-43.1), SPI 38.6 (33.8-44.2), PPI 72.1 (63.1-82.3), and NOL 54.4 (47.6-62.1) (mean [95% CI]). Hydrocortisone 70-78 L1 cell adhesion molecule Homo sapiens 90-99 33569349-7 2020 Differential tumorigenic protein expression revealed a novel mechanism of therapeutic efficacy after 17-AAG treatment with a significant downregulation of HMGA1, FABP5, Oct4, MYCN, prohibitin and p-L1CAM in SK-N-SH cells. tanespimycin 101-107 L1 cell adhesion molecule Homo sapiens 198-203 32777614-6 2021 The concentration of Cu observed in Ubari stream water was (
=10 mug L-1, representing the upper limit of AgNP concentrations predicted in the environment (10 mug L-1). agnps 5-10 L1 cell adhesion molecule Homo sapiens 119-122 32777503-8 2020 Both AgNPs and ionic silver were observed to reduce Prochlorococcus populations by over 90% at concentrations >=10 mug L-1, representing the upper limit of AgNP concentrations predicted in the environment (10 mug L-1). agnps 5-10 L1 cell adhesion molecule Homo sapiens 213-216 32777503-8 2020 Both AgNPs and ionic silver were observed to reduce Prochlorococcus populations by over 90% at concentrations >=10 mug L-1, representing the upper limit of AgNP concentrations predicted in the environment (10 mug L-1). Silver 21-27 L1 cell adhesion molecule Homo sapiens 119-122 32777503-8 2020 Both AgNPs and ionic silver were observed to reduce Prochlorococcus populations by over 90% at concentrations >=10 mug L-1, representing the upper limit of AgNP concentrations predicted in the environment (10 mug L-1). Silver 21-27 L1 cell adhesion molecule Homo sapiens 213-216 32777503-8 2020 Both AgNPs and ionic silver were observed to reduce Prochlorococcus populations by over 90% at concentrations >=10 mug L-1, representing the upper limit of AgNP concentrations predicted in the environment (10 mug L-1). agnp 5-9 L1 cell adhesion molecule Homo sapiens 119-122 32777503-8 2020 Both AgNPs and ionic silver were observed to reduce Prochlorococcus populations by over 90% at concentrations >=10 mug L-1, representing the upper limit of AgNP concentrations predicted in the environment (10 mug L-1). agnp 5-9 L1 cell adhesion molecule Homo sapiens 213-216 32585517-6 2020 High selectivity was also observed in the presence of interfering ions such as Cl-, SO42-, and PO43-, resulting in a removal rate over 80% at percentages over 95% for a concentration of 100 mg L-1 of As (V). Sulfates 84-89 L1 cell adhesion molecule Homo sapiens 193-196 32585517-6 2020 High selectivity was also observed in the presence of interfering ions such as Cl-, SO42-, and PO43-, resulting in a removal rate over 80% at percentages over 95% for a concentration of 100 mg L-1 of As (V). Hydrogen phosphate 95-100 L1 cell adhesion molecule Homo sapiens 193-196 32585517-6 2020 High selectivity was also observed in the presence of interfering ions such as Cl-, SO42-, and PO43-, resulting in a removal rate over 80% at percentages over 95% for a concentration of 100 mg L-1 of As (V). asunaprevir 200-206 L1 cell adhesion molecule Homo sapiens 193-196 32585517-8 2020 The retention percentage for simulated water was 46.3% at a concentration of 1300 mu g L-1. Water 39-44 L1 cell adhesion molecule Homo sapiens 87-90 32822893-5 2020 Microbial analysis revealed that the anammox species almost disappeared in the reactor dosed with SCN- at over 100 mg L-1. scn- at 98-105 L1 cell adhesion molecule Homo sapiens 118-121 32712520-4 2020 RESULTS: Considering total element evaluation through ICP-MS, Co, Ni, Mn, and Zn are found at the highest concentrations in the sample, namely 415 +- 36, 202 +- 55, 1389 +- 225 and 2397 +- 197 mug L-1, respectively. Zinc 78-80 L1 cell adhesion molecule Homo sapiens 197-200 32525612-7 2020 A good linear response was obtained for the concentration of Fe3+ in the range of 10-50 mg L-1 with detection limit of 1.04 mg L-1 . ferric sulfate 61-65 L1 cell adhesion molecule Homo sapiens 91-94 32525612-7 2020 A good linear response was obtained for the concentration of Fe3+ in the range of 10-50 mg L-1 with detection limit of 1.04 mg L-1 . ferric sulfate 61-65 L1 cell adhesion molecule Homo sapiens 127-130 32557322-4 2020 Although genome-wide expression profiling of human lymphoblastoid cell lines (LCLs) reported neural cell adhesion molecule (NCAM) L1 as a tentative biomarker for selective serotonin reuptake inhibitor (SSRI) antidepressant response, the involvement of CHL1 in depression is unclear. Serotonin 172-181 L1 cell adhesion molecule Homo sapiens 93-132 33105995-3 2020 lamourouxi resulted in the isolation of six new brominated alkaloids, convolutamines K and L (1 and 2), volutamides F-H (3-5), and 2,5-dibromo-1-methyl-1H-indole-3-carbaldehyde (6). lamourouxi 0-10 L1 cell adhesion molecule Homo sapiens 91-101 32784081-4 2020 The removal percentage was 99.9% under the optimum conditions (adsorbent dose, 4 g L-1; initial concentration of Cr(VI), 200 mg L-1; pH value, 2; contact time, 200 min). chromium hexavalent ion 113-119 L1 cell adhesion molecule Homo sapiens 128-131 32964253-3 2020 Through optimization of the SERS conditions, including the volume of SA-protected AgNPs solution, pH of Britton-Robinson (BR) buffer solution and concentration of NaCl solution, linear responses were obtained for PTU and MTZ in the concentration ranges of 3.02 x 10-9-1.06 x 10-5 mol L-1 and 1.21 x 10-9-1.21 x 10-5 mol L-1, respectively. sers 28-32 L1 cell adhesion molecule Homo sapiens 284-293 32964253-3 2020 Through optimization of the SERS conditions, including the volume of SA-protected AgNPs solution, pH of Britton-Robinson (BR) buffer solution and concentration of NaCl solution, linear responses were obtained for PTU and MTZ in the concentration ranges of 3.02 x 10-9-1.06 x 10-5 mol L-1 and 1.21 x 10-9-1.21 x 10-5 mol L-1, respectively. Alginates 69-71 L1 cell adhesion molecule Homo sapiens 284-293 32964253-3 2020 Through optimization of the SERS conditions, including the volume of SA-protected AgNPs solution, pH of Britton-Robinson (BR) buffer solution and concentration of NaCl solution, linear responses were obtained for PTU and MTZ in the concentration ranges of 3.02 x 10-9-1.06 x 10-5 mol L-1 and 1.21 x 10-9-1.21 x 10-5 mol L-1, respectively. Sodium Chloride 163-167 L1 cell adhesion molecule Homo sapiens 284-293 32964253-3 2020 Through optimization of the SERS conditions, including the volume of SA-protected AgNPs solution, pH of Britton-Robinson (BR) buffer solution and concentration of NaCl solution, linear responses were obtained for PTU and MTZ in the concentration ranges of 3.02 x 10-9-1.06 x 10-5 mol L-1 and 1.21 x 10-9-1.21 x 10-5 mol L-1, respectively. Propylthiouracil 213-216 L1 cell adhesion molecule Homo sapiens 284-293 32964253-3 2020 Through optimization of the SERS conditions, including the volume of SA-protected AgNPs solution, pH of Britton-Robinson (BR) buffer solution and concentration of NaCl solution, linear responses were obtained for PTU and MTZ in the concentration ranges of 3.02 x 10-9-1.06 x 10-5 mol L-1 and 1.21 x 10-9-1.21 x 10-5 mol L-1, respectively. Methimazole 221-224 L1 cell adhesion molecule Homo sapiens 284-293 32964253-4 2020 By the present method, the limits of detection (LODs) for the determination of PTU and MTZ were as low as 1.58 x 10-10 mol L-1 and 2.97 x 10-11 mol L-1. Propylthiouracil 79-82 L1 cell adhesion molecule Homo sapiens 123-132 32964253-4 2020 By the present method, the limits of detection (LODs) for the determination of PTU and MTZ were as low as 1.58 x 10-10 mol L-1 and 2.97 x 10-11 mol L-1. Methimazole 87-90 L1 cell adhesion molecule Homo sapiens 123-132 32698056-11 2020 The ammonium content in the pore water (up to 5.34 mg L-1) was much higher than the limit for drinking water of 0.5 mg L-1 in China. Ammonium Compounds 4-12 L1 cell adhesion molecule Homo sapiens 54-57 32645597-7 2020 In the system containing 10 mg L-1 As(III) and 1.0 g L-1 Fe-Mn nodules, the maximum oxidation capacity of As(III) reached 3.22, 3.48 and 3.71 mg g-1, and the corresponding As(III,V) adsorption capacity reached 2.49, 2.40, and 2.39 mg g-1 in nitrogen, air and oxygen atmosphere, respectively. as(iii) 35-42 L1 cell adhesion molecule Homo sapiens 31-34 32645597-7 2020 In the system containing 10 mg L-1 As(III) and 1.0 g L-1 Fe-Mn nodules, the maximum oxidation capacity of As(III) reached 3.22, 3.48 and 3.71 mg g-1, and the corresponding As(III,V) adsorption capacity reached 2.49, 2.40, and 2.39 mg g-1 in nitrogen, air and oxygen atmosphere, respectively. as(iii) 106-113 L1 cell adhesion molecule Homo sapiens 31-34 32645597-7 2020 In the system containing 10 mg L-1 As(III) and 1.0 g L-1 Fe-Mn nodules, the maximum oxidation capacity of As(III) reached 3.22, 3.48 and 3.71 mg g-1, and the corresponding As(III,V) adsorption capacity reached 2.49, 2.40, and 2.39 mg g-1 in nitrogen, air and oxygen atmosphere, respectively. as(iii) 106-113 L1 cell adhesion molecule Homo sapiens 53-56 32645597-7 2020 In the system containing 10 mg L-1 As(III) and 1.0 g L-1 Fe-Mn nodules, the maximum oxidation capacity of As(III) reached 3.22, 3.48 and 3.71 mg g-1, and the corresponding As(III,V) adsorption capacity reached 2.49, 2.40, and 2.39 mg g-1 in nitrogen, air and oxygen atmosphere, respectively. Nitrogen 241-249 L1 cell adhesion molecule Homo sapiens 31-34 32645597-7 2020 In the system containing 10 mg L-1 As(III) and 1.0 g L-1 Fe-Mn nodules, the maximum oxidation capacity of As(III) reached 3.22, 3.48 and 3.71 mg g-1, and the corresponding As(III,V) adsorption capacity reached 2.49, 2.40, and 2.39 mg g-1 in nitrogen, air and oxygen atmosphere, respectively. Nitrogen 241-249 L1 cell adhesion molecule Homo sapiens 53-56 32645597-7 2020 In the system containing 10 mg L-1 As(III) and 1.0 g L-1 Fe-Mn nodules, the maximum oxidation capacity of As(III) reached 3.22, 3.48 and 3.71 mg g-1, and the corresponding As(III,V) adsorption capacity reached 2.49, 2.40, and 2.39 mg g-1 in nitrogen, air and oxygen atmosphere, respectively. Oxygen 259-265 L1 cell adhesion molecule Homo sapiens 31-34 32645597-7 2020 In the system containing 10 mg L-1 As(III) and 1.0 g L-1 Fe-Mn nodules, the maximum oxidation capacity of As(III) reached 3.22, 3.48 and 3.71 mg g-1, and the corresponding As(III,V) adsorption capacity reached 2.49, 2.40, and 2.39 mg g-1 in nitrogen, air and oxygen atmosphere, respectively. Oxygen 259-265 L1 cell adhesion molecule Homo sapiens 53-56 32920878-9 2020 The developed preparative process produces >98% purity of both d-nebivolol and l-nebivolol with overall loading capacity of 56 g (L of adsorbent)-1 and productivity of 20 g L-1 day-1 . Dexnebivolol 63-74 L1 cell adhesion molecule Homo sapiens 173-182 32920878-9 2020 The developed preparative process produces >98% purity of both d-nebivolol and l-nebivolol with overall loading capacity of 56 g (L of adsorbent)-1 and productivity of 20 g L-1 day-1 . Levonebivolol 79-90 L1 cell adhesion molecule Homo sapiens 173-182 32603965-7 2020 Remarkably, microcleaners shows robust adsorption where >99% removal was obtained within 10 min for 50 mg L-1 concentrated Eriochrome Black T (EBT) dye using 0.01 g of materials. Eriochrome Black T 123-141 L1 cell adhesion molecule Homo sapiens 106-109 32603965-7 2020 Remarkably, microcleaners shows robust adsorption where >99% removal was obtained within 10 min for 50 mg L-1 concentrated Eriochrome Black T (EBT) dye using 0.01 g of materials. Eriochrome Black T 143-146 L1 cell adhesion molecule Homo sapiens 106-109 32663679-3 2020 Pentacene (24.3 +- 0.09 mg L-1), n-nonane (2.11 +- 0.96 mg L-1) and benzo [a] pyrene (1.39 +- 0.57 mg L-1) were the compounds with the highest concentrations in water. nonane 33-41 L1 cell adhesion molecule Homo sapiens 59-62 32663679-3 2020 Pentacene (24.3 +- 0.09 mg L-1), n-nonane (2.11 +- 0.96 mg L-1) and benzo [a] pyrene (1.39 +- 0.57 mg L-1) were the compounds with the highest concentrations in water. nonane 33-41 L1 cell adhesion molecule Homo sapiens 59-62 32663679-7 2020 The maximum growth of suspended solids for diesel in mineral medium reached 2.95 g L-1, and diesel was completely consumed in 8 days. diesel 43-49 L1 cell adhesion molecule Homo sapiens 83-86 32663679-9 2020 For Mayan crude oil in mineral medium, suspended solids increased from 0.8 to 2.41 g L-1, and Mayan crude oil was completely consumed in 12 days. mayan crude oil 4-19 L1 cell adhesion molecule Homo sapiens 85-88 32663679-10 2020 Using seawater, Mayan crude oil also degraded in 12 days, and suspended solids growth reached 2.11 g L-1. mayan crude oil 16-31 L1 cell adhesion molecule Homo sapiens 101-104 32750556-10 2020 So, the content of 152Eu and 241Am radionuclides are intensively released into the water: from 0 to 198 +- 8 Bq L-1 and 167 +- 7 Bq L-1, respectively. Water 83-88 L1 cell adhesion molecule Homo sapiens 112-135 32707599-7 2020 The optimized method was applied to tap and surface waters; two anti-inflammatory drugs were detected at the ng L-1 level in surface water. Water 52-57 L1 cell adhesion molecule Homo sapiens 112-115 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). Clofibric Acid 8-11 L1 cell adhesion molecule Homo sapiens 110-113 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). Clofibric Acid 8-11 L1 cell adhesion molecule Homo sapiens 181-184 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). Clofibric Acid 8-11 L1 cell adhesion molecule Homo sapiens 181-184 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). Clofibric Acid 26-29 L1 cell adhesion molecule Homo sapiens 110-113 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). Clofibric Acid 26-29 L1 cell adhesion molecule Homo sapiens 181-184 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). Clofibric Acid 26-29 L1 cell adhesion molecule Homo sapiens 181-184 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). potassium persulfate 192-212 L1 cell adhesion molecule Homo sapiens 110-113 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). potassium persulfate 192-212 L1 cell adhesion molecule Homo sapiens 181-184 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). potassium persulfate 192-212 L1 cell adhesion molecule Homo sapiens 181-184 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). ps 214-216 L1 cell adhesion molecule Homo sapiens 110-113 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). Iron 241-245 L1 cell adhesion molecule Homo sapiens 110-113 32535472-2 2020 In pure CFA solution, the CFA degradation rate was accelerated with an increase in oxidant dosage and 2.15 mg L-1 (0.01 mM) CFA could be completed removed within 30 min with 270 mg L-1 (1 mM) potassium persulfate (PS) activated by 56 mg L-1 iron powder (Fe). Iron 254-256 L1 cell adhesion molecule Homo sapiens 110-113 32526422-4 2020 The total Hg (THg) concentration of surface water in the KRB ranged from 0.64 to 32.96 ng L-1 with an average of 5.83 +- 6.19 ng L-1 and decreased in the order of post-monsoon (8.79 +- 7.32 ng L-1) > monsoon (6.68 +- 6.12 ng L-1) > pre-monsoon (2.18 +- 1.29 ng L-1). Water 44-49 L1 cell adhesion molecule Homo sapiens 90-93 32353784-3 2020 The results of the hydrogen evolution curves and chemical kinetics of 7 different concentrations of sodium D-gluconate showed that when the sodium D-gluconate concentration reached 0.25 g L-1, there was almost no hydrogen generation, and the rate constant was almost zero. gluconic acid 100-118 L1 cell adhesion molecule Homo sapiens 188-191 32353784-3 2020 The results of the hydrogen evolution curves and chemical kinetics of 7 different concentrations of sodium D-gluconate showed that when the sodium D-gluconate concentration reached 0.25 g L-1, there was almost no hydrogen generation, and the rate constant was almost zero. gluconic acid 140-158 L1 cell adhesion molecule Homo sapiens 188-191 31390950-4 2020 At pH 5 condition, phenol (90 mg L-1) was completely removed after a 24-h operation. Phenol 19-25 L1 cell adhesion molecule Homo sapiens 33-36 32778291-5 2020 Up to 468 mL L-1 of hydrogen and 203 mg L-1 of poly-beta-hydroxybutyrate can be produced starting from an initial chemical oxygen demand of 1500 mg L-1. Hydrogen 20-28 L1 cell adhesion molecule Homo sapiens 13-16 32778291-5 2020 Up to 468 mL L-1 of hydrogen and 203 mg L-1 of poly-beta-hydroxybutyrate can be produced starting from an initial chemical oxygen demand of 1500 mg L-1. poly-beta-hydroxybutyrate 47-72 L1 cell adhesion molecule Homo sapiens 40-43 32778291-5 2020 Up to 468 mL L-1 of hydrogen and 203 mg L-1 of poly-beta-hydroxybutyrate can be produced starting from an initial chemical oxygen demand of 1500 mg L-1. poly-beta-hydroxybutyrate 47-72 L1 cell adhesion molecule Homo sapiens 40-43 32778291-5 2020 Up to 468 mL L-1 of hydrogen and 203 mg L-1 of poly-beta-hydroxybutyrate can be produced starting from an initial chemical oxygen demand of 1500 mg L-1. Oxygen 123-129 L1 cell adhesion molecule Homo sapiens 13-16 32778291-5 2020 Up to 468 mL L-1 of hydrogen and 203 mg L-1 of poly-beta-hydroxybutyrate can be produced starting from an initial chemical oxygen demand of 1500 mg L-1. Oxygen 123-129 L1 cell adhesion molecule Homo sapiens 40-43 32778291-5 2020 Up to 468 mL L-1 of hydrogen and 203 mg L-1 of poly-beta-hydroxybutyrate can be produced starting from an initial chemical oxygen demand of 1500 mg L-1. Oxygen 123-129 L1 cell adhesion molecule Homo sapiens 40-43 32663679-3 2020 Pentacene (24.3 +- 0.09 mg L-1), n-nonane (2.11 +- 0.96 mg L-1) and benzo [a] pyrene (1.39 +- 0.57 mg L-1) were the compounds with the highest concentrations in water. pentacene 0-9 L1 cell adhesion molecule Homo sapiens 27-30 32574921-4 2020 The integrated system amended with 5 g L-1 AC produced up to 13.4 g L-1 acetate, showing a 179% increase compared with the control group without AC (4.8 g L-1). Acetates 72-79 L1 cell adhesion molecule Homo sapiens 39-42 32574921-4 2020 The integrated system amended with 5 g L-1 AC produced up to 13.4 g L-1 acetate, showing a 179% increase compared with the control group without AC (4.8 g L-1). Acetates 72-79 L1 cell adhesion molecule Homo sapiens 68-71 32574921-4 2020 The integrated system amended with 5 g L-1 AC produced up to 13.4 g L-1 acetate, showing a 179% increase compared with the control group without AC (4.8 g L-1). Acetates 72-79 L1 cell adhesion molecule Homo sapiens 68-71 32574921-4 2020 The integrated system amended with 5 g L-1 AC produced up to 13.4 g L-1 acetate, showing a 179% increase compared with the control group without AC (4.8 g L-1). Charcoal 43-45 L1 cell adhesion molecule Homo sapiens 39-42 32574921-4 2020 The integrated system amended with 5 g L-1 AC produced up to 13.4 g L-1 acetate, showing a 179% increase compared with the control group without AC (4.8 g L-1). Charcoal 43-45 L1 cell adhesion molecule Homo sapiens 68-71 32574921-4 2020 The integrated system amended with 5 g L-1 AC produced up to 13.4 g L-1 acetate, showing a 179% increase compared with the control group without AC (4.8 g L-1). Charcoal 43-45 L1 cell adhesion molecule Homo sapiens 68-71 32574921-5 2020 However, further increasing the AC concentration to 10 and 20 g L-1 resulted in decreased acetate production. Charcoal 32-34 L1 cell adhesion molecule Homo sapiens 64-67 32574921-5 2020 However, further increasing the AC concentration to 10 and 20 g L-1 resulted in decreased acetate production. Acetates 90-97 L1 cell adhesion molecule Homo sapiens 64-67 32574921-8 2020 Also, amending AC with 0 to 10 g L-1 decreased the electrochemical losses via both the membrane and electrolyte. Charcoal 15-17 L1 cell adhesion molecule Homo sapiens 33-36 32777598-1 2020 The European Union has proposed the value of 1 ng L-1 as a drinking water quality standard for estradiol. Water 68-73 L1 cell adhesion molecule Homo sapiens 50-53 32777598-1 2020 The European Union has proposed the value of 1 ng L-1 as a drinking water quality standard for estradiol. Estradiol 95-104 L1 cell adhesion molecule Homo sapiens 50-53 32777598-5 2020 The use of smaller carbon particles allows reaching the ambitious target value of 1 ng L-1 in a millimetric layer. Carbon 19-25 L1 cell adhesion molecule Homo sapiens 87-90 32526422-4 2020 The total Hg (THg) concentration of surface water in the KRB ranged from 0.64 to 32.96 ng L-1 with an average of 5.83 +- 6.19 ng L-1 and decreased in the order of post-monsoon (8.79 +- 7.32 ng L-1) > monsoon (6.68 +- 6.12 ng L-1) > pre-monsoon (2.18 +- 1.29 ng L-1). Thioguanine 14-17 L1 cell adhesion molecule Homo sapiens 90-93 33124386-5 2020 The peak concentrations of ammonia nitrogen (NH4+-N) from April 1st to June 30th were 11.51 mg L-1 and 4.44 mg L-1in 2012 and 2013, respectively. Nitrogen 35-43 L1 cell adhesion molecule Homo sapiens 96-105 33124386-5 2020 The peak concentrations of ammonia nitrogen (NH4+-N) from April 1st to June 30th were 11.51 mg L-1 and 4.44 mg L-1in 2012 and 2013, respectively. nh4+-n 45-51 L1 cell adhesion molecule Homo sapiens 96-105 32846092-1 2020 The growing use of silver-based nanoparticles (Ag-b-NPs) in everyday products goes in hand with their release into the environment, resulting in ng L-1 traces in natural water bodies. Silver 19-25 L1 cell adhesion molecule Homo sapiens 148-151 32846092-1 2020 The growing use of silver-based nanoparticles (Ag-b-NPs) in everyday products goes in hand with their release into the environment, resulting in ng L-1 traces in natural water bodies. Water 170-175 L1 cell adhesion molecule Homo sapiens 148-151 32447107-9 2020 The reactions with Fe-based nanocatalyst containing copper ions in pH = 3, initial dye concentration = 200 mg L-1, I = 3.57 mA cm-2, nanocatalyst concentration = 100 mg L-1, electrodes angular velocity = 50 rpm, Na2SO4 concentration = 0.01 M were capable of removing 97% of dye, 79% of COD and, 65% of TOC. Iron 19-21 L1 cell adhesion molecule Homo sapiens 110-113 32447107-9 2020 The reactions with Fe-based nanocatalyst containing copper ions in pH = 3, initial dye concentration = 200 mg L-1, I = 3.57 mA cm-2, nanocatalyst concentration = 100 mg L-1, electrodes angular velocity = 50 rpm, Na2SO4 concentration = 0.01 M were capable of removing 97% of dye, 79% of COD and, 65% of TOC. Iron 19-21 L1 cell adhesion molecule Homo sapiens 169-172 32563118-4 2020 Mean concentrations of soluble Cd in rime were six times higher than in snow (398 vs. 66 ng L-1). Cadmium 31-33 L1 cell adhesion molecule Homo sapiens 92-95 32384986-6 2020 The degradation extent of ammonia nitrogen was upto 81% when the ammonia nitrogen degradation reaction was photocatalyzed by the hollow SiO2@BiOI(100:10) nanocomposite at an initial concentration of ammonia nitrogen of 10 mg L-1 and 25 C for 4 h. The reaction kinetics of ammonia nitrogen degradation was well simulated by the first-order reaction model. Nitrogen 34-42 L1 cell adhesion molecule Homo sapiens 225-235 32384986-6 2020 The degradation extent of ammonia nitrogen was upto 81% when the ammonia nitrogen degradation reaction was photocatalyzed by the hollow SiO2@BiOI(100:10) nanocomposite at an initial concentration of ammonia nitrogen of 10 mg L-1 and 25 C for 4 h. The reaction kinetics of ammonia nitrogen degradation was well simulated by the first-order reaction model. Nitrogen 73-81 L1 cell adhesion molecule Homo sapiens 225-235 32384986-6 2020 The degradation extent of ammonia nitrogen was upto 81% when the ammonia nitrogen degradation reaction was photocatalyzed by the hollow SiO2@BiOI(100:10) nanocomposite at an initial concentration of ammonia nitrogen of 10 mg L-1 and 25 C for 4 h. The reaction kinetics of ammonia nitrogen degradation was well simulated by the first-order reaction model. Silicon Dioxide 136-140 L1 cell adhesion molecule Homo sapiens 225-235 32384986-6 2020 The degradation extent of ammonia nitrogen was upto 81% when the ammonia nitrogen degradation reaction was photocatalyzed by the hollow SiO2@BiOI(100:10) nanocomposite at an initial concentration of ammonia nitrogen of 10 mg L-1 and 25 C for 4 h. The reaction kinetics of ammonia nitrogen degradation was well simulated by the first-order reaction model. Nitrogen 73-81 L1 cell adhesion molecule Homo sapiens 225-235 32384986-6 2020 The degradation extent of ammonia nitrogen was upto 81% when the ammonia nitrogen degradation reaction was photocatalyzed by the hollow SiO2@BiOI(100:10) nanocomposite at an initial concentration of ammonia nitrogen of 10 mg L-1 and 25 C for 4 h. The reaction kinetics of ammonia nitrogen degradation was well simulated by the first-order reaction model. Nitrogen 73-81 L1 cell adhesion molecule Homo sapiens 225-235 32698056-11 2020 The ammonium content in the pore water (up to 5.34 mg L-1) was much higher than the limit for drinking water of 0.5 mg L-1 in China. Ammonium Compounds 4-12 L1 cell adhesion molecule Homo sapiens 119-122 32698056-11 2020 The ammonium content in the pore water (up to 5.34 mg L-1) was much higher than the limit for drinking water of 0.5 mg L-1 in China. Water 33-38 L1 cell adhesion molecule Homo sapiens 54-57 32705548-6 2020 Design Expert 12.0.8.0 software has been used to design mathematical model to obtain optimum condition (14 V and 47 min) at pH of 7.35, which provides experimental removal efficiency (75.6% chemical oxygen demand, 78.7% total dissolved solids, 93.4% turbidity, and 63.2% chloride) with minimal electrode consumption of 1.38 mg L-1. Oxygen 199-205 L1 cell adhesion molecule Homo sapiens 327-330 32852498-12 2020 Estrone (E1), an endocrine disrupting compound, was reported for the first time in Indian wastewater at 376.2 ng L-1. Estrone 0-7 L1 cell adhesion molecule Homo sapiens 113-116 32505022-8 2020 During treatment of GW, the MCW achieved effluent concentrations for respectively chemical oxygen demand (COD), biological oxygen demand (BOD), total suspended solids (TSS) and total phosphorus (TP) of 43 mg L-1, 16 mg L-1, 2.7 mg L-1 and 1.7 mgP L-1. glycyltryptophan 20-22 L1 cell adhesion molecule Homo sapiens 231-240 32852498-12 2020 Estrone (E1), an endocrine disrupting compound, was reported for the first time in Indian wastewater at 376.2 ng L-1. e1 9-11 L1 cell adhesion molecule Homo sapiens 113-116 32505759-8 2020 For osteoporosis, the estimated BMDs of blood Cd were 7.95 mug L-1 in males and 1.23 mug L-1 in females. Cadmium 46-48 L1 cell adhesion molecule Homo sapiens 63-66 32468622-7 2020 Instrumental limits of detection are 30 ng L-1 for testosterone using ESI and 1 mug L-1 for vitamin D3 using APCI. Testosterone 51-63 L1 cell adhesion molecule Homo sapiens 43-46 32468622-7 2020 Instrumental limits of detection are 30 ng L-1 for testosterone using ESI and 1 mug L-1 for vitamin D3 using APCI. Cholecalciferol 92-102 L1 cell adhesion molecule Homo sapiens 84-87 32473426-2 2020 The 1.5% agarose solution containing the optimal nZVI@biochar dose of 15 g L-1 was used to prepare the nZVI@biochar binding gel which owned a high capacity (1010 +- 50 mug disc-1) and a rapid uptake within 30 min. Sepharose 9-16 L1 cell adhesion molecule Homo sapiens 75-78 32473426-3 2020 The elution efficiency of phenol from the loaded binding gel was up to 99.3% using the mixture of 1% hydroxylamine hydrochloride and 0.05 mol L-1 HCl. Phenol 26-32 L1 cell adhesion molecule Homo sapiens 142-145 32645581-4 2020 The effluent chemical oxygen demand (COD) content decreased from 150 to 78 mg L-1, and remained below a discharge limitation of 80 mg L-1, and the stable COD removal efficiencies (from 56.0% to 47.9%) indicated that catalyst deactivation, which primarily resulted from the deposition of inorganic salts on the surface of the catalyst that limited interaction between ozone and active sites and/or prevented electrons transfer, was primarily inhibited by backflushing. Oxygen 22-28 L1 cell adhesion molecule Homo sapiens 78-81 32736270-4 2020 At a UV dose of 128 mJ cm-2 and a chlorine dose of 10 mg L-1, about 71.7-97.8% CBDs were degraded by UV/chlorine treatment within 10 min. Chlorine 34-42 L1 cell adhesion molecule Homo sapiens 57-60 32736270-4 2020 At a UV dose of 128 mJ cm-2 and a chlorine dose of 10 mg L-1, about 71.7-97.8% CBDs were degraded by UV/chlorine treatment within 10 min. Chlorine 104-112 L1 cell adhesion molecule Homo sapiens 57-60 32820295-6 2020 A limit of detection (LOD) of 10 ng L-1 (3sigma method) and a linear range from 14 to 70 ng L-1 were obtained for the sensing of As(iii) ions. as(iii) 129-136 L1 cell adhesion molecule Homo sapiens 36-39 32820295-6 2020 A limit of detection (LOD) of 10 ng L-1 (3sigma method) and a linear range from 14 to 70 ng L-1 were obtained for the sensing of As(iii) ions. as(iii) 129-136 L1 cell adhesion molecule Homo sapiens 92-95 32852204-2 2020 Complexes 1 and 2 are prepared from the reaction of L1/L2 with the aid of ancillary ligands (PyPzCF3, 2-(3-(trifluoromethyl)-1H-pyrazol-5-yl)pyridine) in a two step method. pypzcf3 93-100 L1 cell adhesion molecule Homo sapiens 52-57 32811144-5 2020 By treating simulated wastewater six times with this material, the PFOA concentration in water was reduced from 1 ppm to 43 ppt (43 ng L-1), showing that PR-PEG-PFA is a promising adsorbent for PFASs separation, recovery, and recycling. perfluorooctanoic acid 67-71 L1 cell adhesion molecule Homo sapiens 135-138 32811144-5 2020 By treating simulated wastewater six times with this material, the PFOA concentration in water was reduced from 1 ppm to 43 ppt (43 ng L-1), showing that PR-PEG-PFA is a promising adsorbent for PFASs separation, recovery, and recycling. Water 27-32 L1 cell adhesion molecule Homo sapiens 135-138 32811144-5 2020 By treating simulated wastewater six times with this material, the PFOA concentration in water was reduced from 1 ppm to 43 ppt (43 ng L-1), showing that PR-PEG-PFA is a promising adsorbent for PFASs separation, recovery, and recycling. pr-peg-pfa 154-164 L1 cell adhesion molecule Homo sapiens 135-138 32388180-8 2020 Methylphenidate was detected in the influent and effluent samples at mean concentrations of 2.7 and 2.6 ng L-1, respectively, but the methylphenidate consumption rate could not be estimated because of the low excretion rate for humans (<1%). Methylphenidate 0-15 L1 cell adhesion molecule Homo sapiens 107-110 32812959-2 2020 This work describes the synthesis of the L-shaped 1,3-bis(3"-carboxypyridine)adamantane (L1) ligand and the corresponding Li(i), Zn(ii) and Cu(ii) frameworks. 1,3-bis(3"-carboxypyridine)adamantane 50-87 L1 cell adhesion molecule Homo sapiens 89-91 32375090-4 2020 Results showed that concentrations of individual PAHs in the surface water ranged from less than the limit of quantification (LOQ) to 949 ng L-1, indicating a reduction of PAH contamination level after the implementation of environmental management actions. Water 69-74 L1 cell adhesion molecule Homo sapiens 141-144 32375090-4 2020 Results showed that concentrations of individual PAHs in the surface water ranged from less than the limit of quantification (LOQ) to 949 ng L-1, indicating a reduction of PAH contamination level after the implementation of environmental management actions. Polycyclic Aromatic Hydrocarbons 49-52 L1 cell adhesion molecule Homo sapiens 141-144 32375090-5 2020 Influent of MWWTPs and wastewater from industrial enterprises exhibited relatively high PAHs concentrations (mean: 880 ng L-1 and 642 ng L-1, respectively); these samples also exhibited a similar seasonal variation as well as composition of PAH congeners to those found in surface water, and therefore were designated as the main emission sources of PAHs in the studied region. Polycyclic Aromatic Hydrocarbons 89-92 L1 cell adhesion molecule Homo sapiens 123-126 32375090-5 2020 Influent of MWWTPs and wastewater from industrial enterprises exhibited relatively high PAHs concentrations (mean: 880 ng L-1 and 642 ng L-1, respectively); these samples also exhibited a similar seasonal variation as well as composition of PAH congeners to those found in surface water, and therefore were designated as the main emission sources of PAHs in the studied region. Polycyclic Aromatic Hydrocarbons 89-93 L1 cell adhesion molecule Homo sapiens 123-126 32375090-5 2020 Influent of MWWTPs and wastewater from industrial enterprises exhibited relatively high PAHs concentrations (mean: 880 ng L-1 and 642 ng L-1, respectively); these samples also exhibited a similar seasonal variation as well as composition of PAH congeners to those found in surface water, and therefore were designated as the main emission sources of PAHs in the studied region. Polycyclic Aromatic Hydrocarbons 89-93 L1 cell adhesion molecule Homo sapiens 138-141 32416427-5 2020 Cu and Zn ions were mainly electrochemically adsorbed on the carbon cathode and anode, respectively, resulting in decreases of their concentrations to below 1 mg L-1 in the leachate. Copper 0-2 L1 cell adhesion molecule Homo sapiens 162-165 32416427-5 2020 Cu and Zn ions were mainly electrochemically adsorbed on the carbon cathode and anode, respectively, resulting in decreases of their concentrations to below 1 mg L-1 in the leachate. Zinc 7-9 L1 cell adhesion molecule Homo sapiens 162-165 32416427-5 2020 Cu and Zn ions were mainly electrochemically adsorbed on the carbon cathode and anode, respectively, resulting in decreases of their concentrations to below 1 mg L-1 in the leachate. carbon cathode 61-75 L1 cell adhesion molecule Homo sapiens 162-165 32812959-2 2020 This work describes the synthesis of the L-shaped 1,3-bis(3"-carboxypyridine)adamantane (L1) ligand and the corresponding Li(i), Zn(ii) and Cu(ii) frameworks. li(i) 122-127 L1 cell adhesion molecule Homo sapiens 89-91 32812959-2 2020 This work describes the synthesis of the L-shaped 1,3-bis(3"-carboxypyridine)adamantane (L1) ligand and the corresponding Li(i), Zn(ii) and Cu(ii) frameworks. zn(ii) 129-135 L1 cell adhesion molecule Homo sapiens 89-91 32812959-2 2020 This work describes the synthesis of the L-shaped 1,3-bis(3"-carboxypyridine)adamantane (L1) ligand and the corresponding Li(i), Zn(ii) and Cu(ii) frameworks. cu(ii) 140-146 L1 cell adhesion molecule Homo sapiens 89-91 32812959-4 2020 The reaction between the carboxylate groups of L1 and the Li(i) cations resulted in the formation of Li-carboxylate rods. carboxylate 25-36 L1 cell adhesion molecule Homo sapiens 47-49 32812959-4 2020 The reaction between the carboxylate groups of L1 and the Li(i) cations resulted in the formation of Li-carboxylate rods. li(i) 58-63 L1 cell adhesion molecule Homo sapiens 47-49 32812959-4 2020 The reaction between the carboxylate groups of L1 and the Li(i) cations resulted in the formation of Li-carboxylate rods. li-carboxylate 101-115 L1 cell adhesion molecule Homo sapiens 47-49 32812959-7 2020 Furthermore, complexation of L1 with Cu(BF4)2 H2O and Zn(CF3SO3)2 provided a 2D 3D interpenetrated network containing a classic dimeric copper paddle-wheel SBU, and an infinite 1D chain which extended into a 3D structure facilitated by hydrogen-bonding interactions, respectively. Copper fluoroborate 37-45 L1 cell adhesion molecule Homo sapiens 29-31 32812959-7 2020 Furthermore, complexation of L1 with Cu(BF4)2 H2O and Zn(CF3SO3)2 provided a 2D 3D interpenetrated network containing a classic dimeric copper paddle-wheel SBU, and an infinite 1D chain which extended into a 3D structure facilitated by hydrogen-bonding interactions, respectively. Water 46-49 L1 cell adhesion molecule Homo sapiens 29-31 32812959-7 2020 Furthermore, complexation of L1 with Cu(BF4)2 H2O and Zn(CF3SO3)2 provided a 2D 3D interpenetrated network containing a classic dimeric copper paddle-wheel SBU, and an infinite 1D chain which extended into a 3D structure facilitated by hydrogen-bonding interactions, respectively. zn(cf3so3)2 54-65 L1 cell adhesion molecule Homo sapiens 29-31 32812959-7 2020 Furthermore, complexation of L1 with Cu(BF4)2 H2O and Zn(CF3SO3)2 provided a 2D 3D interpenetrated network containing a classic dimeric copper paddle-wheel SBU, and an infinite 1D chain which extended into a 3D structure facilitated by hydrogen-bonding interactions, respectively. Copper 138-144 L1 cell adhesion molecule Homo sapiens 29-31 32812959-7 2020 Furthermore, complexation of L1 with Cu(BF4)2 H2O and Zn(CF3SO3)2 provided a 2D 3D interpenetrated network containing a classic dimeric copper paddle-wheel SBU, and an infinite 1D chain which extended into a 3D structure facilitated by hydrogen-bonding interactions, respectively. sbu 158-161 L1 cell adhesion molecule Homo sapiens 29-31 32812959-7 2020 Furthermore, complexation of L1 with Cu(BF4)2 H2O and Zn(CF3SO3)2 provided a 2D 3D interpenetrated network containing a classic dimeric copper paddle-wheel SBU, and an infinite 1D chain which extended into a 3D structure facilitated by hydrogen-bonding interactions, respectively. Hydrogen 238-246 L1 cell adhesion molecule Homo sapiens 29-31 32579267-5 2020 The recovery of 17beta-estradiol is 88-95% with relative standard deviation of less than 4%, and the limits of detection and quantification of this method are 2.08 and 9.29 mug L-1 , respectively. Estradiol 16-32 L1 cell adhesion molecule Homo sapiens 177-180 32559871-5 2020 Metoprolol (524 ng L-1), caffeine (390 ng L-1) and acetaminophen (156 ng L-1) were the three most abundant non-antibiotics with the highest median concentration, and nalidixic acid (135 ng L-1), erythromycin (64 ng L-1) and sulfamethoxazole (77 ng L-1) were the most abundant antibiotics. Metoprolol 0-10 L1 cell adhesion molecule Homo sapiens 19-22 32559871-5 2020 Metoprolol (524 ng L-1), caffeine (390 ng L-1) and acetaminophen (156 ng L-1) were the three most abundant non-antibiotics with the highest median concentration, and nalidixic acid (135 ng L-1), erythromycin (64 ng L-1) and sulfamethoxazole (77 ng L-1) were the most abundant antibiotics. Caffeine 25-33 L1 cell adhesion molecule Homo sapiens 42-45 32559871-5 2020 Metoprolol (524 ng L-1), caffeine (390 ng L-1) and acetaminophen (156 ng L-1) were the three most abundant non-antibiotics with the highest median concentration, and nalidixic acid (135 ng L-1), erythromycin (64 ng L-1) and sulfamethoxazole (77 ng L-1) were the most abundant antibiotics. Caffeine 25-33 L1 cell adhesion molecule Homo sapiens 42-45 32559871-5 2020 Metoprolol (524 ng L-1), caffeine (390 ng L-1) and acetaminophen (156 ng L-1) were the three most abundant non-antibiotics with the highest median concentration, and nalidixic acid (135 ng L-1), erythromycin (64 ng L-1) and sulfamethoxazole (77 ng L-1) were the most abundant antibiotics. Caffeine 25-33 L1 cell adhesion molecule Homo sapiens 42-45 32559871-5 2020 Metoprolol (524 ng L-1), caffeine (390 ng L-1) and acetaminophen (156 ng L-1) were the three most abundant non-antibiotics with the highest median concentration, and nalidixic acid (135 ng L-1), erythromycin (64 ng L-1) and sulfamethoxazole (77 ng L-1) were the most abundant antibiotics. Caffeine 25-33 L1 cell adhesion molecule Homo sapiens 42-45 32559871-5 2020 Metoprolol (524 ng L-1), caffeine (390 ng L-1) and acetaminophen (156 ng L-1) were the three most abundant non-antibiotics with the highest median concentration, and nalidixic acid (135 ng L-1), erythromycin (64 ng L-1) and sulfamethoxazole (77 ng L-1) were the most abundant antibiotics. Caffeine 25-33 L1 cell adhesion molecule Homo sapiens 42-45 32858820-7 2020 The maximum adsorption capacity, estimated by Sips model, was 265 mg L-1 at 300 K. The removal efficiency was significantly improved in the range of pH > 6, as well as in the presence of cation interferents such as Ca(II), Cu(II), and Cd(II). cu(ii) 223-229 L1 cell adhesion molecule Homo sapiens 69-72 32858820-7 2020 The maximum adsorption capacity, estimated by Sips model, was 265 mg L-1 at 300 K. The removal efficiency was significantly improved in the range of pH > 6, as well as in the presence of cation interferents such as Ca(II), Cu(II), and Cd(II). cd(ii) 235-241 L1 cell adhesion molecule Homo sapiens 69-72 32474265-2 2020 The UV-A/Chlorine process, a promising advanced oxidation process (AOP), was evaluated for the first time for the removal of 2-isopropyl-3-methoxy pyrazine (IPMP), a widely reported compound in the literature that causes unpleasant taste and odor when present in water at or below the ng L-1 level. Chlorine 9-17 L1 cell adhesion molecule Homo sapiens 288-291 32361236-4 2020 For an initial concentration of 10 mg L-1 and pH 2.00, the MgAl-LDH with incorporated nitroprusside was only able to adsorb the DMA and As(V) species, with removal percentages of 25.10 and 103.8%, respectively. Nitroprusside 86-99 L1 cell adhesion molecule Homo sapiens 38-41 32843698-5 2020 The results reveled that degradation efficiency of BiOCl-GO for DCF reduced from 100 to 34.4% with the increases in DCF initial concentration from 5 mg L-1 to 25 mg L-1. Diclofenac 64-67 L1 cell adhesion molecule Homo sapiens 152-155 32843698-5 2020 The results reveled that degradation efficiency of BiOCl-GO for DCF reduced from 100 to 34.4% with the increases in DCF initial concentration from 5 mg L-1 to 25 mg L-1. Diclofenac 64-67 L1 cell adhesion molecule Homo sapiens 165-168 32843698-5 2020 The results reveled that degradation efficiency of BiOCl-GO for DCF reduced from 100 to 34.4% with the increases in DCF initial concentration from 5 mg L-1 to 25 mg L-1. Diclofenac 116-119 L1 cell adhesion molecule Homo sapiens 152-155 32843698-5 2020 The results reveled that degradation efficiency of BiOCl-GO for DCF reduced from 100 to 34.4% with the increases in DCF initial concentration from 5 mg L-1 to 25 mg L-1. Diclofenac 116-119 L1 cell adhesion molecule Homo sapiens 165-168 32661529-6 2020 Both of them have sufficient sensitivity (0.05-10 mg L-1), good linear relationship (R2 > 0.99) and high recovery in quantitative SERS analysis. sers 130-134 L1 cell adhesion molecule Homo sapiens 53-56 32736715-7 2020 The proposed muPAD was presented good linearity in the ranges of 5.0-1400.0 and 5.0-200.0 mg L-1, and the limits of detections of 1.7 and 1.9 mg L-1 in presence of chrome azurol S and pyrocatechol violet, respectively. azurol s 171-179 L1 cell adhesion molecule Homo sapiens 93-96 32736715-7 2020 The proposed muPAD was presented good linearity in the ranges of 5.0-1400.0 and 5.0-200.0 mg L-1, and the limits of detections of 1.7 and 1.9 mg L-1 in presence of chrome azurol S and pyrocatechol violet, respectively. azurol s 171-179 L1 cell adhesion molecule Homo sapiens 145-148 32736715-7 2020 The proposed muPAD was presented good linearity in the ranges of 5.0-1400.0 and 5.0-200.0 mg L-1, and the limits of detections of 1.7 and 1.9 mg L-1 in presence of chrome azurol S and pyrocatechol violet, respectively. pyrocatechol violet 184-203 L1 cell adhesion molecule Homo sapiens 145-148 32573604-3 2020 With these implications, by skilfully using the chromogenic and the extinction phenomena in the guaiacol/POD/H2O2 reaction, an automatic analysis system for simultaneous quantification of POD (73-440 U L-1) and AsA (4-60 mg L-1) was successfully established based on flow injection analysis (FIA). Guaiacol 96-104 L1 cell adhesion molecule Homo sapiens 202-205 32573604-3 2020 With these implications, by skilfully using the chromogenic and the extinction phenomena in the guaiacol/POD/H2O2 reaction, an automatic analysis system for simultaneous quantification of POD (73-440 U L-1) and AsA (4-60 mg L-1) was successfully established based on flow injection analysis (FIA). Guaiacol 96-104 L1 cell adhesion molecule Homo sapiens 224-227 32573604-3 2020 With these implications, by skilfully using the chromogenic and the extinction phenomena in the guaiacol/POD/H2O2 reaction, an automatic analysis system for simultaneous quantification of POD (73-440 U L-1) and AsA (4-60 mg L-1) was successfully established based on flow injection analysis (FIA). Hydrogen Peroxide 109-113 L1 cell adhesion molecule Homo sapiens 202-205 32573604-3 2020 With these implications, by skilfully using the chromogenic and the extinction phenomena in the guaiacol/POD/H2O2 reaction, an automatic analysis system for simultaneous quantification of POD (73-440 U L-1) and AsA (4-60 mg L-1) was successfully established based on flow injection analysis (FIA). Hydrogen Peroxide 109-113 L1 cell adhesion molecule Homo sapiens 224-227 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. Hydrochloric Acid 53-56 L1 cell adhesion molecule Homo sapiens 46-49 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. Hydrochloric Acid 53-56 L1 cell adhesion molecule Homo sapiens 181-184 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. Hydrochloric Acid 53-56 L1 cell adhesion molecule Homo sapiens 181-184 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. Carbon 129-135 L1 cell adhesion molecule Homo sapiens 46-49 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. Carbon 129-135 L1 cell adhesion molecule Homo sapiens 181-184 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. Carbon 129-135 L1 cell adhesion molecule Homo sapiens 181-184 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. spod-cds 142-150 L1 cell adhesion molecule Homo sapiens 46-49 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. spod-cds 142-150 L1 cell adhesion molecule Homo sapiens 181-184 32573604-4 2020 Furthermore, under acidic conditions (0.5 mol L-1 of HCl), hydrothermal synthesis (250 C for 1 h) was used for synthesizing new carbon dots (sPOD-CDs) of methylthymol blue (0.08 g L-1)/FeCl3 (0.8 g L-1), which is a simulative enzyme for POD, and it was first used for catalyzing the guaiacol/H2O2 reaction within the FIA system to replace natural HRP in the extinction reaction. spod-cds 142-150 L1 cell adhesion molecule Homo sapiens 181-184 32474265-2 2020 The UV-A/Chlorine process, a promising advanced oxidation process (AOP), was evaluated for the first time for the removal of 2-isopropyl-3-methoxy pyrazine (IPMP), a widely reported compound in the literature that causes unpleasant taste and odor when present in water at or below the ng L-1 level. 2-isopropyl-3-methoxypyrazine 125-155 L1 cell adhesion molecule Homo sapiens 288-291 32474265-2 2020 The UV-A/Chlorine process, a promising advanced oxidation process (AOP), was evaluated for the first time for the removal of 2-isopropyl-3-methoxy pyrazine (IPMP), a widely reported compound in the literature that causes unpleasant taste and odor when present in water at or below the ng L-1 level. 2-isopropyl-3-methoxypyrazine 157-161 L1 cell adhesion molecule Homo sapiens 288-291 32422455-9 2020 Geogenic materials (topsoil and mining tailings), and water samples could contain extremely high arsenic concentrations, i.e. 21,000 mg kg-1 or 1,700,000 mug L-1, respectively, have been found mainly at the "Iron Quadrangle". Water 54-59 L1 cell adhesion molecule Homo sapiens 158-161 32456937-8 2020 The calibration graphs were linear over the concentration ranges of 0.06-50 mg L-1 for sulfamethoxazole, sulfamethazine and sulfapyridine. Sulfamethoxazole 87-103 L1 cell adhesion molecule Homo sapiens 79-82 32456937-8 2020 The calibration graphs were linear over the concentration ranges of 0.06-50 mg L-1 for sulfamethoxazole, sulfamethazine and sulfapyridine. Sulfamethazine 105-119 L1 cell adhesion molecule Homo sapiens 79-82 32456937-8 2020 The calibration graphs were linear over the concentration ranges of 0.06-50 mg L-1 for sulfamethoxazole, sulfamethazine and sulfapyridine. Sulfapyridine 124-137 L1 cell adhesion molecule Homo sapiens 79-82 32422455-9 2020 Geogenic materials (topsoil and mining tailings), and water samples could contain extremely high arsenic concentrations, i.e. 21,000 mg kg-1 or 1,700,000 mug L-1, respectively, have been found mainly at the "Iron Quadrangle". Arsenic 97-104 L1 cell adhesion molecule Homo sapiens 158-161 32422455-9 2020 Geogenic materials (topsoil and mining tailings), and water samples could contain extremely high arsenic concentrations, i.e. 21,000 mg kg-1 or 1,700,000 mug L-1, respectively, have been found mainly at the "Iron Quadrangle". Iron 208-212 L1 cell adhesion molecule Homo sapiens 158-161 33124348-5 2020 However, during the inhibited anaerobic digestion process with a high ammonia concentration, the addition of 4 g L-1 and 10 g L-1 of m-ZVI was able to shorten the lag phase from 18.61 d (the control) to 17.22 d and 16.18 d, respectively. Ammonia 70-77 L1 cell adhesion molecule Homo sapiens 113-125 32724991-9 2020 The IC50 value of 0.89 mg L-1 for BQ was obtained using K3[Fe(CN)6] as the single mediator. quinone 34-36 L1 cell adhesion molecule Homo sapiens 26-29 32724991-9 2020 The IC50 value of 0.89 mg L-1 for BQ was obtained using K3[Fe(CN)6] as the single mediator. KS 3 56-58 L1 cell adhesion molecule Homo sapiens 26-29 32724991-9 2020 The IC50 value of 0.89 mg L-1 for BQ was obtained using K3[Fe(CN)6] as the single mediator. fe(cn)6 59-66 L1 cell adhesion molecule Homo sapiens 26-29 32770016-6 2020 At a manganese concentration of 1 mg L-1, SBP1 achieved up to 46% removal. Manganese 5-14 L1 cell adhesion molecule Homo sapiens 37-40 32540067-3 2020 Combined with gas chromatography-mass spectrometric (GC-MS) detection, the COP-QP-TC based SPME method exhibited high enrichment factors (248-799), low limits of detection (1.31-3.00 ng L-1), good linear range (4.37- 500 ng L-1) and acceptable precisions (relative standard deviations <10.3%). cop-qp-tc 75-84 L1 cell adhesion molecule Homo sapiens 186-189 32524369-9 2020 Application of the method to surface water, groundwater, raw water, and finished drinking water revealed the presence of acesulfame and trifluoromethanesulfonic acid up to 70 and 19 mug L-1, respectively. trifluoromethanesulfonic acid 136-165 L1 cell adhesion molecule Homo sapiens 186-189 32524369-10 2020 Melamine, diphenylguanidine, p-dimethylbenzenesulfonic acid, and 4-hydroxy-1-(2-hydroxyethyl)-2,2,6,6-tetramethylpiperidine were found in high ng L-1 concentrations. p-dimethylbenzenesulfonic acid 29-59 L1 cell adhesion molecule Homo sapiens 146-149 32524369-10 2020 Melamine, diphenylguanidine, p-dimethylbenzenesulfonic acid, and 4-hydroxy-1-(2-hydroxyethyl)-2,2,6,6-tetramethylpiperidine were found in high ng L-1 concentrations. 1-(2-hydroxyethyl)-2,2,6,6-tetramethylpiperidin-4-ol 65-123 L1 cell adhesion molecule Homo sapiens 146-149 32540067-3 2020 Combined with gas chromatography-mass spectrometric (GC-MS) detection, the COP-QP-TC based SPME method exhibited high enrichment factors (248-799), low limits of detection (1.31-3.00 ng L-1), good linear range (4.37- 500 ng L-1) and acceptable precisions (relative standard deviations <10.3%). cop-qp-tc 75-84 L1 cell adhesion molecule Homo sapiens 224-227 32361201-2 2020 A high total nitrogen removal efficiency (>82.6%) and a stable total phosphate removal efficiency (>56.2%) was achieved in reactor with the phosphate concentration over 11.4 mg L-1. Phosphates 140-149 L1 cell adhesion molecule Homo sapiens 177-180 32806906-4 2020 Here, we show that a large music festival held adjacent to the Traisen River in Austria increased the river"s dissolved organic carbon (DOC) concentration from 1.6 to 2.1 mg L-1 and stream ecosystem respiration from -3.2 to -4.5 mg L-1. Carbon 128-134 L1 cell adhesion molecule Homo sapiens 174-177 32806906-4 2020 Here, we show that a large music festival held adjacent to the Traisen River in Austria increased the river"s dissolved organic carbon (DOC) concentration from 1.6 to 2.1 mg L-1 and stream ecosystem respiration from -3.2 to -4.5 mg L-1. Carbon 128-134 L1 cell adhesion molecule Homo sapiens 232-235 32361201-3 2020 However, a phosphate concentration below to 5.7 mg L-1, a floatation of sludge occurred caused the deterioration of process. Phosphates 11-20 L1 cell adhesion molecule Homo sapiens 51-54 32278915-7 2020 The average NH4+-N concentration reached 1.4 +- 0.5, 6.7 +- 3.1, and 8.4 +- 1.5 mg L-1 in the effluent when the influent contained 0, 5, and 10 mg L-1 of Cu(II), respectively. nh4+-n 12-18 L1 cell adhesion molecule Homo sapiens 147-160 32633480-4 2020 The 2D- MOFs of L1 and L2 with Co(II) (1 & 3) and Ni(II) (2 & 4) have been produced via the conventional hydrothermal synthesis while the MOFs of Cu(II) (Cu@1 and Cu@3) are obtained by the post synthetic transmetallation reaction of MOFs 1 and 3. Nickel(2+) 50-56 L1 cell adhesion molecule Homo sapiens 16-25 32480027-8 2020 Increasing HAs concentration from 0 to 15 mg L-1 at pH 5.5 inhibited aggregations but enhanced dissolution of the uncoated and carbon-coated Cu-NPs. Carbon 127-133 L1 cell adhesion molecule Homo sapiens 45-48 32480027-8 2020 Increasing HAs concentration from 0 to 15 mg L-1 at pH 5.5 inhibited aggregations but enhanced dissolution of the uncoated and carbon-coated Cu-NPs. Copper 141-143 L1 cell adhesion molecule Homo sapiens 45-48 32531136-7 2020 Moreover, limits of detection and limits of the quantification were in the range of 3-10 mug L-1 and 7-30 mug L-1 in water and biological samples, respectively. Water 117-122 L1 cell adhesion molecule Homo sapiens 93-96 32531136-8 2020 Intra-day and inter-day precisions (n = 6) of the spiked methadone at a concentration level of 50 mug L-1 were over ranges of 5.1-6.8 % and 5.7-7.1 %, respectively. Methadone 57-66 L1 cell adhesion molecule Homo sapiens 102-105 32533901-7 2020 The limits of detection were within 0.16-0.51 mug L-1 , depending upon the triazine and the type of sample analyzed. Triazines 75-83 L1 cell adhesion molecule Homo sapiens 50-53 32312447-7 2020 The minimum detectable concentrations were far below the maximum concentration levels (60-200 mug L-1) set by the WHO for drinking water. Water 131-136 L1 cell adhesion molecule Homo sapiens 98-101 32633480-4 2020 The 2D- MOFs of L1 and L2 with Co(II) (1 & 3) and Ni(II) (2 & 4) have been produced via the conventional hydrothermal synthesis while the MOFs of Cu(II) (Cu@1 and Cu@3) are obtained by the post synthetic transmetallation reaction of MOFs 1 and 3. cu(ii) 146-152 L1 cell adhesion molecule Homo sapiens 16-25 32633480-4 2020 The 2D- MOFs of L1 and L2 with Co(II) (1 & 3) and Ni(II) (2 & 4) have been produced via the conventional hydrothermal synthesis while the MOFs of Cu(II) (Cu@1 and Cu@3) are obtained by the post synthetic transmetallation reaction of MOFs 1 and 3. Copper 146-148 L1 cell adhesion molecule Homo sapiens 16-25 32633480-4 2020 The 2D- MOFs of L1 and L2 with Co(II) (1 & 3) and Ni(II) (2 & 4) have been produced via the conventional hydrothermal synthesis while the MOFs of Cu(II) (Cu@1 and Cu@3) are obtained by the post synthetic transmetallation reaction of MOFs 1 and 3. Copper 154-156 L1 cell adhesion molecule Homo sapiens 16-25 32701083-8 2020 Limits of quantification were predominantly below 10 ng L-1, except for the ubiquitous oxazepam, quetiapine and temazepam, which were between 75-300 ng L-1. Oxazepam 87-95 L1 cell adhesion molecule Homo sapiens 152-155 32701083-8 2020 Limits of quantification were predominantly below 10 ng L-1, except for the ubiquitous oxazepam, quetiapine and temazepam, which were between 75-300 ng L-1. Temazepam 112-121 L1 cell adhesion molecule Homo sapiens 152-155 32289620-5 2020 With further increasing pH value to 6.0, the hydrolysis of Fe(III) was promoted to precipitate the arsenate for its immobilization, accompanying with the decrease of final iron ions and arsenate concentrations to 0.012 mmol L-1 and 58 mug L-1, respectively. ferric sulfate 59-66 L1 cell adhesion molecule Homo sapiens 224-227 32775894-4 2020 Distance-based detection of chloride was achieved by measuring the length of the colored band with a detection limit of 1.7 mg L-1 Cl-. Chlorides 28-36 L1 cell adhesion molecule Homo sapiens 127-130 32775894-5 2020 This method was used to detect chlorides in tap water, with an analytical result (10.1 +- 1.2 mg L-1) agreeing well with that obtained by a classical conventional precipitation titration (9.8 mg L-1), which was based on the measurement of the consumed volume of titrant. Chlorides 31-40 L1 cell adhesion molecule Homo sapiens 97-100 32775894-5 2020 This method was used to detect chlorides in tap water, with an analytical result (10.1 +- 1.2 mg L-1) agreeing well with that obtained by a classical conventional precipitation titration (9.8 mg L-1), which was based on the measurement of the consumed volume of titrant. Chlorides 31-40 L1 cell adhesion molecule Homo sapiens 195-198 32289620-5 2020 With further increasing pH value to 6.0, the hydrolysis of Fe(III) was promoted to precipitate the arsenate for its immobilization, accompanying with the decrease of final iron ions and arsenate concentrations to 0.012 mmol L-1 and 58 mug L-1, respectively. ferric sulfate 59-66 L1 cell adhesion molecule Homo sapiens 239-242 32289620-5 2020 With further increasing pH value to 6.0, the hydrolysis of Fe(III) was promoted to precipitate the arsenate for its immobilization, accompanying with the decrease of final iron ions and arsenate concentrations to 0.012 mmol L-1 and 58 mug L-1, respectively. arsenic acid 99-107 L1 cell adhesion molecule Homo sapiens 224-227 32289620-5 2020 With further increasing pH value to 6.0, the hydrolysis of Fe(III) was promoted to precipitate the arsenate for its immobilization, accompanying with the decrease of final iron ions and arsenate concentrations to 0.012 mmol L-1 and 58 mug L-1, respectively. arsenic acid 99-107 L1 cell adhesion molecule Homo sapiens 239-242 32302848-6 2020 After short time MIP treatment with an input power of 150 W, as high as 85.62% degradation efficiency was achieved for the fipronil at concentration of 20 mg L--1 under the optimized conditions, and the corresponding energy efficiency was 1334.8 mg kwh-1. fipronil 123-131 L1 cell adhesion molecule Homo sapiens 158-162 32661724-3 2020 Under the optimized conditions, the developed MIPs electrochemical sensor detects AMP with a low detection limit of 3.65 x 10-10 mol L-1 and shows outstanding reproducibility and stability. Adenosine Monophosphate 82-85 L1 cell adhesion molecule Homo sapiens 133-136 32661724-10 2020 Under the optimal conditions, the developed MIPs EC sensor can detect AMP with a low detection limit of 3.65 x 10-10 mol L-1. Adenosine Monophosphate 70-73 L1 cell adhesion molecule Homo sapiens 121-124 32733403-4 2020 Consortium ACE-3 was able to completely degrade 50 mg L-1 acetamiprid in 144 h, and was metabolically active at a wide range of pH values (6.0-8.0) and temperatures (20-42 C). acetamiprid 58-69 L1 cell adhesion molecule Homo sapiens 54-57 32646042-7 2020 The fabricated sensor could be used to efficiently detect H2O2, presenting a good linear relationship between the H2O2 concentration and the peak current, with quantification limit (LQ) of the 10.91 mumol L-1 and detection limit (LD) of 3.5913 mumol L-1. Hydrogen Peroxide 58-62 L1 cell adhesion molecule Homo sapiens 205-208 32646042-7 2020 The fabricated sensor could be used to efficiently detect H2O2, presenting a good linear relationship between the H2O2 concentration and the peak current, with quantification limit (LQ) of the 10.91 mumol L-1 and detection limit (LD) of 3.5913 mumol L-1. Hydrogen Peroxide 58-62 L1 cell adhesion molecule Homo sapiens 250-253 32646042-7 2020 The fabricated sensor could be used to efficiently detect H2O2, presenting a good linear relationship between the H2O2 concentration and the peak current, with quantification limit (LQ) of the 10.91 mumol L-1 and detection limit (LD) of 3.5913 mumol L-1. Hydrogen Peroxide 114-118 L1 cell adhesion molecule Homo sapiens 205-208 32646042-7 2020 The fabricated sensor could be used to efficiently detect H2O2, presenting a good linear relationship between the H2O2 concentration and the peak current, with quantification limit (LQ) of the 10.91 mumol L-1 and detection limit (LD) of 3.5913 mumol L-1. Hydrogen Peroxide 114-118 L1 cell adhesion molecule Homo sapiens 250-253 32623574-5 2020 The highest concentration levels in the samples taken from both types of water were 0.9 and 60 mug L-1 for BPA and DEHP, respectively. Water 73-78 L1 cell adhesion molecule Homo sapiens 99-102 32623574-5 2020 The highest concentration levels in the samples taken from both types of water were 0.9 and 60 mug L-1 for BPA and DEHP, respectively. bisphenol A 107-110 L1 cell adhesion molecule Homo sapiens 99-102 32623574-5 2020 The highest concentration levels in the samples taken from both types of water were 0.9 and 60 mug L-1 for BPA and DEHP, respectively. Diethylhexyl Phthalate 115-119 L1 cell adhesion molecule Homo sapiens 99-102 31273664-7 2020 A doping level of 0.21 mol% CuSO4 was identified as optimum condition to enable visible light photocatalysis of doped TiO2 catalysts calcined at 300 C. Finally, operational parameters were evaluated defining a wide range of pH operation under 3.0 g L-1 of catalyst dose to treat up to 20 g L-1 of highly recalcitrant phenothiazine dye. Copper Sulfate 28-33 L1 cell adhesion molecule Homo sapiens 250-253 32608896-5 2020 The results showed that the bottom water of the lower terrain rapidly entered the anaerobic condition after the system was deactivated, resulting in the release of a large amount of dissolved manganese into the overlying water, the maximum concentration of which was 0.42 mg L-1. Water 35-40 L1 cell adhesion molecule Homo sapiens 275-278 32608896-5 2020 The results showed that the bottom water of the lower terrain rapidly entered the anaerobic condition after the system was deactivated, resulting in the release of a large amount of dissolved manganese into the overlying water, the maximum concentration of which was 0.42 mg L-1. Manganese 192-201 L1 cell adhesion molecule Homo sapiens 275-278 32608896-6 2020 However, the bottom water of the higher terrain briefly entered a state of hypoxia, after which the dissolved oxygen concentration increased rapidly, so the dissolved manganese concentration increased moderately to 0.17 mg L-1. Manganese 167-176 L1 cell adhesion molecule Homo sapiens 223-226 32276204-2 2020 Treating synthetic secondary effluent at HRT 3 h, the PSAD system obtained the effluent with NO3--N 0.28 +- 0.14 mg L-1 and without PO43--P to be detected. no3--n 93-99 L1 cell adhesion molecule Homo sapiens 116-119 32443244-11 2020 The optimum removal percentage was 85.74% occurred at a pH of 5.6, chromium concentration of 150 mg L-1, and adsorbent concentration of 400 mg L-1. Chromium 67-75 L1 cell adhesion molecule Homo sapiens 100-103 32443244-11 2020 The optimum removal percentage was 85.74% occurred at a pH of 5.6, chromium concentration of 150 mg L-1, and adsorbent concentration of 400 mg L-1. adsorbent 109-118 L1 cell adhesion molecule Homo sapiens 143-146 32443213-4 2020 For alkylphenols concentrations ranged from 1.1 to 78.3 ng L-1 in wastewater and from 0.1 to 37.2 ng L-1 in surface water, while in drinking water concentrations varied from 0.4 to 7.9 ng L-1. alkylphenols 4-16 L1 cell adhesion molecule Homo sapiens 59-62 32443213-4 2020 For alkylphenols concentrations ranged from 1.1 to 78.3 ng L-1 in wastewater and from 0.1 to 37.2 ng L-1 in surface water, while in drinking water concentrations varied from 0.4 to 7.9 ng L-1. Water 71-76 L1 cell adhesion molecule Homo sapiens 59-62 32443213-4 2020 For alkylphenols concentrations ranged from 1.1 to 78.3 ng L-1 in wastewater and from 0.1 to 37.2 ng L-1 in surface water, while in drinking water concentrations varied from 0.4 to 7.9 ng L-1. Water 116-121 L1 cell adhesion molecule Homo sapiens 101-104 32443213-4 2020 For alkylphenols concentrations ranged from 1.1 to 78.3 ng L-1 in wastewater and from 0.1 to 37.2 ng L-1 in surface water, while in drinking water concentrations varied from 0.4 to 7.9 ng L-1. Water 116-121 L1 cell adhesion molecule Homo sapiens 101-104 32443213-9 2020 In drinking water, EEQt was below 1 ng L-1 in all samples. Water 12-17 L1 cell adhesion molecule Homo sapiens 39-42 32273329-6 2020 We developed poly(carboxybetaine-methacrylate) coated beads to isolate L1 cell adhesion molecule (L1CAM)-positive extracellular vesicles with characteristics of exosomes and used mass spectrometry or multiplexed electrochemiluminescence to measure exosomal proteins. polycarboxybetaine methacrylate 13-46 L1 cell adhesion molecule Homo sapiens 71-96 32273329-6 2020 We developed poly(carboxybetaine-methacrylate) coated beads to isolate L1 cell adhesion molecule (L1CAM)-positive extracellular vesicles with characteristics of exosomes and used mass spectrometry or multiplexed electrochemiluminescence to measure exosomal proteins. polycarboxybetaine methacrylate 13-46 L1 cell adhesion molecule Homo sapiens 98-103 32510411-3 2020 According to the LC50 of the isolated compounds, xylene (16.1 +- 2.4 mg L-1) was considered the most toxic, followed by toluene (38.0 +- 5.3 mg L-1) and, lastly, benzene (78.0 +- 2.9 mg L-1). Xylenes 49-55 L1 cell adhesion molecule Homo sapiens 72-75 32510356-6 2020 The lowest concentration of dissolved oxygen (3.6 mg L-1) was observed within the river plume. Oxygen 38-44 L1 cell adhesion molecule Homo sapiens 53-56 32302852-8 2020 Moreover, it could degrade high concentration acid orange 7 of up to 50 mg L-1 and achieve a high degradation efficiency of over 93%. 2-naphthol orange 46-57 L1 cell adhesion molecule Homo sapiens 75-78 31273664-7 2020 A doping level of 0.21 mol% CuSO4 was identified as optimum condition to enable visible light photocatalysis of doped TiO2 catalysts calcined at 300 C. Finally, operational parameters were evaluated defining a wide range of pH operation under 3.0 g L-1 of catalyst dose to treat up to 20 g L-1 of highly recalcitrant phenothiazine dye. Copper Sulfate 28-33 L1 cell adhesion molecule Homo sapiens 291-294 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. Benzo(a)pyrene 0-14 L1 cell adhesion molecule Homo sapiens 95-98 32583581-5 2020 An impressive removal capacity as high as 22 500 mg N g-1 CuPd ( 12 times superior to Fe-based catalysts), high nitrate conversion (>95%) and nitrogen selectivity (>95%) are achieved under a low initial concentration of nitrate (100 mg L-1 ) when using an optimized-NRR electrocatalyst (4CuPd@DCL-MCS/CNTs). Nitrates 220-227 L1 cell adhesion molecule Homo sapiens 236-239 32583581-6 2020 Remarkably, nitrate conversion and nitrogen selectivity are both close to 100% in an ultralow concentration of 10 mg L-1 , meeting drinking water standard. Nitrates 12-19 L1 cell adhesion molecule Homo sapiens 117-120 32583581-6 2020 Remarkably, nitrate conversion and nitrogen selectivity are both close to 100% in an ultralow concentration of 10 mg L-1 , meeting drinking water standard. Nitrogen 35-43 L1 cell adhesion molecule Homo sapiens 117-120 32583581-6 2020 Remarkably, nitrate conversion and nitrogen selectivity are both close to 100% in an ultralow concentration of 10 mg L-1 , meeting drinking water standard. Water 140-145 L1 cell adhesion molecule Homo sapiens 117-120 32339863-2 2020 A microcosm experiment was conducted to explore the chronic effects of ZnO nanoparticle at environmental concentrations (30, 300, 3000 ng L-1) on aquatic fungi associated with the decomposing process of poplar leaf litter (45 days). Zinc Oxide 71-74 L1 cell adhesion molecule Homo sapiens 138-141 32339863-5 2020 After chronic exposure, the fungal community structure was significantly impacted by ZnO nanoparticles at 300 ng L-1 due to the reduced proportion of Anguillospora, which eventually caused a significant decrease in litter decomposition rate. Zinc Oxide 85-88 L1 cell adhesion molecule Homo sapiens 113-116 32629854-1 2020 Carbon-nanofiber-based screen-printed electrodes modified with silver nanoparticles (Ag-NP-SPCNFEs) were tested in a pioneering manner for the direct determination of As(V) at low mug L-1 levels by means of differential pulse anodic stripping voltammetry. Carbon 0-6 L1 cell adhesion molecule Homo sapiens 184-187 32629854-1 2020 Carbon-nanofiber-based screen-printed electrodes modified with silver nanoparticles (Ag-NP-SPCNFEs) were tested in a pioneering manner for the direct determination of As(V) at low mug L-1 levels by means of differential pulse anodic stripping voltammetry. asunaprevir 167-172 L1 cell adhesion molecule Homo sapiens 184-187 32629854-4 2020 These results suggest that Ag-NS offer a better analytical response compared to Ag-NPr, with a detection and quantification limit of 0.6 and 1.9 microg L-1, respectively. ag-ns 27-32 L1 cell adhesion molecule Homo sapiens 152-155 32610617-3 2020 H2O2 was administered at 4 microg L-1 and a combination of fluorometry, microscopy, flow cytometry, and high throughput DNA sequencing were used to quantify the effects on eukaryotic and prokaryotic plankton communities. Hydrogen Peroxide 0-4 L1 cell adhesion molecule Homo sapiens 34-37 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. Benzo(a)pyrene 0-14 L1 cell adhesion molecule Homo sapiens 110-113 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. Benzo(a)pyrene 0-14 L1 cell adhesion molecule Homo sapiens 110-113 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. Benzo(a)pyrene 0-14 L1 cell adhesion molecule Homo sapiens 110-113 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. bapeq 48-53 L1 cell adhesion molecule Homo sapiens 95-98 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. bapeq 48-53 L1 cell adhesion molecule Homo sapiens 110-113 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. bapeq 48-53 L1 cell adhesion molecule Homo sapiens 110-113 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. bapeq 48-53 L1 cell adhesion molecule Homo sapiens 110-113 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. Polycyclic Aromatic Hydrocarbons 70-74 L1 cell adhesion molecule Homo sapiens 95-98 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. Polycyclic Aromatic Hydrocarbons 70-74 L1 cell adhesion molecule Homo sapiens 110-113 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. Polycyclic Aromatic Hydrocarbons 70-74 L1 cell adhesion molecule Homo sapiens 110-113 32229384-8 2020 Benzo[a]pyrene-equivalent toxic concentrations (BaPeq) of the Sigma17 PAHs ranged from 0.07 ng L-1 to 2.26 ng L-1 (0.62 +- 0.52 ng L-1, mean +- standard deviation) with a median of 0.47 ng L-1. Polycyclic Aromatic Hydrocarbons 70-74 L1 cell adhesion molecule Homo sapiens 110-113 32637807-6 2020 The brewing technique had a major influence on the Al content in the beverage: significantly higher Al concentrations (72.57 +- 23.96 mug L-1) occurred in coffee brewed in an aluminum moka pot. Aluminum 100-102 L1 cell adhesion molecule Homo sapiens 138-141 32498610-4 2022 The degradation efficiency reached 100% within 13 min (the concentration of NOR and S2O8 2- were 100 mg L-1 and 1 mM, respectively; m(NGO-Fe3O4): m(PDS) =4 : 1; pH: 3.0). Norfloxacin 76-79 L1 cell adhesion molecule Homo sapiens 104-116 32498610-4 2022 The degradation efficiency reached 100% within 13 min (the concentration of NOR and S2O8 2- were 100 mg L-1 and 1 mM, respectively; m(NGO-Fe3O4): m(PDS) =4 : 1; pH: 3.0). s2o8 84-88 L1 cell adhesion molecule Homo sapiens 104-116 32250883-8 2020 Furthermore, free chlorine at the concentration of 1 mg L-1 was generated through chloride ion oxidation in the anode, which can be effective for disinfection. Chlorine 18-26 L1 cell adhesion molecule Homo sapiens 56-59 32250883-8 2020 Furthermore, free chlorine at the concentration of 1 mg L-1 was generated through chloride ion oxidation in the anode, which can be effective for disinfection. Chlorides 82-90 L1 cell adhesion molecule Homo sapiens 56-59 32533378-8 2020 Median concentrations of E2 and EE2 were 19 and 5 ng L-1, respectively, downstream of WWTP inputs, concentrations known to affect reproductive processes of aquatic biota and impair human health. Estradiol 25-27 L1 cell adhesion molecule Homo sapiens 53-56 32251885-5 2020 The methodology allows quantifying polychlorinated biphenyls at very trace levels, with limits of detection between 0.2 and 1.7 ng L-1. Polychlorinated Biphenyls 35-60 L1 cell adhesion molecule Homo sapiens 131-134 32608788-2 2020 Iron, manganese and ammonia [Fe(II) 0-19.26 mg L-1, Mn(II) 0.52-2.05 mg L-1, and NH4+-N 0.37-2.59 mg L-1] were analyzed to explore the ammonia nitrogen removal efficiency under different iron and manganese concentrations. Ammonia 20-27 L1 cell adhesion molecule Homo sapiens 47-50 32608788-3 2020 The results showed that when the concentration of manganese in the inlet water was maintained at approximately 0.6 mg L-1 and the concentration of ferrous iron in the inlet water was increased, with the increase of iron oxides in the filter layer, the ratio of ammonia nitrogen removed by adsorption of iron oxides increased, while the ratio of ammonia nitrogen removed by nitrification will decreased and adsorption preceded nitrification. Manganese 50-59 L1 cell adhesion molecule Homo sapiens 118-121 32608788-4 2020 When the concentration of ferrous iron in the water was maintained at approximately 8 mg L-1and 11 mg L-1, and the concentration of manganese in the water was increased, the proportion of ammonia nitrogen removed by adsorption did not increase with the increase of manganese oxide, and the removal route of ammonia nitrogen hardly changed. ferrous iron 26-38 L1 cell adhesion molecule Homo sapiens 89-92 32608789-5 2020 The degradation efficiency of RBK5 (20 mg L-1) could reach 86% within 90 min when the Mn/Fe molar ratio was 1, the catalyst dosage was 0.2 g L-1, the PMS concentration was 1 mmol L-1, and the initial pH value was 7.0. peroxymonosulfate 150-153 L1 cell adhesion molecule Homo sapiens 42-45 32608796-2 2020 The results showed that when the autotrophic nitrogen removal and denitrification were operated stably for 67 days at an initial COD concentration of 60 mg L-1, the maximum nitrogen removal efficiency, the COD removal rate, and the nitrogen removal rate were 92.0%, 82.9%, and 2.3 kg (m3 d)-1, respectively. Nitrogen 45-53 L1 cell adhesion molecule Homo sapiens 156-159 32608796-2 2020 The results showed that when the autotrophic nitrogen removal and denitrification were operated stably for 67 days at an initial COD concentration of 60 mg L-1, the maximum nitrogen removal efficiency, the COD removal rate, and the nitrogen removal rate were 92.0%, 82.9%, and 2.3 kg (m3 d)-1, respectively. Nitrogen 173-181 L1 cell adhesion molecule Homo sapiens 156-159 32608796-2 2020 The results showed that when the autotrophic nitrogen removal and denitrification were operated stably for 67 days at an initial COD concentration of 60 mg L-1, the maximum nitrogen removal efficiency, the COD removal rate, and the nitrogen removal rate were 92.0%, 82.9%, and 2.3 kg (m3 d)-1, respectively. Nitrogen 173-181 L1 cell adhesion molecule Homo sapiens 156-159 32608797-4 2020 Under the same hydroxylamine concentration (HA=5 mg L-1) at a higher pH environment (pH >= 7.5), hydroxylamine produced more free hydroxylamine (FHA) and the inhibitory effect on Nitrobacter was improved. Hydroxylamine 97-110 L1 cell adhesion molecule Homo sapiens 52-55 32608797-4 2020 Under the same hydroxylamine concentration (HA=5 mg L-1) at a higher pH environment (pH >= 7.5), hydroxylamine produced more free hydroxylamine (FHA) and the inhibitory effect on Nitrobacter was improved. Hydroxylamine 97-110 L1 cell adhesion molecule Homo sapiens 52-55 32608797-7 2020 When pH=7.5 and hydroxylamine concentration was 45 mg L-1, the relative activity of Nitrospira was 82%. Hydroxylamine 16-29 L1 cell adhesion molecule Homo sapiens 54-57 32353225-6 2020 Almost 2,000 lakes are predicted to have chloride concentrations above 50 mg L-1 and should be monitored. Chlorides 41-49 L1 cell adhesion molecule Homo sapiens 77-80 31606810-7 2020 CONCLUSION: MOLLI T1-mapping sequences may be used for detecting dissolved oxygen in vivo at 3 T with an [Formula: see text] in the range 4.18-4.8 x 10-3 s-1 mg-1 L and a corresponding LOD for dissolved oxygen of approximately 10 mg L-1. Oxygen 75-81 L1 cell adhesion molecule Homo sapiens 233-236 32279817-16 2020 The viability (%) of HeLa cells declined significantly at 10 mg L-1 concentration of AgNP and complete mortality was observed at a concentration of 60 mg L-1. agnp 85-89 L1 cell adhesion molecule Homo sapiens 64-67 32784276-8 2020 In the ozonation with 30 mg L-1 T2-MOF, the COD removal rate of 100 mg L-1 succinonitrile reached 73.1% (+-4.6%) within 180 min, which was 67.3% (+-4.4%) higher than that obtained in the process without catalyst. succinonitrile 75-89 L1 cell adhesion molecule Homo sapiens 28-31 32784276-8 2020 In the ozonation with 30 mg L-1 T2-MOF, the COD removal rate of 100 mg L-1 succinonitrile reached 73.1% (+-4.6%) within 180 min, which was 67.3% (+-4.4%) higher than that obtained in the process without catalyst. succinonitrile 75-89 L1 cell adhesion molecule Homo sapiens 71-74 32533378-8 2020 Median concentrations of E2 and EE2 were 19 and 5 ng L-1, respectively, downstream of WWTP inputs, concentrations known to affect reproductive processes of aquatic biota and impair human health. Norinyl 32-35 L1 cell adhesion molecule Homo sapiens 53-56 32608839-5 2020 The total concentration of PAHs was in the range of 37.27 to 285.88 ng L-1 with a mean value of 78.31 ng L-1, while the monomer concentration of PAHs ranged from 0 to 61.35 ng L-1. Polycyclic Aromatic Hydrocarbons 27-31 L1 cell adhesion molecule Homo sapiens 71-74 32329336-5 2020 The limit of detection of PFOA in ultrapure water was 11.0 ng L-1. Water 44-49 L1 cell adhesion molecule Homo sapiens 62-65 32596113-6 2020 Moreover, an ultra-high volumetric energy density of 2727 Wh L-1 -cathode is achieved based on the densification effect with higher density (1.69 g cm-3), which is competitive to the Ni-rich oxide cathode (1800-2160 Wh L-1) of lithium-ion batteries. ni-rich oxide 183-196 L1 cell adhesion molecule Homo sapiens 61-64 32596113-6 2020 Moreover, an ultra-high volumetric energy density of 2727 Wh L-1 -cathode is achieved based on the densification effect with higher density (1.69 g cm-3), which is competitive to the Ni-rich oxide cathode (1800-2160 Wh L-1) of lithium-ion batteries. Lithium 227-234 L1 cell adhesion molecule Homo sapiens 61-64 32536688-8 2021 Finally, our data suggested sex differences in serine-312 phosphorylation of IRS-1 in L1CAM+ exosomes in subjects with MDD. Serine 47-53 L1 cell adhesion molecule Homo sapiens 86-91 32342067-7 2020 At 1.2 V voltage, its desalination capacity and rate reach 17.8 mg g-1 and 1.12 mg g-1 min-1 in 600 mg L-1 NaCl. Sodium Chloride 107-111 L1 cell adhesion molecule Homo sapiens 103-106 32608839-5 2020 The total concentration of PAHs was in the range of 37.27 to 285.88 ng L-1 with a mean value of 78.31 ng L-1, while the monomer concentration of PAHs ranged from 0 to 61.35 ng L-1. Polycyclic Aromatic Hydrocarbons 27-31 L1 cell adhesion molecule Homo sapiens 105-108 32608844-6 2020 The total concentrations of antibiotics in surface water ranged from 1.12 ng L-1 to 53.74 ng L-1. Water 51-56 L1 cell adhesion molecule Homo sapiens 77-80 32608839-5 2020 The total concentration of PAHs was in the range of 37.27 to 285.88 ng L-1 with a mean value of 78.31 ng L-1, while the monomer concentration of PAHs ranged from 0 to 61.35 ng L-1. Polycyclic Aromatic Hydrocarbons 27-31 L1 cell adhesion molecule Homo sapiens 105-108 32608844-6 2020 The total concentrations of antibiotics in surface water ranged from 1.12 ng L-1 to 53.74 ng L-1. Water 51-56 L1 cell adhesion molecule Homo sapiens 93-96 32608839-7 2020 As a toxic PAH monomer, the concentration of benzo[a] pyrene ranged from 0 to 11.08 ng L-1. Benzo(a)pyrene 45-60 L1 cell adhesion molecule Homo sapiens 87-90 32608839-8 2020 According to "Water Quality Standards for Drinking Water Sources (CJ 3020-1993)" of China, the concentration of benzo[a] pyrene in a water sample (S12) located near Wuxi City exceeded the limit of drinking water standards (10 ng L-1). Benzo(a)pyrene 112-127 L1 cell adhesion molecule Homo sapiens 229-232 32701503-6 2020 For example, when the initial concentration of PNP was 4,000 mg L-1, and the dosage of Fe2+ was 109 mg L-1 (H2O2/Fe2+ = 200), the removal rates of COD and TOC at 85 C reached 95% and 71% respectively. 4-nitrophenol 47-50 L1 cell adhesion molecule Homo sapiens 64-67 32608847-5 2020 The PO43- with low-concentration (2 mmol L-1), humic acid and fulvic acid (2 mg L-1 and 10 mg L-1) loaded on iron mineral nanoparticles changed their surface charge and further improved the stability of FHNPs and GTNPs at medium and high pH. po43 4-8 L1 cell adhesion molecule Homo sapiens 80-90 32608847-5 2020 The PO43- with low-concentration (2 mmol L-1), humic acid and fulvic acid (2 mg L-1 and 10 mg L-1) loaded on iron mineral nanoparticles changed their surface charge and further improved the stability of FHNPs and GTNPs at medium and high pH. fulvic acid 62-73 L1 cell adhesion molecule Homo sapiens 80-90 32608847-5 2020 The PO43- with low-concentration (2 mmol L-1), humic acid and fulvic acid (2 mg L-1 and 10 mg L-1) loaded on iron mineral nanoparticles changed their surface charge and further improved the stability of FHNPs and GTNPs at medium and high pH. Iron 109-113 L1 cell adhesion molecule Homo sapiens 80-90 32608847-5 2020 The PO43- with low-concentration (2 mmol L-1), humic acid and fulvic acid (2 mg L-1 and 10 mg L-1) loaded on iron mineral nanoparticles changed their surface charge and further improved the stability of FHNPs and GTNPs at medium and high pH. gtnps 213-218 L1 cell adhesion molecule Homo sapiens 80-90 32608855-5 2020 The removal rates of NH4+-N and NO2--N were 94% and 97%, respectively, and the NO3--N concentration in the effluent was stable at 22 mg L-1. no3--n 79-85 L1 cell adhesion molecule Homo sapiens 136-139 32303795-7 2020 A quantification limit of 11.3 NH4+mg L-1 and linear application range from up to 150 NH4+mg L-1 were obtained making it suitable for the expected concentrations of total ammonia nitrogen in human saliva. Nitrogen 179-187 L1 cell adhesion molecule Homo sapiens 38-41 32303795-7 2020 A quantification limit of 11.3 NH4+mg L-1 and linear application range from up to 150 NH4+mg L-1 were obtained making it suitable for the expected concentrations of total ammonia nitrogen in human saliva. Nitrogen 179-187 L1 cell adhesion molecule Homo sapiens 93-96 32172419-3 2020 And the 10 g L-1 of PEI modified AC (PAC-30) has the highest adsorption capacity of formaldehyde, reached to 650 mg g-1, with an increasing magnitude of 240% in comparison with that without modified AC. Formaldehyde 84-96 L1 cell adhesion molecule Homo sapiens 13-35 32148292-6 2020 As regards the Freundlich model, the values of the adsorption constant (KF, expressed in L1/n mumol1-1/n kg-1), were in the range 0.4-1.9 for SDZ, 0.9-2.9 for SMT, and 1.2-3.8 for SCP. Sulfadiazine 142-145 L1 cell adhesion molecule Homo sapiens 89-102 31635654-3 2020 A 98.4% photodegradation of 2,3-dichlorophenol (50 mg L-1) was attained in the presence of Bi2WO6/NaBiO3 (1:10) under the visible-light irradiation in 30 min. 2,3-dichlorophenol 28-46 L1 cell adhesion molecule Homo sapiens 54-57 31635654-3 2020 A 98.4% photodegradation of 2,3-dichlorophenol (50 mg L-1) was attained in the presence of Bi2WO6/NaBiO3 (1:10) under the visible-light irradiation in 30 min. Sodium 98-104 L1 cell adhesion molecule Homo sapiens 54-57 32701503-6 2020 For example, when the initial concentration of PNP was 4,000 mg L-1, and the dosage of Fe2+ was 109 mg L-1 (H2O2/Fe2+ = 200), the removal rates of COD and TOC at 85 C reached 95% and 71% respectively. 4-nitrophenol 47-50 L1 cell adhesion molecule Homo sapiens 103-106 32701503-6 2020 For example, when the initial concentration of PNP was 4,000 mg L-1, and the dosage of Fe2+ was 109 mg L-1 (H2O2/Fe2+ = 200), the removal rates of COD and TOC at 85 C reached 95% and 71% respectively. ammonium ferrous sulfate 87-91 L1 cell adhesion molecule Homo sapiens 103-106 32701503-6 2020 For example, when the initial concentration of PNP was 4,000 mg L-1, and the dosage of Fe2+ was 109 mg L-1 (H2O2/Fe2+ = 200), the removal rates of COD and TOC at 85 C reached 95% and 71% respectively. Hydrogen Peroxide 108-112 L1 cell adhesion molecule Homo sapiens 103-106 32701503-7 2020 Both were higher than the 93% COD removal rate and 44% TOC removal rate when the dosage of Fe2+ was 1,092 mg L-1 (H2O2/Fe2+ = 20) at room temperature. ammonium ferrous sulfate 91-95 L1 cell adhesion molecule Homo sapiens 109-112 32701503-7 2020 Both were higher than the 93% COD removal rate and 44% TOC removal rate when the dosage of Fe2+ was 1,092 mg L-1 (H2O2/Fe2+ = 20) at room temperature. Hydrogen Peroxide 114-118 L1 cell adhesion molecule Homo sapiens 109-112 32608668-7 2020 The highest concentrations of acesulfame, saccharin, aspartame, and neotame in source water were 22.94, 39.17, 0.73, and 8.92 mug L-1, respectively, and detection rates were 72.7%, 90.9%, 18.2%, and 90.9%, respectively. Saccharin 42-51 L1 cell adhesion molecule Homo sapiens 130-133 32373749-9 2020 The materials removed phosphate from three polluted water samples having phosphate concentrations between 0.0919 and 1.211 mg L-1. Phosphates 22-31 L1 cell adhesion molecule Homo sapiens 126-129 32373749-11 2020 The presence of 10 mg L-1 humic of fulvic acid did not affect the performance of the materials. fulvic acid 35-46 L1 cell adhesion molecule Homo sapiens 22-25 32264767-3 2021 The addition of 0.5 g L-1 zeolite to a continuously-fed membrane photobioreactor increased the microalgal biomass concentration from 0.50 to 0.90-1.17 g particulate organic carbon per L while the average ammonium removal efficiency increased from 14% to 30%. Carbon 173-179 L1 cell adhesion molecule Homo sapiens 22-25 32264767-3 2021 The addition of 0.5 g L-1 zeolite to a continuously-fed membrane photobioreactor increased the microalgal biomass concentration from 0.50 to 0.90-1.17 g particulate organic carbon per L while the average ammonium removal efficiency increased from 14% to 30%. Ammonium Compounds 204-212 L1 cell adhesion molecule Homo sapiens 22-25 32264767-5 2021 With higher zeolite doses (1 and 5 g L-1) inside the reactor, however, the breaking apart of added zeolite particles into finer particles dramatically increased solution turbidity, which likely was not beneficial for microalgal growth and ammonium removal due to reduced light penetration. Zeolites 12-19 L1 cell adhesion molecule Homo sapiens 37-40 32608665-4 2020 The results show that approximately 7.83% of rivers in China exceeded the Chinese drinking water standard for nitrate (45 mg L-1). Nitrates 110-117 L1 cell adhesion molecule Homo sapiens 125-128 32608668-7 2020 The highest concentrations of acesulfame, saccharin, aspartame, and neotame in source water were 22.94, 39.17, 0.73, and 8.92 mug L-1, respectively, and detection rates were 72.7%, 90.9%, 18.2%, and 90.9%, respectively. acetosulfame 30-40 L1 cell adhesion molecule Homo sapiens 130-133 32601506-1 2020 Two new chemosensors, rhodamine B derivative bearing 3-formyl-6-nitrochromone (L 1 ) and 3-formyl-6-methylchromone (L 2 ) units were designed and synthesized using microwave irradiation for the selective detection of Cu2+ in aqueous media. rhodamine B 22-33 L1 cell adhesion molecule Homo sapiens 79-82 32601506-1 2020 Two new chemosensors, rhodamine B derivative bearing 3-formyl-6-nitrochromone (L 1 ) and 3-formyl-6-methylchromone (L 2 ) units were designed and synthesized using microwave irradiation for the selective detection of Cu2+ in aqueous media. 3-Formyl-6-nitrochromone 53-77 L1 cell adhesion molecule Homo sapiens 79-82 32252408-13 2020 The concentrations were variable and ranged from ng L-1 in some compounds like diclofenac or carbamazepine to microg L-1 in common pharmaceutical compounds such as caffeine, naproxen or ibuprofen. Caffeine 164-172 L1 cell adhesion molecule Homo sapiens 117-120 32252408-13 2020 The concentrations were variable and ranged from ng L-1 in some compounds like diclofenac or carbamazepine to microg L-1 in common pharmaceutical compounds such as caffeine, naproxen or ibuprofen. Naproxen 174-182 L1 cell adhesion molecule Homo sapiens 117-120 32252408-13 2020 The concentrations were variable and ranged from ng L-1 in some compounds like diclofenac or carbamazepine to microg L-1 in common pharmaceutical compounds such as caffeine, naproxen or ibuprofen. Ibuprofen 186-195 L1 cell adhesion molecule Homo sapiens 117-120 32028148-4 2020 After the dark fermentation, the volatile fatty acids (VFAs) including acetate and butyrate, were detected in the waste, with concentration determined as 1.04 g L-1 and 1.52 g L-1, respectively. Fatty Acids 42-53 L1 cell adhesion molecule Homo sapiens 161-170 32028148-4 2020 After the dark fermentation, the volatile fatty acids (VFAs) including acetate and butyrate, were detected in the waste, with concentration determined as 1.04 g L-1 and 1.52 g L-1, respectively. Fatty Acids 42-53 L1 cell adhesion molecule Homo sapiens 161-164 32028148-4 2020 After the dark fermentation, the volatile fatty acids (VFAs) including acetate and butyrate, were detected in the waste, with concentration determined as 1.04 g L-1 and 1.52 g L-1, respectively. Acetates 71-78 L1 cell adhesion molecule Homo sapiens 161-170 32028148-4 2020 After the dark fermentation, the volatile fatty acids (VFAs) including acetate and butyrate, were detected in the waste, with concentration determined as 1.04 g L-1 and 1.52 g L-1, respectively. Butyrates 83-91 L1 cell adhesion molecule Homo sapiens 161-170 32028148-4 2020 After the dark fermentation, the volatile fatty acids (VFAs) including acetate and butyrate, were detected in the waste, with concentration determined as 1.04 g L-1 and 1.52 g L-1, respectively. Butyrates 83-91 L1 cell adhesion molecule Homo sapiens 161-164 31983004-3 2020 The initial pH value significantly influenced on the degradation of p-ASA and at the optimal pH (3.0), p-ASA (10 mg L-1) could be completely oxidized to As(V), NH4+, and plentiful phenolic compounds such as phenol and p-hydroquinone via the cleavage of C-N and C-As bonds within 60 min in pure water. Arsanilic Acid 68-73 L1 cell adhesion molecule Homo sapiens 116-119 31983004-3 2020 The initial pH value significantly influenced on the degradation of p-ASA and at the optimal pH (3.0), p-ASA (10 mg L-1) could be completely oxidized to As(V), NH4+, and plentiful phenolic compounds such as phenol and p-hydroquinone via the cleavage of C-N and C-As bonds within 60 min in pure water. Arsanilic Acid 103-108 L1 cell adhesion molecule Homo sapiens 116-119 31983004-3 2020 The initial pH value significantly influenced on the degradation of p-ASA and at the optimal pH (3.0), p-ASA (10 mg L-1) could be completely oxidized to As(V), NH4+, and plentiful phenolic compounds such as phenol and p-hydroquinone via the cleavage of C-N and C-As bonds within 60 min in pure water. Arsenic 153-155 L1 cell adhesion molecule Homo sapiens 116-119 31983004-3 2020 The initial pH value significantly influenced on the degradation of p-ASA and at the optimal pH (3.0), p-ASA (10 mg L-1) could be completely oxidized to As(V), NH4+, and plentiful phenolic compounds such as phenol and p-hydroquinone via the cleavage of C-N and C-As bonds within 60 min in pure water. Ammonium Compounds 160-164 L1 cell adhesion molecule Homo sapiens 116-119 31983004-3 2020 The initial pH value significantly influenced on the degradation of p-ASA and at the optimal pH (3.0), p-ASA (10 mg L-1) could be completely oxidized to As(V), NH4+, and plentiful phenolic compounds such as phenol and p-hydroquinone via the cleavage of C-N and C-As bonds within 60 min in pure water. Phenol 180-186 L1 cell adhesion molecule Homo sapiens 116-119 31983004-3 2020 The initial pH value significantly influenced on the degradation of p-ASA and at the optimal pH (3.0), p-ASA (10 mg L-1) could be completely oxidized to As(V), NH4+, and plentiful phenolic compounds such as phenol and p-hydroquinone via the cleavage of C-N and C-As bonds within 60 min in pure water. hydroquinone 218-232 L1 cell adhesion molecule Homo sapiens 116-119 31983004-3 2020 The initial pH value significantly influenced on the degradation of p-ASA and at the optimal pH (3.0), p-ASA (10 mg L-1) could be completely oxidized to As(V), NH4+, and plentiful phenolic compounds such as phenol and p-hydroquinone via the cleavage of C-N and C-As bonds within 60 min in pure water. Water 294-299 L1 cell adhesion molecule Homo sapiens 116-119 31983004-4 2020 Meanwhile, although the formed lepidocrocite and magnetite on the surface of SiO2-nZVI significantly limited the reutilization, they played a vital role in the adsorption of the released As(V) and the residual arsenic levels in the effluent were as low as 0.031 mg L-1, meeting both the drinking water standard of the World Health Organization (WHO) and the surface water standard of China (0.05 mg L-1). ferric oxide 31-44 L1 cell adhesion molecule Homo sapiens 265-268 31983004-4 2020 Meanwhile, although the formed lepidocrocite and magnetite on the surface of SiO2-nZVI significantly limited the reutilization, they played a vital role in the adsorption of the released As(V) and the residual arsenic levels in the effluent were as low as 0.031 mg L-1, meeting both the drinking water standard of the World Health Organization (WHO) and the surface water standard of China (0.05 mg L-1). ferric oxide 31-44 L1 cell adhesion molecule Homo sapiens 399-402 31983004-4 2020 Meanwhile, although the formed lepidocrocite and magnetite on the surface of SiO2-nZVI significantly limited the reutilization, they played a vital role in the adsorption of the released As(V) and the residual arsenic levels in the effluent were as low as 0.031 mg L-1, meeting both the drinking water standard of the World Health Organization (WHO) and the surface water standard of China (0.05 mg L-1). Silicon Dioxide 77-81 L1 cell adhesion molecule Homo sapiens 265-268 31983004-4 2020 Meanwhile, although the formed lepidocrocite and magnetite on the surface of SiO2-nZVI significantly limited the reutilization, they played a vital role in the adsorption of the released As(V) and the residual arsenic levels in the effluent were as low as 0.031 mg L-1, meeting both the drinking water standard of the World Health Organization (WHO) and the surface water standard of China (0.05 mg L-1). Silicon Dioxide 77-81 L1 cell adhesion molecule Homo sapiens 399-402 32230816-7 2020 At the studied concentrations (40 mg L-1, 80 mg L-1, 120 mg L-1), ZnO NPs had obvious impacts on the activity of Proteobacteria. Zinc Oxide 66-69 L1 cell adhesion molecule Homo sapiens 37-40 32230816-7 2020 At the studied concentrations (40 mg L-1, 80 mg L-1, 120 mg L-1), ZnO NPs had obvious impacts on the activity of Proteobacteria. Zinc Oxide 66-69 L1 cell adhesion molecule Homo sapiens 48-51 32230816-7 2020 At the studied concentrations (40 mg L-1, 80 mg L-1, 120 mg L-1), ZnO NPs had obvious impacts on the activity of Proteobacteria. Zinc Oxide 66-69 L1 cell adhesion molecule Homo sapiens 48-51 32230816-11 2020 The group with NP concentration (40 mg L-1) had the lowest AWCD value; those of the groups with high NP concentrations (80 mg L-1, 120 mg L-1) were slightly lower than that of the control group. Neptunium 15-17 L1 cell adhesion molecule Homo sapiens 39-42 32192127-4 2020 Meanwhile, the electrochemical behaviour of GA on the surface of the modified electrode was studied using differential pulse voltammetry (DPV), showing a sensitivity of the electrode for GA determination, within a concentration range of 1 x 10-6 mol L-1 to 1 x 10-3 mol L-1 with a correlation coefficient of R2 of 0.9945 and a limit of detection of 1.24 x 10-7 mol L-1 (S/N = 3). Gallic Acid 44-46 L1 cell adhesion molecule Homo sapiens 250-265 32192127-4 2020 Meanwhile, the electrochemical behaviour of GA on the surface of the modified electrode was studied using differential pulse voltammetry (DPV), showing a sensitivity of the electrode for GA determination, within a concentration range of 1 x 10-6 mol L-1 to 1 x 10-3 mol L-1 with a correlation coefficient of R2 of 0.9945 and a limit of detection of 1.24 x 10-7 mol L-1 (S/N = 3). Gallic Acid 187-189 L1 cell adhesion molecule Homo sapiens 250-265 31740318-4 2020 Under the optimal conditions, good linear relationship was obtained in the range of 0.05-200 mug L-1 for Cd2+ and 0.1-200 mug L-1 for Hg2+, and the limits of detection were 0.016 and 0.040 mug L-1, respectively. Mercury 134-138 L1 cell adhesion molecule Homo sapiens 97-100 32135470-6 2020 The initial biomass concentration of 3 g L-1 gave the best result on biomass productivity and CO2 fixation which reached 143.4 mg L-1 h-1 and 224 mg L-1 h-1 respectively. N2,N6-bis(4-(2-aminoethoxy)quinolin-2-yl)-4-((4-fluorobenzyl)oxy)pyridine-2,6-dicarboxamide 94-97 L1 cell adhesion molecule Homo sapiens 41-44 32235335-6 2020 The proposed method is characterized by a working range of 2.7-150.0 mug L-1 of NH4+, with a detection and quantification limit of 0.80 and 2.66 mug L-1, respectively, for a 10-mL sample consumption. Ammonium Compounds 80-84 L1 cell adhesion molecule Homo sapiens 73-76 32235335-6 2020 The proposed method is characterized by a working range of 2.7-150.0 mug L-1 of NH4+, with a detection and quantification limit of 0.80 and 2.66 mug L-1, respectively, for a 10-mL sample consumption. Ammonium Compounds 80-84 L1 cell adhesion molecule Homo sapiens 149-152 32148171-7 2021 The treated effluent that received 20% of leachate showed 2.7 mg L-1 ammonia and 1.1 mg L-1 nitrate. Ammonia 69-76 L1 cell adhesion molecule Homo sapiens 65-68 32148171-7 2021 The treated effluent that received 20% of leachate showed 2.7 mg L-1 ammonia and 1.1 mg L-1 nitrate. Nitrates 92-99 L1 cell adhesion molecule Homo sapiens 88-91 32017423-1 2020 In this paper, we have used two N,O-ketiminato ligands ( L1 and L2 ) with biphenyl and terphenyl substituent on the nitrogen atom. Superoxides 32-46 L1 cell adhesion molecule Homo sapiens 57-66 32017423-1 2020 In this paper, we have used two N,O-ketiminato ligands ( L1 and L2 ) with biphenyl and terphenyl substituent on the nitrogen atom. diphenyl 74-82 L1 cell adhesion molecule Homo sapiens 57-66 32017423-1 2020 In this paper, we have used two N,O-ketiminato ligands ( L1 and L2 ) with biphenyl and terphenyl substituent on the nitrogen atom. Terphenyl Compounds 87-96 L1 cell adhesion molecule Homo sapiens 57-66 32017423-1 2020 In this paper, we have used two N,O-ketiminato ligands ( L1 and L2 ) with biphenyl and terphenyl substituent on the nitrogen atom. Nitrogen 116-124 L1 cell adhesion molecule Homo sapiens 57-66 32017423-7 2020 More diverse results were obtained when lithiated L1 and L2 were treated with germanium dichloride. Germanium 78-98 L1 cell adhesion molecule Homo sapiens 50-59 32608668-7 2020 The highest concentrations of acesulfame, saccharin, aspartame, and neotame in source water were 22.94, 39.17, 0.73, and 8.92 mug L-1, respectively, and detection rates were 72.7%, 90.9%, 18.2%, and 90.9%, respectively. Aspartame 53-62 L1 cell adhesion molecule Homo sapiens 130-133 32608668-7 2020 The highest concentrations of acesulfame, saccharin, aspartame, and neotame in source water were 22.94, 39.17, 0.73, and 8.92 mug L-1, respectively, and detection rates were 72.7%, 90.9%, 18.2%, and 90.9%, respectively. neotame 68-75 L1 cell adhesion molecule Homo sapiens 130-133 32608668-7 2020 The highest concentrations of acesulfame, saccharin, aspartame, and neotame in source water were 22.94, 39.17, 0.73, and 8.92 mug L-1, respectively, and detection rates were 72.7%, 90.9%, 18.2%, and 90.9%, respectively. Water 86-91 L1 cell adhesion molecule Homo sapiens 130-133 32608686-2 2020 The finding indicated that in an intermittent operation mode, the average concentration of total nitrogen and ammonia nitrogen in the effluent could reach 1.05 mg L-1 and 0.54 mg L-1, and the average removal rate was 94.77% and 93.30%, respectively. Nitrogen 97-105 L1 cell adhesion molecule Homo sapiens 163-166 31787315-1 2020 In East and Southeast Asia, the health of over 100 million people is threatened by the consumption of groundwater containing high concentrations of arsenic (>10 mug L-1), which is released from sediments through reductive dissolution of arsenic-bearing iron/manganese oxides. Arsenic 148-155 L1 cell adhesion molecule Homo sapiens 165-168 31787315-1 2020 In East and Southeast Asia, the health of over 100 million people is threatened by the consumption of groundwater containing high concentrations of arsenic (>10 mug L-1), which is released from sediments through reductive dissolution of arsenic-bearing iron/manganese oxides. Iron 253-257 L1 cell adhesion molecule Homo sapiens 165-168 31923783-8 2020 For carbaryl, the RMSEC were 5.24 x 10-7 g L-1 and 6.18 x 10-7, the RMSEP were 9.20 x 10-7 g L-1 and 9.63 x 10-7 g L-1 for 2D correlation spectra and EEM spectra, respectively. Carbaryl 4-12 L1 cell adhesion molecule Homo sapiens 43-52 32608686-2 2020 The finding indicated that in an intermittent operation mode, the average concentration of total nitrogen and ammonia nitrogen in the effluent could reach 1.05 mg L-1 and 0.54 mg L-1, and the average removal rate was 94.77% and 93.30%, respectively. Nitrogen 97-105 L1 cell adhesion molecule Homo sapiens 179-182 32608686-2 2020 The finding indicated that in an intermittent operation mode, the average concentration of total nitrogen and ammonia nitrogen in the effluent could reach 1.05 mg L-1 and 0.54 mg L-1, and the average removal rate was 94.77% and 93.30%, respectively. Ammonia 110-117 L1 cell adhesion molecule Homo sapiens 163-166 32608686-2 2020 The finding indicated that in an intermittent operation mode, the average concentration of total nitrogen and ammonia nitrogen in the effluent could reach 1.05 mg L-1 and 0.54 mg L-1, and the average removal rate was 94.77% and 93.30%, respectively. Ammonia 110-117 L1 cell adhesion molecule Homo sapiens 179-182 32608686-2 2020 The finding indicated that in an intermittent operation mode, the average concentration of total nitrogen and ammonia nitrogen in the effluent could reach 1.05 mg L-1 and 0.54 mg L-1, and the average removal rate was 94.77% and 93.30%, respectively. Nitrogen 118-126 L1 cell adhesion molecule Homo sapiens 163-166 32608686-2 2020 The finding indicated that in an intermittent operation mode, the average concentration of total nitrogen and ammonia nitrogen in the effluent could reach 1.05 mg L-1 and 0.54 mg L-1, and the average removal rate was 94.77% and 93.30%, respectively. Nitrogen 118-126 L1 cell adhesion molecule Homo sapiens 179-182 32164266-3 2020 The optimal parameters, such as pH value at 10, photocatalyst dosage of 0.4 g L-1, and 10 mol% Cu-doped BiVO4/g-C3N4 photocatalyst, were determined to degrade initial concentration of 20 ppm Bisphenol A, which could be completely removed after 90 min. bismuth vanadium tetraoxide 104-109 L1 cell adhesion molecule Homo sapiens 78-81 32164266-3 2020 The optimal parameters, such as pH value at 10, photocatalyst dosage of 0.4 g L-1, and 10 mol% Cu-doped BiVO4/g-C3N4 photocatalyst, were determined to degrade initial concentration of 20 ppm Bisphenol A, which could be completely removed after 90 min. c3n4 112-116 L1 cell adhesion molecule Homo sapiens 78-81 32608636-2 2020 The results showed that the concentration (dry weight) of OCPs in Lake Gucheng ranged from 26.74 to 48.12 ng L-1 in surface water, 9.01 to 35.34 ng g-1 in sediment, and 13.39 to 124.29 ng g-1 in organisms. ocps 58-62 L1 cell adhesion molecule Homo sapiens 109-112 32608638-6 2020 The concentration range of 8 different detectable organophosphate esters in the effluent of sewage treatment plant is 85.9-235.4 ng L-1 during the six-day sampling process, permissive river downstream of the six-day SigmaOPEs average total concentration was 130.3 ng L-1, higher than the 119.4 ng L-1 upstream water concentration, but lower than the sewage treatment plant effluent concentration of total 162.5ng L-1. organophosphate esters 50-72 L1 cell adhesion molecule Homo sapiens 132-135 32608638-6 2020 The concentration range of 8 different detectable organophosphate esters in the effluent of sewage treatment plant is 85.9-235.4 ng L-1 during the six-day sampling process, permissive river downstream of the six-day SigmaOPEs average total concentration was 130.3 ng L-1, higher than the 119.4 ng L-1 upstream water concentration, but lower than the sewage treatment plant effluent concentration of total 162.5ng L-1. organophosphate esters 50-72 L1 cell adhesion molecule Homo sapiens 267-270 32608638-6 2020 The concentration range of 8 different detectable organophosphate esters in the effluent of sewage treatment plant is 85.9-235.4 ng L-1 during the six-day sampling process, permissive river downstream of the six-day SigmaOPEs average total concentration was 130.3 ng L-1, higher than the 119.4 ng L-1 upstream water concentration, but lower than the sewage treatment plant effluent concentration of total 162.5ng L-1. organophosphate esters 50-72 L1 cell adhesion molecule Homo sapiens 267-270 32608638-6 2020 The concentration range of 8 different detectable organophosphate esters in the effluent of sewage treatment plant is 85.9-235.4 ng L-1 during the six-day sampling process, permissive river downstream of the six-day SigmaOPEs average total concentration was 130.3 ng L-1, higher than the 119.4 ng L-1 upstream water concentration, but lower than the sewage treatment plant effluent concentration of total 162.5ng L-1. organophosphate esters 50-72 L1 cell adhesion molecule Homo sapiens 267-270 32124056-10 2020 However, maximum DCF levels in residential wastewater and hospital wastewater were detected to be 105 mug L-1 and 34 mug L-1, respectively. Diclofenac 17-20 L1 cell adhesion molecule Homo sapiens 106-116 32048832-6 2020 The rigid ligands (L1 and L2) exhibit higher selective abilities for the Am(III)/Eu(III) separation compared with that of the flexible ligand (L3). Europium 81-88 L1 cell adhesion molecule Homo sapiens 19-28 32008081-6 2020 The linear dynamic ranges obtained for Ni(II) and Co(II) were 1.0-30 and 0.50-20 mug L-1, respectively. Nickel 39-45 L1 cell adhesion molecule Homo sapiens 85-88 31896184-4 2020 The optimal conditions were achieved at the catalyst loading of 0.05 g L-1, PMS dosage of 1.26 g L-1, and pH of 7.7 through the response surface methodology by using the Box-Behnken design model. peroxymonosulfate 76-79 L1 cell adhesion molecule Homo sapiens 97-100 31896184-7 2020 Moreover, Co3Fe7-CoFe2O4 showed efficient catalytic performance in continuous five runs and exhibited less metal leaching of 0.052 and 0.036 mg L-1 for Co and Fe species, respectively. Iron 10-24 L1 cell adhesion molecule Homo sapiens 144-147 31896184-7 2020 Moreover, Co3Fe7-CoFe2O4 showed efficient catalytic performance in continuous five runs and exhibited less metal leaching of 0.052 and 0.036 mg L-1 for Co and Fe species, respectively. Iron 13-15 L1 cell adhesion molecule Homo sapiens 144-147 31892094-10 2020 The content of arsenic in five kinds of natural water samples ranged from 34 ng L-1 to 2.3 mug L-1. Arsenic 15-22 L1 cell adhesion molecule Homo sapiens 80-90 32541116-5 2020 The maximum adsorption capacities of rhodamine B and methylene blue onto MBMM prepared at calcination temperature 500 C were 57.79 mg g-1 and 55.94 mg g-1 under the conditions of initial concentration 300 mg L-1, dosage 0.1 g, pH 7.0, adsorption temperature 55 C, and adsorption time 7 h. The results showed that the calcining treatment was beneficial to the formation of mesoporous microspheres, improving their adsorption capacities. rhodamine B 37-48 L1 cell adhesion molecule Homo sapiens 209-212 32541116-5 2020 The maximum adsorption capacities of rhodamine B and methylene blue onto MBMM prepared at calcination temperature 500 C were 57.79 mg g-1 and 55.94 mg g-1 under the conditions of initial concentration 300 mg L-1, dosage 0.1 g, pH 7.0, adsorption temperature 55 C, and adsorption time 7 h. The results showed that the calcining treatment was beneficial to the formation of mesoporous microspheres, improving their adsorption capacities. Methylene Blue 53-67 L1 cell adhesion molecule Homo sapiens 209-212 32003378-5 2020 In wastewater effluents, average concentrations of all target and suspect QACs combined ranged from 0.4 mug L-1 to 6.6 mug L-1. Quaternary Ammonium Compounds 74-78 L1 cell adhesion molecule Homo sapiens 108-118 31679890-4 2020 The removal efficiency of methylene blue (MB, 50 mg L-1) achieves ~100% within 2 min. Methylene Chloride 26-35 L1 cell adhesion molecule Homo sapiens 52-55 32139999-6 2020 Results: Significantly more patients with Scheuermann"s disease had at least one MC compared to the controls at the level L1/L2 (Odds Ratio [OR] 21.11, 95% Confidence Interval [95% CI] 2.31-192.96), at the level L3/L4 (OR 13.62, 95% CI 1.41-131.26), and at the level L5/S1 (OR 6.11, 95% CI 1.50-24.83). Methylcholanthrene 81-83 L1 cell adhesion molecule Homo sapiens 122-127 31834667-5 2020 A 1,2 bis(o-aminophenoxy)ethane-N,N,-N",N"-tetraacetic-acid-based probe allows Ca2+ ion sensing with 0.02-0.05 mmol L-1 sensitivity within 0.50-1.25 mmol L-1 detection range. 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid 2-59 L1 cell adhesion molecule Homo sapiens 154-157 31834667-5 2020 A 1,2 bis(o-aminophenoxy)ethane-N,N,-N",N"-tetraacetic-acid-based probe allows Ca2+ ion sensing with 0.02-0.05 mmol L-1 sensitivity within 0.50-1.25 mmol L-1 detection range. Calcium 79-83 L1 cell adhesion molecule Homo sapiens 116-119 31834667-5 2020 A 1,2 bis(o-aminophenoxy)ethane-N,N,-N",N"-tetraacetic-acid-based probe allows Ca2+ ion sensing with 0.02-0.05 mmol L-1 sensitivity within 0.50-1.25 mmol L-1 detection range. Calcium 79-83 L1 cell adhesion molecule Homo sapiens 154-157 31834667-6 2020 5-Oxazolecarboxylic acid senses Mg2+ ions, exhibiting a sensitivity of 0.10-0.44 mmol L-1 within the range of 0.5-0.8 mmol L-1 . Fura-2 0-24 L1 cell adhesion molecule Homo sapiens 86-89 31834667-6 2020 5-Oxazolecarboxylic acid senses Mg2+ ions, exhibiting a sensitivity of 0.10-0.44 mmol L-1 within the range of 0.5-0.8 mmol L-1 . Fura-2 0-24 L1 cell adhesion molecule Homo sapiens 123-126 31834667-6 2020 5-Oxazolecarboxylic acid senses Mg2+ ions, exhibiting a sensitivity of 0.10-0.44 mmol L-1 within the range of 0.5-0.8 mmol L-1 . Magnesium 32-36 L1 cell adhesion molecule Homo sapiens 86-89 31834667-6 2020 5-Oxazolecarboxylic acid senses Mg2+ ions, exhibiting a sensitivity of 0.10-0.44 mmol L-1 within the range of 0.5-0.8 mmol L-1 . Magnesium 32-36 L1 cell adhesion molecule Homo sapiens 123-126 31834667-7 2020 The N-(2-methoxyphenyl)iminodiacetate Zn2+ ion sensor has a sensitivity of 1 micromol L-1 within the range of 10-20 micromol L-1 . cobalt iminodiacetate 4-37 L1 cell adhesion molecule Homo sapiens 86-89 31834667-7 2020 The N-(2-methoxyphenyl)iminodiacetate Zn2+ ion sensor has a sensitivity of 1 micromol L-1 within the range of 10-20 micromol L-1 . cobalt iminodiacetate 4-37 L1 cell adhesion molecule Homo sapiens 125-128 31834667-7 2020 The N-(2-methoxyphenyl)iminodiacetate Zn2+ ion sensor has a sensitivity of 1 micromol L-1 within the range of 10-20 micromol L-1 . Zinc 38-41 L1 cell adhesion molecule Homo sapiens 86-89 31834667-7 2020 The N-(2-methoxyphenyl)iminodiacetate Zn2+ ion sensor has a sensitivity of 1 micromol L-1 within the range of 10-20 micromol L-1 . Zinc 38-41 L1 cell adhesion molecule Homo sapiens 125-128 31925490-8 2020 The lowest limits of detection (LOD) achieved were 13.16 and 13.86 ng L-1, and the limits of quantification (LOQ) were 43.89 and 46.19 ng L-1 for simazine and atrazine, respectively, with repeatability (expressed as %RSD) below 5% in all cases. Simazine 146-154 L1 cell adhesion molecule Homo sapiens 138-141 31806513-2 2020 RCPH-biochar at concentration of 15 g L-1 substantially enhanced hydrogen generation during batch tests, with the highest cumulative hydrogen volume (3990 mL L-1) being 1.7 times that without RCPH-biochar. Hydrogen 65-73 L1 cell adhesion molecule Homo sapiens 38-41 31806513-2 2020 RCPH-biochar at concentration of 15 g L-1 substantially enhanced hydrogen generation during batch tests, with the highest cumulative hydrogen volume (3990 mL L-1) being 1.7 times that without RCPH-biochar. Hydrogen 133-141 L1 cell adhesion molecule Homo sapiens 158-161 31806513-3 2020 Then, continuous hydrogen production performance demonstrated that RCPH-biochar was capable of retaining biomass in the reactor, at 6 h hydraulic retention time, hydrogen production rate (22.8 mmol H2 L-1 h-1) was tripled compared to the control, meanwhile, glucose and xylose utilization reached to 82.3% and 54.6%, respectively. Hydrogen 162-170 L1 cell adhesion molecule Homo sapiens 201-204 31441374-3 2020 NDEs were enriched by sequential precipitation and anti-L1CAM antibody immunoabsorption, and extracted protein biomarkers were quantified by enzyme-linked immunosorbent assays. ndes 0-4 L1 cell adhesion molecule Homo sapiens 56-61 31854935-3 2020 The results showed that after the operation of intermittent starvation, the NO3--N concentration at the end of the aerobic phase decreased to 8.72 mg L-1 and the NO2- accumulation percentage reached 83.18%, which indicated that the nitrite oxidizing bacteria (NOB) activity was effectively inhibited and that the nitritation performance improved. Nitrites 232-239 L1 cell adhesion molecule Homo sapiens 150-153 31854935-4 2020 After the operation of the intermittent starvation, the ratio of NO2- to NH4+-N at the end of the aerobic phase was adjusted to provide more suitable substrates for the subsequent ANAMMOX process, such that the concentration of NH4+-N in the effluent fell below 1.0 mg L-1. ammonium dinitramide 228-234 L1 cell adhesion molecule Homo sapiens 269-272 31854936-4 2020 After adding 700 mg L-1 glucose to the influent, due to the synergistic effect of denitrification and anammoxidation, the combined process achieved its best nitrogen removal performance at a reflux ratio of 2.0 and hydraulic retention time (HRT) of 2.2 days. Glucose 24-31 L1 cell adhesion molecule Homo sapiens 20-23 31854936-4 2020 After adding 700 mg L-1 glucose to the influent, due to the synergistic effect of denitrification and anammoxidation, the combined process achieved its best nitrogen removal performance at a reflux ratio of 2.0 and hydraulic retention time (HRT) of 2.2 days. Nitrogen 157-165 L1 cell adhesion molecule Homo sapiens 20-23 31828374-4 2020 The maximum adsorption rates onto chitosan films at initial concentrations of 0.5 and 1.0 mg L-1 for Cu2+ and Cd2+ were 97%, 98% and 60%, 62%, respectively. Copper 101-105 L1 cell adhesion molecule Homo sapiens 93-96 31828374-4 2020 The maximum adsorption rates onto chitosan films at initial concentrations of 0.5 and 1.0 mg L-1 for Cu2+ and Cd2+ were 97%, 98% and 60%, 62%, respectively. 2'-chloro-2'-deoxyadenosine 110-113 L1 cell adhesion molecule Homo sapiens 93-96 31669871-3 2020 A maximum caproate production rate of 2.41 +- 0.69 g L-1 d-1, and a final concentration of 7.66 +- 1.38 g L-1 was achieved. Caproates 10-18 L1 cell adhesion molecule Homo sapiens 53-56 31669871-3 2020 A maximum caproate production rate of 2.41 +- 0.69 g L-1 d-1, and a final concentration of 7.66 +- 1.38 g L-1 was achieved. Caproates 10-18 L1 cell adhesion molecule Homo sapiens 106-109 29860695-4 2020 The performance of the catalysts was tested in the CWPO of sulfamethoxazole (SMX) (5 mg L-1) under ambient conditions and circumneutral pH (pH0 = 5), using the stoichiometric dose of H2O2 (25 mg L-1) and a catalyst load of 1 g L-1. Sulfamethoxazole 59-75 L1 cell adhesion molecule Homo sapiens 88-91 29860695-4 2020 The performance of the catalysts was tested in the CWPO of sulfamethoxazole (SMX) (5 mg L-1) under ambient conditions and circumneutral pH (pH0 = 5), using the stoichiometric dose of H2O2 (25 mg L-1) and a catalyst load of 1 g L-1. Sulfamethoxazole 77-80 L1 cell adhesion molecule Homo sapiens 88-91 31703977-6 2020 The results showed that the concentrations of Cl2 and ClO2 required to achieve a log reduction value of 2 for the live bacterial cells with 180 min of contact time were 1.5 and 0.6 mg L-1, respectively. Chlorine 54-58 L1 cell adhesion molecule Homo sapiens 184-187 31740318-4 2020 Under the optimal conditions, good linear relationship was obtained in the range of 0.05-200 mug L-1 for Cd2+ and 0.1-200 mug L-1 for Hg2+, and the limits of detection were 0.016 and 0.040 mug L-1, respectively. Mercury 134-138 L1 cell adhesion molecule Homo sapiens 126-129 31740318-4 2020 Under the optimal conditions, good linear relationship was obtained in the range of 0.05-200 mug L-1 for Cd2+ and 0.1-200 mug L-1 for Hg2+, and the limits of detection were 0.016 and 0.040 mug L-1, respectively. Mercury 134-138 L1 cell adhesion molecule Homo sapiens 126-129 31769027-8 2020 The best results were obtained with 4 g L-1 and 8 g L-1 of silicon and 15 g L-1 of calcium. Silicon 59-66 L1 cell adhesion molecule Homo sapiens 40-55 31769027-11 2020 CONCLUSIONS: The application of 4 g L-1 and 8 of silicon and 15 g L-1 of calcium to the grapes represents a potential alternative fertilizing strategy, which could increase the plant yield without damaging the phytochemical characteristics of the fruit and its derivatives. Silicon 49-56 L1 cell adhesion molecule Homo sapiens 36-45 31818745-5 2020 MXene exhibited outstanding adsorption of Ba2+ and Sr2+, to approximately 180 and 225 mg g-1, respectively, when 1 g L-1 MXene was admixed with adsorbates at 2 g L-1. mxene 0-5 L1 cell adhesion molecule Homo sapiens 117-120 31818745-5 2020 MXene exhibited outstanding adsorption of Ba2+ and Sr2+, to approximately 180 and 225 mg g-1, respectively, when 1 g L-1 MXene was admixed with adsorbates at 2 g L-1. mxene 0-5 L1 cell adhesion molecule Homo sapiens 162-165 31818745-5 2020 MXene exhibited outstanding adsorption of Ba2+ and Sr2+, to approximately 180 and 225 mg g-1, respectively, when 1 g L-1 MXene was admixed with adsorbates at 2 g L-1. mxene 121-126 L1 cell adhesion molecule Homo sapiens 117-120 31834667-4 2020 Crown ether derivatives exhibit selectivity to Na+ and K+ ions within detection ranges of 0-100 and 0-50 mmol L-1 , and selectivities of 15.6 and 8.1 mmol L-1 , respectively. Ethers 6-11 L1 cell adhesion molecule Homo sapiens 110-113 31834667-4 2020 Crown ether derivatives exhibit selectivity to Na+ and K+ ions within detection ranges of 0-100 and 0-50 mmol L-1 , and selectivities of 15.6 and 8.1 mmol L-1 , respectively. Ethers 6-11 L1 cell adhesion molecule Homo sapiens 155-158 31834667-5 2020 A 1,2 bis(o-aminophenoxy)ethane-N,N,-N",N"-tetraacetic-acid-based probe allows Ca2+ ion sensing with 0.02-0.05 mmol L-1 sensitivity within 0.50-1.25 mmol L-1 detection range. 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid 2-59 L1 cell adhesion molecule Homo sapiens 116-119 31740246-6 2020 At the optimal SiC nanoparticles concentration of 150 mg L-1 and photoperiod of 6:18 h, the maximum biomass concentration and total lipid content reached 3.18 g L-1 and 40.26%, respectively. Silicon 15-18 L1 cell adhesion molecule Homo sapiens 57-60 31740246-6 2020 At the optimal SiC nanoparticles concentration of 150 mg L-1 and photoperiod of 6:18 h, the maximum biomass concentration and total lipid content reached 3.18 g L-1 and 40.26%, respectively. Silicon 15-18 L1 cell adhesion molecule Homo sapiens 161-164 31806513-2 2020 RCPH-biochar at concentration of 15 g L-1 substantially enhanced hydrogen generation during batch tests, with the highest cumulative hydrogen volume (3990 mL L-1) being 1.7 times that without RCPH-biochar. Hydrogen 133-141 L1 cell adhesion molecule Homo sapiens 38-41 31726594-2 2020 Two parallel sequencing batch reactors were operated to treat the aniline-rich wastewater with and without 20 mg L-1 of Mn2+. Manganese 120-124 L1 cell adhesion molecule Homo sapiens 113-116 31623844-9 2020 Good linearity (r > 0.994) was obtained in the ranges of 0.6-200 mug L-1 for eight alkylphenols and 1.8-600 mug L-1 for nonylphenol. alkylphenols 83-95 L1 cell adhesion molecule Homo sapiens 69-72 31623844-9 2020 Good linearity (r > 0.994) was obtained in the ranges of 0.6-200 mug L-1 for eight alkylphenols and 1.8-600 mug L-1 for nonylphenol. nonylphenol 120-131 L1 cell adhesion molecule Homo sapiens 112-115 31984281-4 2020 On the basis of extended conjugation and planarity, L 1 complexes exhibited superior bioactivity with greater calculated DNA binding constant values, (K b) 2.9444 x 103 [(L 1 ) 2 Cu] and 2.2693 x 103 [(L 1 ) 2 Zn], as compared to L 2 complexes, 1.793 x 103 [(L 2 )Cu(H 2 O)] and 9.801 x 102 [(L 2 )Zn(H 2 O)]. Copper 179-181 L1 cell adhesion molecule Homo sapiens 52-55 31984281-4 2020 On the basis of extended conjugation and planarity, L 1 complexes exhibited superior bioactivity with greater calculated DNA binding constant values, (K b) 2.9444 x 103 [(L 1 ) 2 Cu] and 2.2693 x 103 [(L 1 ) 2 Zn], as compared to L 2 complexes, 1.793 x 103 [(L 2 )Cu(H 2 O)] and 9.801 x 102 [(L 2 )Zn(H 2 O)]. Zinc 210-212 L1 cell adhesion molecule Homo sapiens 52-55 31984281-4 2020 On the basis of extended conjugation and planarity, L 1 complexes exhibited superior bioactivity with greater calculated DNA binding constant values, (K b) 2.9444 x 103 [(L 1 ) 2 Cu] and 2.2693 x 103 [(L 1 ) 2 Zn], as compared to L 2 complexes, 1.793 x 103 [(L 2 )Cu(H 2 O)] and 9.801 x 102 [(L 2 )Zn(H 2 O)]. Copper 264-266 L1 cell adhesion molecule Homo sapiens 52-55 31984281-4 2020 On the basis of extended conjugation and planarity, L 1 complexes exhibited superior bioactivity with greater calculated DNA binding constant values, (K b) 2.9444 x 103 [(L 1 ) 2 Cu] and 2.2693 x 103 [(L 1 ) 2 Zn], as compared to L 2 complexes, 1.793 x 103 [(L 2 )Cu(H 2 O)] and 9.801 x 102 [(L 2 )Zn(H 2 O)]. Water 267-272 L1 cell adhesion molecule Homo sapiens 52-55 31984281-4 2020 On the basis of extended conjugation and planarity, L 1 complexes exhibited superior bioactivity with greater calculated DNA binding constant values, (K b) 2.9444 x 103 [(L 1 ) 2 Cu] and 2.2693 x 103 [(L 1 ) 2 Zn], as compared to L 2 complexes, 1.793 x 103 [(L 2 )Cu(H 2 O)] and 9.801 x 102 [(L 2 )Zn(H 2 O)]. Zinc 298-300 L1 cell adhesion molecule Homo sapiens 52-55 31984281-4 2020 On the basis of extended conjugation and planarity, L 1 complexes exhibited superior bioactivity with greater calculated DNA binding constant values, (K b) 2.9444 x 103 [(L 1 ) 2 Cu] and 2.2693 x 103 [(L 1 ) 2 Zn], as compared to L 2 complexes, 1.793 x 103 [(L 2 )Cu(H 2 O)] and 9.801 x 102 [(L 2 )Zn(H 2 O)]. Water 301-306 L1 cell adhesion molecule Homo sapiens 52-55 31984281-6 2020 The minor groove binding of the [(L 1 ) 2 Cu] complex is further confirmed by the molecular docking study. Copper 42-44 L1 cell adhesion molecule Homo sapiens 34-37 31984281-8 2020 The [(L 1 ) 2 Cu] complex was found to have pronounced cleavage efficiency as evaluated from sodium dodecyl sulfate polyacrylamide gel electrophoresis electrophoresis. Copper 14-16 L1 cell adhesion molecule Homo sapiens 6-9 31984281-8 2020 The [(L 1 ) 2 Cu] complex was found to have pronounced cleavage efficiency as evaluated from sodium dodecyl sulfate polyacrylamide gel electrophoresis electrophoresis. Sodium Dodecyl Sulfate 93-130 L1 cell adhesion molecule Homo sapiens 6-9 31499309-5 2020 Complete degradation of phenol (of initial concentration 50 mg L-1) was achieved under the near-optimum operating conditions (40 mA cm-2, pH 7, 0.4 m3 h-1 water circulation rate) within 30 min. Phenol 24-30 L1 cell adhesion molecule Homo sapiens 63-66 31499309-5 2020 Complete degradation of phenol (of initial concentration 50 mg L-1) was achieved under the near-optimum operating conditions (40 mA cm-2, pH 7, 0.4 m3 h-1 water circulation rate) within 30 min. Water 155-160 L1 cell adhesion molecule Homo sapiens 63-66 32811281-7 2020 Minimum half-life of cyantraniliprole, i.e. 8.7 days was recorded at elevated CO2 level (625 +- 5 microL L-1) while its maximum half-life of 86.6 days was recorded at 5 C. Metabolite IN-J9Z38 started forming from zero-day and reached the maximum on 15th to 60th day. cyantraniliprole 21-37 L1 cell adhesion molecule Homo sapiens 105-108 31679890-5 2020 with low dosage of FeOCl/MoS2 (0.2 g L-1) and H2O2 (0.6 mM). 2-octulosonic acid 19-24 L1 cell adhesion molecule Homo sapiens 37-40 31679890-5 2020 with low dosage of FeOCl/MoS2 (0.2 g L-1) and H2O2 (0.6 mM). molybdenum disulfide 25-29 L1 cell adhesion molecule Homo sapiens 37-40 31799844-1 2019 The synthesis of the asymmetric ligand 3-phenyl-1-(pyridin-2-yl)-1H-pyrazol-5-amine (L1) and its single-crystal X-ray structure are reported. 2-phenyl-4-(3-pyridin-2-yl-1H-pyrazol-4-yl)pyridine 39-83 L1 cell adhesion molecule Homo sapiens 85-87 31906219-4 2019 The experimental results indicated that the maximum adsorption capacity (qmax) of Fe@BC for DCF obtained from Langmuir isotherm simulation was 123.45 mg L-1 and it was a remarkable value of DCF adsorption in comparison with that of other biomass-based adsorbents previously reported. Iron 82-84 L1 cell adhesion molecule Homo sapiens 153-156 31906219-4 2019 The experimental results indicated that the maximum adsorption capacity (qmax) of Fe@BC for DCF obtained from Langmuir isotherm simulation was 123.45 mg L-1 and it was a remarkable value of DCF adsorption in comparison with that of other biomass-based adsorbents previously reported. Diclofenac 92-95 L1 cell adhesion molecule Homo sapiens 153-156 31906219-4 2019 The experimental results indicated that the maximum adsorption capacity (qmax) of Fe@BC for DCF obtained from Langmuir isotherm simulation was 123.45 mg L-1 and it was a remarkable value of DCF adsorption in comparison with that of other biomass-based adsorbents previously reported. Diclofenac 190-193 L1 cell adhesion molecule Homo sapiens 153-156 32380616-4 2019 The results indicated that the removal efficiency of Co ions had positive correlation with applied voltage (R2 = 0.9991), which increased from 15.11% to 36.54% when the applied voltage increased from 0 V to 1.2 V. However, the removal efficiency of Co ions decreased gradually from 36.54% to 9.51% with the increasing initial Co ions concentration from 5 to 30 mg L-1. Cobalt 53-55 L1 cell adhesion molecule Homo sapiens 364-367 32380616-4 2019 The results indicated that the removal efficiency of Co ions had positive correlation with applied voltage (R2 = 0.9991), which increased from 15.11% to 36.54% when the applied voltage increased from 0 V to 1.2 V. However, the removal efficiency of Co ions decreased gradually from 36.54% to 9.51% with the increasing initial Co ions concentration from 5 to 30 mg L-1. Cobalt 249-251 L1 cell adhesion molecule Homo sapiens 364-367 32380616-4 2019 The results indicated that the removal efficiency of Co ions had positive correlation with applied voltage (R2 = 0.9991), which increased from 15.11% to 36.54% when the applied voltage increased from 0 V to 1.2 V. However, the removal efficiency of Co ions decreased gradually from 36.54% to 9.51% with the increasing initial Co ions concentration from 5 to 30 mg L-1. Cobalt 249-251 L1 cell adhesion molecule Homo sapiens 364-367 31799844-2 2019 L1 displays crystallographic symmetry (orthorhombic, Pccn) higher than its molecular symmetry (point group C1) and also displays supercooling, with a difference in the melting and solidification points of over 100 C. Upon complexation with ZnCl2, L1 engages in both primary cation and secondary anion coordination via hydrogen bonding, and the complex exhibits a room-to-low-temperature single crystal-to-crystal phase transition. Zinc 241-246 L1 cell adhesion molecule Homo sapiens 0-2 31799844-2 2019 L1 displays crystallographic symmetry (orthorhombic, Pccn) higher than its molecular symmetry (point group C1) and also displays supercooling, with a difference in the melting and solidification points of over 100 C. Upon complexation with ZnCl2, L1 engages in both primary cation and secondary anion coordination via hydrogen bonding, and the complex exhibits a room-to-low-temperature single crystal-to-crystal phase transition. Hydrogen 319-327 L1 cell adhesion molecule Homo sapiens 0-2 31847169-5 2019 Preliminary results in a laboratory environment showed sensitivity for small added amounts of CO2 (0.25 mg L-1). Carbon Dioxide 94-97 L1 cell adhesion molecule Homo sapiens 107-110 31854601-4 2019 In the finish water of CX Waterworks and tap water supplied by CX Water works, concentrations of THMs ranged from 7.70 to 32.73mug L-1and 9.00 to 51.42mug L-1, respectively, and those of HAAs 3.05 to 21.30mug L-1 and 6.00 to 26.79mug L-1, respectively. Trihalomethanes 97-101 L1 cell adhesion molecule Homo sapiens 131-134 31854601-4 2019 In the finish water of CX Waterworks and tap water supplied by CX Water works, concentrations of THMs ranged from 7.70 to 32.73mug L-1and 9.00 to 51.42mug L-1, respectively, and those of HAAs 3.05 to 21.30mug L-1 and 6.00 to 26.79mug L-1, respectively. Trihalomethanes 97-101 L1 cell adhesion molecule Homo sapiens 155-158 31854601-4 2019 In the finish water of CX Waterworks and tap water supplied by CX Water works, concentrations of THMs ranged from 7.70 to 32.73mug L-1and 9.00 to 51.42mug L-1, respectively, and those of HAAs 3.05 to 21.30mug L-1 and 6.00 to 26.79mug L-1, respectively. Trihalomethanes 97-101 L1 cell adhesion molecule Homo sapiens 155-158 31854601-5 2019 The THMs in finished water and tap water of TH Waterworks were in the range 8.65-38.76mug L-1 and 12.09-42.04mug L-1, respectively, and those of HAAs were 2.42-14.79mug L-1 and 2.80-33.40mug L-1, respectively. Trihalomethanes 4-8 L1 cell adhesion molecule Homo sapiens 90-93 31854601-5 2019 The THMs in finished water and tap water of TH Waterworks were in the range 8.65-38.76mug L-1 and 12.09-42.04mug L-1, respectively, and those of HAAs were 2.42-14.79mug L-1 and 2.80-33.40mug L-1, respectively. Trihalomethanes 4-8 L1 cell adhesion molecule Homo sapiens 113-116 31854601-5 2019 The THMs in finished water and tap water of TH Waterworks were in the range 8.65-38.76mug L-1 and 12.09-42.04mug L-1, respectively, and those of HAAs were 2.42-14.79mug L-1 and 2.80-33.40mug L-1, respectively. Trihalomethanes 4-8 L1 cell adhesion molecule Homo sapiens 113-116 31854604-4 2019 The average concentration of total nitrogen (TN) and total phosphorus (TP) reached 10.05 mg L-1 and 1.10 mg L-1, far exceeding the occurrence standard of eutrophication, which should be cause for concern. Nitrogen 35-43 L1 cell adhesion molecule Homo sapiens 92-101 31854604-4 2019 The average concentration of total nitrogen (TN) and total phosphorus (TP) reached 10.05 mg L-1 and 1.10 mg L-1, far exceeding the occurrence standard of eutrophication, which should be cause for concern. Phosphorus 59-69 L1 cell adhesion molecule Homo sapiens 92-101 31299615-1 2019 Here in we report tris (3-aminopropyl) amine based tripodal receptors L, L1 and L2 which were functionalized with 4-nitrophenyl moieties having thio-urea, amide and sulfonamide as hydrogen bonding moieties respectively, shows a strong selectivity towards cyanide. tris (3-aminopropyl) amine 18-44 L1 cell adhesion molecule Homo sapiens 73-82 31299615-1 2019 Here in we report tris (3-aminopropyl) amine based tripodal receptors L, L1 and L2 which were functionalized with 4-nitrophenyl moieties having thio-urea, amide and sulfonamide as hydrogen bonding moieties respectively, shows a strong selectivity towards cyanide. Thiourea 144-153 L1 cell adhesion molecule Homo sapiens 73-82 31299615-1 2019 Here in we report tris (3-aminopropyl) amine based tripodal receptors L, L1 and L2 which were functionalized with 4-nitrophenyl moieties having thio-urea, amide and sulfonamide as hydrogen bonding moieties respectively, shows a strong selectivity towards cyanide. Amides 155-160 L1 cell adhesion molecule Homo sapiens 73-82 31299615-1 2019 Here in we report tris (3-aminopropyl) amine based tripodal receptors L, L1 and L2 which were functionalized with 4-nitrophenyl moieties having thio-urea, amide and sulfonamide as hydrogen bonding moieties respectively, shows a strong selectivity towards cyanide. Sulfonamides 165-176 L1 cell adhesion molecule Homo sapiens 73-82 31299615-1 2019 Here in we report tris (3-aminopropyl) amine based tripodal receptors L, L1 and L2 which were functionalized with 4-nitrophenyl moieties having thio-urea, amide and sulfonamide as hydrogen bonding moieties respectively, shows a strong selectivity towards cyanide. Hydrogen 180-188 L1 cell adhesion molecule Homo sapiens 73-82 31299615-1 2019 Here in we report tris (3-aminopropyl) amine based tripodal receptors L, L1 and L2 which were functionalized with 4-nitrophenyl moieties having thio-urea, amide and sulfonamide as hydrogen bonding moieties respectively, shows a strong selectivity towards cyanide. Cyanides 255-262 L1 cell adhesion molecule Homo sapiens 73-82 31299615-3 2019 To the best of our knowledge, this is the first example of a naked-eye detection of cyanide via fluoride displacement assay by a tripodal receptor and such a displacement phenomenon is not observes in the cases of L1 and L2, instead the receptor L1 binds nitrate and cyanide; L2 binds dihydrogen phosphate and cyanide. Cyanides 84-91 L1 cell adhesion molecule Homo sapiens 214-223 31768591-2 2019 The pencil graphite electrode"s surface was directly modified from graphite to graphene with cyclic voltammetry method in a single step by performing potential cycling between - 0.9 and - 1.4 V in 0.2 mol L-1 NaOH modifying solution. Graphite 11-19 L1 cell adhesion molecule Homo sapiens 205-208 31768591-2 2019 The pencil graphite electrode"s surface was directly modified from graphite to graphene with cyclic voltammetry method in a single step by performing potential cycling between - 0.9 and - 1.4 V in 0.2 mol L-1 NaOH modifying solution. Graphite 79-87 L1 cell adhesion molecule Homo sapiens 205-208 31768591-2 2019 The pencil graphite electrode"s surface was directly modified from graphite to graphene with cyclic voltammetry method in a single step by performing potential cycling between - 0.9 and - 1.4 V in 0.2 mol L-1 NaOH modifying solution. Sodium 209-213 L1 cell adhesion molecule Homo sapiens 205-208 31768591-3 2019 A linear relationship between peak current and concentration was obtained in the range between 5-100 mug L-1 for both Cd2+ and Pb2+, with detection limits of 0.12 mug L-1 for Cd2+ and 0.29 mug L-1 for Pb2+. Lead 127-131 L1 cell adhesion molecule Homo sapiens 105-108 31768591-3 2019 A linear relationship between peak current and concentration was obtained in the range between 5-100 mug L-1 for both Cd2+ and Pb2+, with detection limits of 0.12 mug L-1 for Cd2+ and 0.29 mug L-1 for Pb2+. Lead 127-131 L1 cell adhesion molecule Homo sapiens 167-170 31768591-3 2019 A linear relationship between peak current and concentration was obtained in the range between 5-100 mug L-1 for both Cd2+ and Pb2+, with detection limits of 0.12 mug L-1 for Cd2+ and 0.29 mug L-1 for Pb2+. Lead 127-131 L1 cell adhesion molecule Homo sapiens 167-170 31478191-10 2019 Production using the lacZDeltam15 mutant yielded 3-FL concentration of 4.6 g/L with the productivity of 0.076 g L-1 hr-1 and the specific 3-FL yield of 0.5 g/g dry cell weight. 3'-fucosyllactose 49-53 L1 cell adhesion molecule Homo sapiens 112-121 31546080-4 2019 Additionally, phenol (50 mg L-1) could be largely removed by NPC modified cathode, the mineralization ratio and TOC reached 100% and 82.61% at 120 min of optimization condition, respectively. Phenols 14-20 L1 cell adhesion molecule Homo sapiens 28-31 31754264-2 2019 METHODS: We analysed by immunohistochemistry L1CAM protein expression in formalin-fixed, paraffin-embedded specimens from 309 GC patients. Paraffin 89-97 L1 cell adhesion molecule Homo sapiens 45-50 31330434-7 2019 In particular, a total removal of carbamazepine (CBZ) and imidacloprid (IMD) was observed for UV-C/FC process with 0.27 kJ L-1 and 10 mgL-1 of FC, while, in the sunlight/FC process (same FC dose), CBZ total removal took place quite fast (0.50 kJ L-1), but 90% removal of IMD was observed only after 60 min (7.09 kJ L-1). Carbamazepine 34-47 L1 cell adhesion molecule Homo sapiens 123-139 31330434-7 2019 In particular, a total removal of carbamazepine (CBZ) and imidacloprid (IMD) was observed for UV-C/FC process with 0.27 kJ L-1 and 10 mgL-1 of FC, while, in the sunlight/FC process (same FC dose), CBZ total removal took place quite fast (0.50 kJ L-1), but 90% removal of IMD was observed only after 60 min (7.09 kJ L-1). Carbamazepine 49-52 L1 cell adhesion molecule Homo sapiens 123-139 31330434-7 2019 In particular, a total removal of carbamazepine (CBZ) and imidacloprid (IMD) was observed for UV-C/FC process with 0.27 kJ L-1 and 10 mgL-1 of FC, while, in the sunlight/FC process (same FC dose), CBZ total removal took place quite fast (0.50 kJ L-1), but 90% removal of IMD was observed only after 60 min (7.09 kJ L-1). imidacloprid 58-70 L1 cell adhesion molecule Homo sapiens 123-139 31766549-5 2019 Nonetheless, their use in sensors is becoming more and more common, with the obtainment of very good results in terms of selectivity and sensitivity (up to 5.4 x 10-10 mol L-1 and 1.8 x 10-9 mol L-1 for caffeine and theophylline, respectively). Caffeine 203-211 L1 cell adhesion molecule Homo sapiens 172-190 31596176-4 2019 The lowest LOD was found for acetaldehyde (0.03 microg L-1), while the lowest LOQ value (1.0 microg L-1) was found for acetaldehyde and EC, formaldehyde and furfural. Acetaldehyde 119-131 L1 cell adhesion molecule Homo sapiens 100-103 31494490-3 2019 At the experimental conditions employed in the present work (compound parabolic collectors photoreactor) the optimal TiO2 concentration was about 50 mg L-1. titanium dioxide 117-121 L1 cell adhesion molecule Homo sapiens 152-155 31635452-10 2019 However, the addition of H2O2, when the background NH2Cl level was above 2 mg L-1 (as Cl2) provided limited improvement in treatment efficiency. Water 25-29 L1 cell adhesion molecule Homo sapiens 78-81 31532059-1 2019 Here, we report synthesis and characterization of four new aroyl-hydrazone derivatives; L 1 -L 4 and their structural as well as biological activities have been explored. aroyl-hydrazone 59-74 L1 cell adhesion molecule Homo sapiens 88-91 31404751-2 2019 The results indicated that the strain had a higher maximum quantum efficiency (Fv/Fm, 0.71) and biomass yield (1.42 g L-1) at pH 8.3 under 25.2 g L-1 NaHCO3 compared to pH 7.3 or 9.3. Sodium Bicarbonate 150-156 L1 cell adhesion molecule Homo sapiens 118-121 31404751-2 2019 The results indicated that the strain had a higher maximum quantum efficiency (Fv/Fm, 0.71) and biomass yield (1.42 g L-1) at pH 8.3 under 25.2 g L-1 NaHCO3 compared to pH 7.3 or 9.3. Sodium Bicarbonate 150-156 L1 cell adhesion molecule Homo sapiens 146-149 31482525-4 2019 Considering the interest to find an optimal condition for all analytes simultaneously, the best extraction parameters found were as follows: pH = 5.33, concentration of Na2HPO4 = 0.0088 mol L-1 and organic phase volume = 4.5 mL. sodium phosphate 169-176 L1 cell adhesion molecule Homo sapiens 190-193 31482525-8 2019 The difenoconazole was detected in concentrations between 12.53 and 94.76 ng L-1. difenoconazole 4-18 L1 cell adhesion molecule Homo sapiens 77-80 31039890-7 2019 The supporting electrolyte was NaCl solution of 1 g L-1. nacl solution 31-44 L1 cell adhesion molecule Homo sapiens 52-55 31466145-2 2019 Coupled system showed the highest total nitrogen (TN) removal efficiency of 67.85% with the addition of 15 g L-1 iron shavings at pH 7.0, which was higher than 29.62% in the mono-ZVI system and 43.86% in the mono-cell system. Nitrogen 40-48 L1 cell adhesion molecule Homo sapiens 109-112 31466145-2 2019 Coupled system showed the highest total nitrogen (TN) removal efficiency of 67.85% with the addition of 15 g L-1 iron shavings at pH 7.0, which was higher than 29.62% in the mono-ZVI system and 43.86% in the mono-cell system. Iron 113-117 L1 cell adhesion molecule Homo sapiens 109-112 31466145-3 2019 Besides, the activities of nitrate reductase (NAR), nitrite reductase (NIR), nitric oxide reductase (NOR) and nitrous oxide reductase (N2OR) were significantly improved at ZVI dosage of 15 g L-1 and pH 7.0, which contributed to the higher TN removal efficiency in coupled system. Iron 172-175 L1 cell adhesion molecule Homo sapiens 191-194 31090990-2 2019 This study aims to evaluate a combined process using heterogeneous photocatalysis, with ZnO/UV or TiO2 /UV (0.6 g catalyst L-1 solution/2-hr UV radiation), and a biological process for textile wastewater treatment. titanium dioxide 98-102 L1 cell adhesion molecule Homo sapiens 123-126 31400591-7 2019 During chlorination, bromide-catalysis enhances the rate of the oxidation of Se(IV) to Se(VI) from 50% to nearly 90% with bromide concentrations of 50 mug L-1 and 200 mug L-1, respectively, at pH 7.0 and a chlorine dose of 2.0 mg L-1 (within 15 min). Bromides 21-28 L1 cell adhesion molecule Homo sapiens 155-174 31203953-5 2019 This fully automated analyzer had a limit of detection of 0.02 mumol L-1 for nitrite and 0.14 mumol L-1 for nitrate. Nitrites 77-84 L1 cell adhesion molecule Homo sapiens 69-72 31434054-4 2019 When the concentrations of zinc and tetracycline increased to 3.39 mg L-1 in R1 and 1.0 mg L-1 in R2, an obvious deterioration in performance was observed. Tetracycline 36-48 L1 cell adhesion molecule Homo sapiens 70-85 31203953-5 2019 This fully automated analyzer had a limit of detection of 0.02 mumol L-1 for nitrite and 0.14 mumol L-1 for nitrate. Nitrates 108-115 L1 cell adhesion molecule Homo sapiens 100-103 31203953-7 2019 With automated dilution, the calibration curve for nitrate was linear up to a concentration of 400 mumol L-1 (R2 > 0.999). Nitrates 51-58 L1 cell adhesion molecule Homo sapiens 105-108 31337646-5 2019 EXPERIMENTAL DESIGN: We prepared a theranostic convergence bioradiopharmaceutical using chimeric anti-L1CAM antibody (cA10-A3) conjugated with 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) chelator and labeled with 64Cu or 177Lu and evaluated the immuno-PET or SPECT/CT imaging and biodistribution with 64Cu-/177Lu-cA10-A3 in various cholangiocarcinoma xenograft models. ca10-a3 118-125 L1 cell adhesion molecule Homo sapiens 102-107 31337646-5 2019 EXPERIMENTAL DESIGN: We prepared a theranostic convergence bioradiopharmaceutical using chimeric anti-L1CAM antibody (cA10-A3) conjugated with 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) chelator and labeled with 64Cu or 177Lu and evaluated the immuno-PET or SPECT/CT imaging and biodistribution with 64Cu-/177Lu-cA10-A3 in various cholangiocarcinoma xenograft models. 1,4,7-triazacyclononane-N,N',N''-triacetic acid 143-187 L1 cell adhesion molecule Homo sapiens 102-107 31337646-5 2019 EXPERIMENTAL DESIGN: We prepared a theranostic convergence bioradiopharmaceutical using chimeric anti-L1CAM antibody (cA10-A3) conjugated with 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) chelator and labeled with 64Cu or 177Lu and evaluated the immuno-PET or SPECT/CT imaging and biodistribution with 64Cu-/177Lu-cA10-A3 in various cholangiocarcinoma xenograft models. 1,4,7-triazacyclononane-N,N',N''-triacetic acid 189-193 L1 cell adhesion molecule Homo sapiens 102-107 31337646-5 2019 EXPERIMENTAL DESIGN: We prepared a theranostic convergence bioradiopharmaceutical using chimeric anti-L1CAM antibody (cA10-A3) conjugated with 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) chelator and labeled with 64Cu or 177Lu and evaluated the immuno-PET or SPECT/CT imaging and biodistribution with 64Cu-/177Lu-cA10-A3 in various cholangiocarcinoma xenograft models. Copper-64 221-225 L1 cell adhesion molecule Homo sapiens 102-107 31337646-5 2019 EXPERIMENTAL DESIGN: We prepared a theranostic convergence bioradiopharmaceutical using chimeric anti-L1CAM antibody (cA10-A3) conjugated with 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) chelator and labeled with 64Cu or 177Lu and evaluated the immuno-PET or SPECT/CT imaging and biodistribution with 64Cu-/177Lu-cA10-A3 in various cholangiocarcinoma xenograft models. Lutetium-177 229-234 L1 cell adhesion molecule Homo sapiens 102-107 31337646-5 2019 EXPERIMENTAL DESIGN: We prepared a theranostic convergence bioradiopharmaceutical using chimeric anti-L1CAM antibody (cA10-A3) conjugated with 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) chelator and labeled with 64Cu or 177Lu and evaluated the immuno-PET or SPECT/CT imaging and biodistribution with 64Cu-/177Lu-cA10-A3 in various cholangiocarcinoma xenograft models. Copper-64 309-313 L1 cell adhesion molecule Homo sapiens 102-107 31337646-5 2019 EXPERIMENTAL DESIGN: We prepared a theranostic convergence bioradiopharmaceutical using chimeric anti-L1CAM antibody (cA10-A3) conjugated with 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) chelator and labeled with 64Cu or 177Lu and evaluated the immuno-PET or SPECT/CT imaging and biodistribution with 64Cu-/177Lu-cA10-A3 in various cholangiocarcinoma xenograft models. ca10-a3 321-328 L1 cell adhesion molecule Homo sapiens 102-107 31337646-10 2019 CONCLUSIONS: Anti-L1CAM immuno-PET imaging using 64Cu-cA10-A3 could be translated into the clinic for characterizing the pharmacokinetics and selecting appropriate patients for radioimmunotherapy. 64cu-ca10-a3 49-61 L1 cell adhesion molecule Homo sapiens 18-23 31854825-7 2019 The total amounts of nitrogen removed by synchronous nitrification and denitrification were 29.89, 28.77, and 29.78 mg L-1. Nitrogen 21-29 L1 cell adhesion molecule Homo sapiens 119-122 31598322-5 2019 The optimal solid/liquid ratio, temperature and reaction time for the leaching process of the three organic acids was the same (10 g l-1, 70 C, 60 min). organic acids 100-113 L1 cell adhesion molecule Homo sapiens 133-150 31251365-2 2019 The arithmetic mean ( +- standard deviation) of tritium concentrations in precipitation samples from Hokkaido, Gifu and Okinawa were estimated to be 0.62 +- 0.27 Bq L-1, 0.32 +- 0.12 Bq L-1 and 0.13 +- 0.05 Bq L-1, respectively. Tritium 48-55 L1 cell adhesion molecule Homo sapiens 165-168 31251365-2 2019 The arithmetic mean ( +- standard deviation) of tritium concentrations in precipitation samples from Hokkaido, Gifu and Okinawa were estimated to be 0.62 +- 0.27 Bq L-1, 0.32 +- 0.12 Bq L-1 and 0.13 +- 0.05 Bq L-1, respectively. Tritium 48-55 L1 cell adhesion molecule Homo sapiens 186-189 31251365-2 2019 The arithmetic mean ( +- standard deviation) of tritium concentrations in precipitation samples from Hokkaido, Gifu and Okinawa were estimated to be 0.62 +- 0.27 Bq L-1, 0.32 +- 0.12 Bq L-1 and 0.13 +- 0.05 Bq L-1, respectively. Tritium 48-55 L1 cell adhesion molecule Homo sapiens 186-189 31202339-8 2019 The analytical curve was linear in the glucose concentration range from 1.0 x 10-4 mol L-1 to 4 x 10-2 mol L-1, with a limit of detection of 3 x 10-5 mol L-1. Glucose 39-46 L1 cell adhesion molecule Homo sapiens 87-102 31961804-2 2019 The decoloration rate and chemical oxygen demand (COD) of wastewater were evaluated during plasma treatments with the initial concentration of methyl violet of 300 mg L-1. Gentian Violet 143-156 L1 cell adhesion molecule Homo sapiens 167-170 31146836-8 2019 Under the optimum condition, the linear range of urea and creatinine were 30-240 mg L-1 and 10-500 mg L-1, with limits of detection of 9.0 mg L-1 and 0.9 mg L-1, respectively. Urea 49-53 L1 cell adhesion molecule Homo sapiens 84-105 31146836-8 2019 Under the optimum condition, the linear range of urea and creatinine were 30-240 mg L-1 and 10-500 mg L-1, with limits of detection of 9.0 mg L-1 and 0.9 mg L-1, respectively. Creatinine 58-68 L1 cell adhesion molecule Homo sapiens 84-105 31154220-8 2019 The Se concentration in soil solution without and with 4% HA addition at the day 15 of incubation were 1.05 mg L-1 and 0.30 mg L-1, respectively. Selenium 4-6 L1 cell adhesion molecule Homo sapiens 111-114 31154220-8 2019 The Se concentration in soil solution without and with 4% HA addition at the day 15 of incubation were 1.05 mg L-1 and 0.30 mg L-1, respectively. Selenium 4-6 L1 cell adhesion molecule Homo sapiens 127-130 31533832-11 2019 Exploratory analyses revealed a novel significant association of high combined CD274 & PDCD1LG2 (L1/L2) transcript expression with PFS (p < 0.0001) and OS (p = 0.0011), which remained significant at a multivariate level for both PFS (HR = 0.31) and OS (HR = 0.39). Adenosine Monophosphate 86-89 L1 cell adhesion molecule Homo sapiens 101-106 31146065-8 2019 Fluoride was captured by L1 and L3 via electrostatic attraction and ligand exchange of different bond strength. Fluorides 0-8 L1 cell adhesion molecule Homo sapiens 25-34 31572680-0 2019 Integrated Transcriptome Analysis Reveals KLK5 and L1CAM Predict Response to Anlotinib in NSCLC at 3rd Line. anlotinib 77-86 L1 cell adhesion molecule Homo sapiens 51-56 31572680-6 2019 Moreover, an independent validation in a cohort of ALTER0303 (NCT02388919) indicated that high serum levels of KLK5 and L1CAM were also associated with poor anlotinib response in NSCLC patients at 3rd line. anlotinib 157-166 L1 cell adhesion molecule Homo sapiens 120-125 31572680-7 2019 Lastly, we demonstrated that knockdown of KLK5 and L1CAM increases anlotinib-induced cytotoxicity in anlotinib-resistant NCI-H1975 cells. anlotinib 67-76 L1 cell adhesion molecule Homo sapiens 51-56 31572680-7 2019 Lastly, we demonstrated that knockdown of KLK5 and L1CAM increases anlotinib-induced cytotoxicity in anlotinib-resistant NCI-H1975 cells. anlotinib 101-110 L1 cell adhesion molecule Homo sapiens 51-56 31572680-8 2019 Collectively, our study suggested serum levels of KLK5 and L1CAM potentially serve as biomarkers for anlotinib-responsive stratification in NSCLC patients at 3rd line. anlotinib 101-110 L1 cell adhesion molecule Homo sapiens 59-64 31158585-3 2019 It was found that the degradation efficiency of 0.018 mmol L-1 DBP was 86.73% under the conditions of 0.40 g L-1 and 2.70 mmol L-1 persulfate at a wide pH range. Peroxydisulfate 131-141 L1 cell adhesion molecule Homo sapiens 109-118 31132594-5 2019 The maximum ciprofloxacin adsorption capacity of the biochar reached 449.40 mg L-1. Ciprofloxacin 12-25 L1 cell adhesion molecule Homo sapiens 79-82 31405218-6 2019 The degradation efficiency of Rhodamine B (RhB, 20 mg L-1) can reach nearly 100% within 25 min, the apparent rate constant (kapp/min-1) is approximately 40.06 and 3.87 times higher than that of pure CuS and Bi2WO6, respectively. rhodamine B 30-41 L1 cell adhesion molecule Homo sapiens 54-57 31108438-4 2019 RhB discoloration is improved with increasing catalyst dosage (0-2.0 g L-1), H2O2 dosage (0-0.15 mol L-1), solution pH (4.66-9.36) and temperature (30-50 C). rhodamine B 0-3 L1 cell adhesion molecule Homo sapiens 71-74 31108438-4 2019 RhB discoloration is improved with increasing catalyst dosage (0-2.0 g L-1), H2O2 dosage (0-0.15 mol L-1), solution pH (4.66-9.36) and temperature (30-50 C). rhodamine B 0-3 L1 cell adhesion molecule Homo sapiens 101-104 31108438-4 2019 RhB discoloration is improved with increasing catalyst dosage (0-2.0 g L-1), H2O2 dosage (0-0.15 mol L-1), solution pH (4.66-9.36) and temperature (30-50 C). Hydrogen Peroxide 77-81 L1 cell adhesion molecule Homo sapiens 101-104 31420781-6 2019 The detection limit was 9.1 x 10-8 mol L-1, a satisfying level to detect Cu2+ in the micromolar scale. cupric ion 73-77 L1 cell adhesion molecule Homo sapiens 39-42 31386693-11 2019 DAB was found in >70% of samples at variable concentrations (<3-1,900 ng L-1), the highest concentrations corresponding to lake samples in cyanobacterial bloom periods. 2,4-diaminobutyric acid 0-3 L1 cell adhesion molecule Homo sapiens 79-82 31227868-4 2019 Nitrite and ammonium removal rates of up to 455 mg N-NO2- L-1 day-1 and 228 mg N-NH4+ L-1 were reached. Nitrites 0-7 L1 cell adhesion molecule Homo sapiens 58-61 31227868-4 2019 Nitrite and ammonium removal rates of up to 455 mg N-NO2- L-1 day-1 and 228 mg N-NH4+ L-1 were reached. Nitrites 0-7 L1 cell adhesion molecule Homo sapiens 86-89 31227868-4 2019 Nitrite and ammonium removal rates of up to 455 mg N-NO2- L-1 day-1 and 228 mg N-NH4+ L-1 were reached. Ammonium Compounds 12-20 L1 cell adhesion molecule Homo sapiens 58-61 31227868-4 2019 Nitrite and ammonium removal rates of up to 455 mg N-NO2- L-1 day-1 and 228 mg N-NH4+ L-1 were reached. Ammonium Compounds 12-20 L1 cell adhesion molecule Homo sapiens 86-89 31227868-4 2019 Nitrite and ammonium removal rates of up to 455 mg N-NO2- L-1 day-1 and 228 mg N-NH4+ L-1 were reached. n-nh4 79-84 L1 cell adhesion molecule Homo sapiens 86-89 31227868-5 2019 All nitrate produced by anammox bacteria (57 mg N-NO3- L-1 day-1) was consumed, leading to a nitrogen removal efficiency of 97.5%. Nitrates 4-11 L1 cell adhesion molecule Homo sapiens 55-58 31227868-5 2019 All nitrate produced by anammox bacteria (57 mg N-NO3- L-1 day-1) was consumed, leading to a nitrogen removal efficiency of 97.5%. Nitrogen 93-101 L1 cell adhesion molecule Homo sapiens 55-58 30982513-6 2019 Linear calibration graphs are obtained within 0.02-2, 0.1-20, 0.2-1 mg L-1 for NO2-, NO3- and NH4+, along with detection limits of 0.006, 0.03, 0.06 mg L-1, respectively. Nitrogen Dioxide 79-82 L1 cell adhesion molecule Homo sapiens 71-74 30982513-6 2019 Linear calibration graphs are obtained within 0.02-2, 0.1-20, 0.2-1 mg L-1 for NO2-, NO3- and NH4+, along with detection limits of 0.006, 0.03, 0.06 mg L-1, respectively. Ammonia 94-97 L1 cell adhesion molecule Homo sapiens 71-74 31335128-3 2019 According to our calculations, the bifurcation points of reaction pathways caused by different ligands and bases combinations are L1/L2Int5, a [DPPP/DIBPP]benzoylpalladium(II)iodide complex. dppp/dibpp]benzoylpalladium(ii)iodide 144-181 L1 cell adhesion molecule Homo sapiens 130-139 31335128-4 2019 The affinity of L1/L2Int5 and adducts (K2CO3 and DBU), as well as the substrate itself, are the predominant factors of switching from aminocarbonylation to alkoxycarbonylation. potassium carbonate 39-44 L1 cell adhesion molecule Homo sapiens 16-25 31335128-4 2019 The affinity of L1/L2Int5 and adducts (K2CO3 and DBU), as well as the substrate itself, are the predominant factors of switching from aminocarbonylation to alkoxycarbonylation. 1,8-diazabicyclo(5.4.0)undec-7-ene 49-52 L1 cell adhesion molecule Homo sapiens 16-25 31079686-2 2019 According to the central composite design (CCD), adsorption of IBD onto CoFe2O4/chitosan composite was favored when initial pH and adsorbent dosage were 3.0 and 0.75 g L-1, respectively. cobalt ferrite 72-79 L1 cell adhesion molecule Homo sapiens 168-171 31405218-6 2019 The degradation efficiency of Rhodamine B (RhB, 20 mg L-1) can reach nearly 100% within 25 min, the apparent rate constant (kapp/min-1) is approximately 40.06 and 3.87 times higher than that of pure CuS and Bi2WO6, respectively. rhodamine B 43-46 L1 cell adhesion molecule Homo sapiens 54-57 31405218-7 2019 The degradation efficiency of tetracycline hydrochloride (TC-HCl, 40mg L-1) can reach 73% in 50 min by employing 0.1% CuS/Bi2WO6 heterostructure as a photo-Fenton-like catalyst. Tetracycline 30-56 L1 cell adhesion molecule Homo sapiens 71-74 31405218-7 2019 The degradation efficiency of tetracycline hydrochloride (TC-HCl, 40mg L-1) can reach 73% in 50 min by employing 0.1% CuS/Bi2WO6 heterostructure as a photo-Fenton-like catalyst. Tetracycline 58-64 L1 cell adhesion molecule Homo sapiens 71-74 31405218-7 2019 The degradation efficiency of tetracycline hydrochloride (TC-HCl, 40mg L-1) can reach 73% in 50 min by employing 0.1% CuS/Bi2WO6 heterostructure as a photo-Fenton-like catalyst. cupric sulfide 118-121 L1 cell adhesion molecule Homo sapiens 71-74 28455819-5 2019 N-Cu-biochar showed superior catalytic ability in mediating p-nitrophenol reduction as compared to Cu-biochar and N-doped biochar, achieving complete reduction of 0.35 mM p-nitrophenol within 30 min at a dose of 0.25 g L-1. n-cu 0-4 L1 cell adhesion molecule Homo sapiens 219-222 28455819-5 2019 N-Cu-biochar showed superior catalytic ability in mediating p-nitrophenol reduction as compared to Cu-biochar and N-doped biochar, achieving complete reduction of 0.35 mM p-nitrophenol within 30 min at a dose of 0.25 g L-1. 4-nitrophenol 60-73 L1 cell adhesion molecule Homo sapiens 219-222 28455819-5 2019 N-Cu-biochar showed superior catalytic ability in mediating p-nitrophenol reduction as compared to Cu-biochar and N-doped biochar, achieving complete reduction of 0.35 mM p-nitrophenol within 30 min at a dose of 0.25 g L-1. 4-nitrophenol 171-184 L1 cell adhesion molecule Homo sapiens 219-222 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Zinc 43-45 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Lead 31-33 L1 cell adhesion molecule Homo sapiens 94-97 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Lead 31-33 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Lead 31-33 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Lead 31-33 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Lead 31-33 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Lead 31-33 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Zinc 43-45 L1 cell adhesion molecule Homo sapiens 94-97 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Zinc 43-45 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Zinc 43-45 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Zinc 43-45 L1 cell adhesion molecule Homo sapiens 107-110 31220758-4 2019 When the milling time was 2 h, Pb, Cu, and Zn leaching concentrations decreased from 13.92 mg L-1, 2.83 mg L-1, and 114.42 mg L-1 to 0.027 mg L-1, 0.59 mg L-1, and 0.16 mg L-1, respectively; these values were all lower than the surface water Class III standard regulatory thresholds proposed by the Chinese Ministry of Ecology and Environment. Zinc 43-45 L1 cell adhesion molecule Homo sapiens 107-110 31078034-3 2019 Under neutral pH and room temperature condition, about 71.3% of pentachlorophenol (PCP, 10 mg L-1) was decomposed in 180 min with 40 mmol L-1 persulfate and 1.0 mmol L-1 AA, while only 15.4% and 3.2% of PCP was removed by alone persulfate and AA respectively. Pentachlorophenol 64-81 L1 cell adhesion molecule Homo sapiens 94-97 31078034-3 2019 Under neutral pH and room temperature condition, about 71.3% of pentachlorophenol (PCP, 10 mg L-1) was decomposed in 180 min with 40 mmol L-1 persulfate and 1.0 mmol L-1 AA, while only 15.4% and 3.2% of PCP was removed by alone persulfate and AA respectively. Pentachlorophenol 64-81 L1 cell adhesion molecule Homo sapiens 138-141 31078034-3 2019 Under neutral pH and room temperature condition, about 71.3% of pentachlorophenol (PCP, 10 mg L-1) was decomposed in 180 min with 40 mmol L-1 persulfate and 1.0 mmol L-1 AA, while only 15.4% and 3.2% of PCP was removed by alone persulfate and AA respectively. Pentachlorophenol 64-81 L1 cell adhesion molecule Homo sapiens 138-141 31078034-3 2019 Under neutral pH and room temperature condition, about 71.3% of pentachlorophenol (PCP, 10 mg L-1) was decomposed in 180 min with 40 mmol L-1 persulfate and 1.0 mmol L-1 AA, while only 15.4% and 3.2% of PCP was removed by alone persulfate and AA respectively. Pentachlorophenol 83-86 L1 cell adhesion molecule Homo sapiens 94-97 31078034-3 2019 Under neutral pH and room temperature condition, about 71.3% of pentachlorophenol (PCP, 10 mg L-1) was decomposed in 180 min with 40 mmol L-1 persulfate and 1.0 mmol L-1 AA, while only 15.4% and 3.2% of PCP was removed by alone persulfate and AA respectively. Pentachlorophenol 83-86 L1 cell adhesion molecule Homo sapiens 138-141 31078034-3 2019 Under neutral pH and room temperature condition, about 71.3% of pentachlorophenol (PCP, 10 mg L-1) was decomposed in 180 min with 40 mmol L-1 persulfate and 1.0 mmol L-1 AA, while only 15.4% and 3.2% of PCP was removed by alone persulfate and AA respectively. Pentachlorophenol 83-86 L1 cell adhesion molecule Homo sapiens 138-141 31078034-3 2019 Under neutral pH and room temperature condition, about 71.3% of pentachlorophenol (PCP, 10 mg L-1) was decomposed in 180 min with 40 mmol L-1 persulfate and 1.0 mmol L-1 AA, while only 15.4% and 3.2% of PCP was removed by alone persulfate and AA respectively. Peroxydisulfate 142-152 L1 cell adhesion molecule Homo sapiens 138-141 31078034-3 2019 Under neutral pH and room temperature condition, about 71.3% of pentachlorophenol (PCP, 10 mg L-1) was decomposed in 180 min with 40 mmol L-1 persulfate and 1.0 mmol L-1 AA, while only 15.4% and 3.2% of PCP was removed by alone persulfate and AA respectively. Peroxydisulfate 142-152 L1 cell adhesion molecule Homo sapiens 138-141 31413410-6 2019 The linear calibration curve of the developed method towards iodide was in the concentration range of 0.5-4.0 mg/L with sensitivity of - 1.383 microA mg/L-1 cm-2 (R2 = 0.9950), limit of detection (LOD) of 0.3 mg/L and limit of quantification (LOQ) of 1.0 mg/L, respectively. Iodides 61-67 L1 cell adhesion molecule Homo sapiens 153-161 30849204-9 2019 The kr and Ks values were 0.027 mg L-1 min-1 and 0.621 L/mg, respectively. Potassium 11-13 L1 cell adhesion molecule Homo sapiens 35-45 31376963-10 2019 Leaching with 1 M citrate, 0.2 M N2H4, at pH = 5, using sodium hydroxide (NaOH) at solid:liquid (S:L) ratio of 20 g L-1, yielded a remarkably high In recovery of 98.9% after 16.6 h. Citric Acid 18-25 L1 cell adhesion molecule Homo sapiens 116-119 30967189-4 2019 Based on the obtained results, the dramatic reduction of "hands-on" manipulation and the elimination of hazardous materials (e.g., sodium borohydride (NaBH4) and stannous chloride (SnCl2)) from the process enabled a simple and ultraclean procedure with an extremely low detection limit of 0.75 ng L-1 for Hg2+ in urine samples. sodium borohydride 131-149 L1 cell adhesion molecule Homo sapiens 297-300 31376963-10 2019 Leaching with 1 M citrate, 0.2 M N2H4, at pH = 5, using sodium hydroxide (NaOH) at solid:liquid (S:L) ratio of 20 g L-1, yielded a remarkably high In recovery of 98.9% after 16.6 h. hydrazine 33-37 L1 cell adhesion molecule Homo sapiens 116-119 31376963-10 2019 Leaching with 1 M citrate, 0.2 M N2H4, at pH = 5, using sodium hydroxide (NaOH) at solid:liquid (S:L) ratio of 20 g L-1, yielded a remarkably high In recovery of 98.9% after 16.6 h. Sodium Hydroxide 56-72 L1 cell adhesion molecule Homo sapiens 116-119 31376963-10 2019 Leaching with 1 M citrate, 0.2 M N2H4, at pH = 5, using sodium hydroxide (NaOH) at solid:liquid (S:L) ratio of 20 g L-1, yielded a remarkably high In recovery of 98.9% after 16.6 h. Sodium Hydroxide 74-78 L1 cell adhesion molecule Homo sapiens 116-119 30967189-4 2019 Based on the obtained results, the dramatic reduction of "hands-on" manipulation and the elimination of hazardous materials (e.g., sodium borohydride (NaBH4) and stannous chloride (SnCl2)) from the process enabled a simple and ultraclean procedure with an extremely low detection limit of 0.75 ng L-1 for Hg2+ in urine samples. sodium borohydride 151-156 L1 cell adhesion molecule Homo sapiens 297-300 30967189-4 2019 Based on the obtained results, the dramatic reduction of "hands-on" manipulation and the elimination of hazardous materials (e.g., sodium borohydride (NaBH4) and stannous chloride (SnCl2)) from the process enabled a simple and ultraclean procedure with an extremely low detection limit of 0.75 ng L-1 for Hg2+ in urine samples. stannous chloride 162-179 L1 cell adhesion molecule Homo sapiens 297-300 31317342-9 2019 The method has a linear response in the 0.1 to 200 mug L-1 PAH concentration range. Polycyclic Aromatic Hydrocarbons 59-62 L1 cell adhesion molecule Homo sapiens 55-58 31854714-3 2019 The results showed that Cu2+ had a significant inhibitory effect on denitrification process using NO2- as an electron acceptor, and the semi-inhibitory concentration EC50 of sludge activity was 4.79 mg L-1. Copper 24-28 L1 cell adhesion molecule Homo sapiens 202-205 31854714-5 2019 When the concentration of Cu2+ was 0.5 mg L-1and 1 mg L-1, the denitrification activity of the sludge could be restored to the original level after acclimation. Copper 26-30 L1 cell adhesion molecule Homo sapiens 42-50 31854714-5 2019 When the concentration of Cu2+ was 0.5 mg L-1and 1 mg L-1, the denitrification activity of the sludge could be restored to the original level after acclimation. Copper 26-30 L1 cell adhesion molecule Homo sapiens 42-45 31854714-6 2019 When the concentration of Cu2+ was increased to 3 mg L-1, the denitrification performance was destroyed and difficult to recover, at which point the NO2--N removal rate was reduced to less than 10% and the denitrification system was severely inhibited. Copper 26-30 L1 cell adhesion molecule Homo sapiens 53-56 31000165-2 2019 The enzymatic activity and functional genes abundance associated with nitrification and denitrification at a 20 mg L-1 TC stress were higher than those at a mixtures stress of 20 mg L-1 TC and 10 mg L-1 Cu(II), while they were lower than those at a mixtures stress of 20 mg L-1 TC and 40 mg L-1 Cu(II). Tetracycline 119-121 L1 cell adhesion molecule Homo sapiens 115-118 31000165-2 2019 The enzymatic activity and functional genes abundance associated with nitrification and denitrification at a 20 mg L-1 TC stress were higher than those at a mixtures stress of 20 mg L-1 TC and 10 mg L-1 Cu(II), while they were lower than those at a mixtures stress of 20 mg L-1 TC and 40 mg L-1 Cu(II). Tetracycline 186-188 L1 cell adhesion molecule Homo sapiens 182-185 31000165-2 2019 The enzymatic activity and functional genes abundance associated with nitrification and denitrification at a 20 mg L-1 TC stress were higher than those at a mixtures stress of 20 mg L-1 TC and 10 mg L-1 Cu(II), while they were lower than those at a mixtures stress of 20 mg L-1 TC and 40 mg L-1 Cu(II). Tetracycline 186-188 L1 cell adhesion molecule Homo sapiens 182-185 31000165-2 2019 The enzymatic activity and functional genes abundance associated with nitrification and denitrification at a 20 mg L-1 TC stress were higher than those at a mixtures stress of 20 mg L-1 TC and 10 mg L-1 Cu(II), while they were lower than those at a mixtures stress of 20 mg L-1 TC and 40 mg L-1 Cu(II). Tetracycline 186-188 L1 cell adhesion molecule Homo sapiens 182-185 31000165-2 2019 The enzymatic activity and functional genes abundance associated with nitrification and denitrification at a 20 mg L-1 TC stress were higher than those at a mixtures stress of 20 mg L-1 TC and 10 mg L-1 Cu(II), while they were lower than those at a mixtures stress of 20 mg L-1 TC and 40 mg L-1 Cu(II). cu(ii) 295-301 L1 cell adhesion molecule Homo sapiens 115-118 31000165-4 2019 The incremental Cu(II) concentration at a 20 mg L-1 TC stress could not change the result that the sensitivity of denitrifying enzymatic activity to TC was higher than nitrifying enzymatic activity. cu(ii) 16-22 L1 cell adhesion molecule Homo sapiens 48-51 31000165-5 2019 Compared to the relative abundance of nitrifers and denitrifers at a 20 mg L-1 TC stress, the 10 mg L-1 Cu(II) addition resulted in their increase, while they decreased as the 40 mg L-1 Cu(II) addition. cu(ii) 104-110 L1 cell adhesion molecule Homo sapiens 100-103 31000165-5 2019 Compared to the relative abundance of nitrifers and denitrifers at a 20 mg L-1 TC stress, the 10 mg L-1 Cu(II) addition resulted in their increase, while they decreased as the 40 mg L-1 Cu(II) addition. cu(ii) 104-110 L1 cell adhesion molecule Homo sapiens 100-103 31000165-5 2019 Compared to the relative abundance of nitrifers and denitrifers at a 20 mg L-1 TC stress, the 10 mg L-1 Cu(II) addition resulted in their increase, while they decreased as the 40 mg L-1 Cu(II) addition. cu(ii) 186-192 L1 cell adhesion molecule Homo sapiens 100-103 31000165-5 2019 Compared to the relative abundance of nitrifers and denitrifers at a 20 mg L-1 TC stress, the 10 mg L-1 Cu(II) addition resulted in their increase, while they decreased as the 40 mg L-1 Cu(II) addition. cu(ii) 186-192 L1 cell adhesion molecule Homo sapiens 100-103 31066429-5 2019 The L1 and L2 molecules in complexes 4 and 5 adopt the same coordination and join adjacent Cd(ii) cations together with fumarates, giving rise to different 3D networks with vma and irl topologies. cd(ii) 91-97 L1 cell adhesion molecule Homo sapiens 4-13 29457761-5 2019 HP with 1.4 g TiO2 L-1 at pH 7 under sunlight, produced 85% TOC removal in deionized water and 39% in WWTP effluent also after 3 h treatment. Hematoporphyrins 0-2 L1 cell adhesion molecule Homo sapiens 19-22 29457761-5 2019 HP with 1.4 g TiO2 L-1 at pH 7 under sunlight, produced 85% TOC removal in deionized water and 39% in WWTP effluent also after 3 h treatment. titanium dioxide 14-18 L1 cell adhesion molecule Homo sapiens 19-22 29457761-5 2019 HP with 1.4 g TiO2 L-1 at pH 7 under sunlight, produced 85% TOC removal in deionized water and 39% in WWTP effluent also after 3 h treatment. Water 85-90 L1 cell adhesion molecule Homo sapiens 19-22 30582619-9 2019 At baseline, serum cortisol measured 284.0 +- 61.4 nmol/L and fell significantly to 15.5 +- 4.3 nmol/L 1 day following triamcinolone injection (P = .03). Triamcinolone 119-132 L1 cell adhesion molecule Homo sapiens 101-104 31066429-6 2019 The same coordination mode of L1 and L2 in complexes 6-8 joins adjacent Cd(ii) cations together with aromatic dicarboxylates, leading to different (63)(65 8), 2-periodic (6 3) and (4 4) layer motifs. cd(ii) 72-78 L1 cell adhesion molecule Homo sapiens 30-39 31066429-6 2019 The same coordination mode of L1 and L2 in complexes 6-8 joins adjacent Cd(ii) cations together with aromatic dicarboxylates, leading to different (63)(65 8), 2-periodic (6 3) and (4 4) layer motifs. malonic acid 110-124 L1 cell adhesion molecule Homo sapiens 30-39 31201523-8 2019 This is strikingly lower than the guideline values of domestic water given by the WHO which are 3 mug L-1 for Cd(II) and 10 mug L-1 for Pb(II). cd(ii) 110-116 L1 cell adhesion molecule Homo sapiens 102-105 31240479-7 2019 Under the most favorable conditions, the limits of detection (S/N = 3) for SUHs in spiked soya milk and grape juice samples ranged between 14-58 ng L-1 and 46-91 ng L-1, respectively. suhs 75-79 L1 cell adhesion molecule Homo sapiens 148-168 31854673-7 2019 A total of 32.6% of OP within the effluent was removed through bioadsorption reactions with activated coke, while the removal of OP was up to 79.1% when 30 mg L-1 of O3 was applied, which suggested that advanced oxidation was more beneficial for the enhancement of OP removal. Superoxides 166-168 L1 cell adhesion molecule Homo sapiens 159-162 31020976-1 2019 A tris-amine and oxy-ether functionalised macrocyclic wheel (NaphMC) and various phenanthroline based multidentate axles (L1, L2 and L3) are utilised for the formation of [n]pseudorotaxanes (n = 2, 3, 4) in high yields via Cu(ii) temptation and pi-pi stacking interactions. Tromethamine 2-12 L1 cell adhesion molecule Homo sapiens 122-135 31020976-1 2019 A tris-amine and oxy-ether functionalised macrocyclic wheel (NaphMC) and various phenanthroline based multidentate axles (L1, L2 and L3) are utilised for the formation of [n]pseudorotaxanes (n = 2, 3, 4) in high yields via Cu(ii) temptation and pi-pi stacking interactions. oxy-ether 17-26 L1 cell adhesion molecule Homo sapiens 122-135 31020976-1 2019 A tris-amine and oxy-ether functionalised macrocyclic wheel (NaphMC) and various phenanthroline based multidentate axles (L1, L2 and L3) are utilised for the formation of [n]pseudorotaxanes (n = 2, 3, 4) in high yields via Cu(ii) temptation and pi-pi stacking interactions. Phenanthrolines 81-95 L1 cell adhesion molecule Homo sapiens 122-135 31020976-1 2019 A tris-amine and oxy-ether functionalised macrocyclic wheel (NaphMC) and various phenanthroline based multidentate axles (L1, L2 and L3) are utilised for the formation of [n]pseudorotaxanes (n = 2, 3, 4) in high yields via Cu(ii) temptation and pi-pi stacking interactions. Rotaxanes 174-189 L1 cell adhesion molecule Homo sapiens 122-135 31020976-1 2019 A tris-amine and oxy-ether functionalised macrocyclic wheel (NaphMC) and various phenanthroline based multidentate axles (L1, L2 and L3) are utilised for the formation of [n]pseudorotaxanes (n = 2, 3, 4) in high yields via Cu(ii) temptation and pi-pi stacking interactions. cu(ii) 223-229 L1 cell adhesion molecule Homo sapiens 122-135 30826582-10 2019 Unlike receptor L1, receptor L2 does not recognize H2PO4-, but instead of H2PO4-, it recognizes bifluoride as evidenced from UV-Vis spectroscopic and naked-eye colorimetric studies. h2po4 51-56 L1 cell adhesion molecule Homo sapiens 16-31 30826582-10 2019 Unlike receptor L1, receptor L2 does not recognize H2PO4-, but instead of H2PO4-, it recognizes bifluoride as evidenced from UV-Vis spectroscopic and naked-eye colorimetric studies. h2po4 74-79 L1 cell adhesion molecule Homo sapiens 16-31 30826582-10 2019 Unlike receptor L1, receptor L2 does not recognize H2PO4-, but instead of H2PO4-, it recognizes bifluoride as evidenced from UV-Vis spectroscopic and naked-eye colorimetric studies. bifluoride 96-106 L1 cell adhesion molecule Homo sapiens 16-31 30771944-5 2019 Under the optimum conditions, a detection limit of 0.63 mug L-1 for TiO2 NPs and a sample throughput of 6 h-1 were achieved. titanium dioxide 68-72 L1 cell adhesion molecule Homo sapiens 60-63 30874074-5 2019 Our findings highlight the sensor"s capability of phenol detection in aqueous solutions with high sensitivity of 0.294x10-3 (mg L-1)-1, pH immunity ranging from 2.0 to 14.0, and high selectivity with a limit of detection of 30 mug L-1. Phenol 50-56 L1 cell adhesion molecule Homo sapiens 129-132 31197466-4 2019 The limits of detection (LOD) are 2.6 mg L-1 for Co(II) and 2.2 mg L-1 for Fe(III). ferric sulfate 75-82 L1 cell adhesion molecule Homo sapiens 67-70 31197466-7 2019 The first is UV-vis spectrometry which has a LOD as low as 0.14 mg L-1 for Co(II) (at 412 nm) and 0.12 mg L-1 for Fe(III) (at 400 nm). ferric sulfate 114-121 L1 cell adhesion molecule Homo sapiens 106-109 30772689-4 2019 Approximately 20 mg L-1 of Primidone was removed in less than 20 min if ozone was applied, regardless of the presence or absence of light and catalyst. Primidone 27-36 L1 cell adhesion molecule Homo sapiens 20-23 30744926-4 2019 The suppression threshold of Zn(II) on denitrifying bacteria was 10 mg L-1 for long-term exposure. Zinc 29-35 L1 cell adhesion molecule Homo sapiens 71-74 30744926-5 2019 The nitrogen removal rate was decreased by long-term addition of 10 mg L-1 Zn(II). Nitrogen 4-12 L1 cell adhesion molecule Homo sapiens 71-74 30744926-5 2019 The nitrogen removal rate was decreased by long-term addition of 10 mg L-1 Zn(II). Zinc 75-81 L1 cell adhesion molecule Homo sapiens 71-74 30716544-3 2019 The adsorption envelopes reveal that the adsorption of TAsIII on alpha-Fe2O3 is significantly less than that of arsenite (AsIII) in the pH range from 7 to 11 with the initial As concentration of 25 mg L-1. asiii 56-61 L1 cell adhesion molecule Homo sapiens 201-204 30716544-3 2019 The adsorption envelopes reveal that the adsorption of TAsIII on alpha-Fe2O3 is significantly less than that of arsenite (AsIII) in the pH range from 7 to 11 with the initial As concentration of 25 mg L-1. Arsenic 56-58 L1 cell adhesion molecule Homo sapiens 201-204 30716544-4 2019 However, at the initial As concentration of 135 mg L-1, the uptake of TAsIII by alpha-Fe2O3 is higher at pH 7 but lower at pH 8-11 than that of AsIII. alpha-fe2o3 80-91 L1 cell adhesion molecule Homo sapiens 51-54 30716544-5 2019 The adsorption isotherms show that the adsorption of As on alpha-Fe2O3 is largely inhibited by the presence of aqueous sulfide at pH 7 with low As equilibrium concentration (<40 mg L-1). alpha-fe2o3 59-70 L1 cell adhesion molecule Homo sapiens 184-187 30716544-5 2019 The adsorption isotherms show that the adsorption of As on alpha-Fe2O3 is largely inhibited by the presence of aqueous sulfide at pH 7 with low As equilibrium concentration (<40 mg L-1). Sulfides 119-126 L1 cell adhesion molecule Homo sapiens 184-187 30716544-6 2019 Whereas the uptake of As by alpha-Fe2O3 is highly elevated compared with the value predicted by Langmuir model at pH 7 with high As equilibrium concentration (>40 mg L-1), implying the formation of As-bearing (surface) precipitate. Arsenic 22-24 L1 cell adhesion molecule Homo sapiens 169-172 30716544-6 2019 Whereas the uptake of As by alpha-Fe2O3 is highly elevated compared with the value predicted by Langmuir model at pH 7 with high As equilibrium concentration (>40 mg L-1), implying the formation of As-bearing (surface) precipitate. alpha-fe2o3 28-39 L1 cell adhesion molecule Homo sapiens 169-172 30782553-6 2019 For a brine containing 3090 mg L-1 of Mg2+ and 685 mg L-1 of Ca2+, 62 kWh m-3 are needed for the full removal of both cations when a current density of 223 A m-2 is employed. brine 6-11 L1 cell adhesion molecule Homo sapiens 31-34 30782553-6 2019 For a brine containing 3090 mg L-1 of Mg2+ and 685 mg L-1 of Ca2+, 62 kWh m-3 are needed for the full removal of both cations when a current density of 223 A m-2 is employed. brine 6-11 L1 cell adhesion molecule Homo sapiens 54-57 30712591-7 2019 The method was optimized and validated for the determination of 29 pesticides in water, showing good linearity in the range between 0.012 and 40.00 mug L-1 with determination coefficients of R2 > 0,9649. Water 81-86 L1 cell adhesion molecule Homo sapiens 152-155 30791184-6 2019 2.8 mg L-1 ) under continuous operating mode, data indicates that about 1750 kg water m-2 membrane can be treated while maintaining drinking water quality, and the saturated membranes can be regenerated and reused several times without decrease in performance. Water 80-85 L1 cell adhesion molecule Homo sapiens 7-10 30735969-6 2019 In 21 days, metformin showed high stability in wastewater at 24 C and -20 C. The mean concentrations of metformin in all WWTPs ranged from 2.42 mug L-1 to 53.6 mug L-1. Metformin 12-21 L1 cell adhesion molecule Homo sapiens 150-161 30735969-6 2019 In 21 days, metformin showed high stability in wastewater at 24 C and -20 C. The mean concentrations of metformin in all WWTPs ranged from 2.42 mug L-1 to 53.6 mug L-1. Metformin 106-115 L1 cell adhesion molecule Homo sapiens 150-161 31001697-6 2019 Under optimal conditions obtained by ANN-MOEAD, the detection limit (S/N = 3), the quantitation limit(S/N = 10), and the linear range for Cu2+ were 0.05, 0.15, and 0.15-1000 mug L-1, respectively, and for Cd2+ were 0.07, 0.21, and 0.21-750 mug L-1, respectively. cupric ion 138-142 L1 cell adhesion molecule Homo sapiens 178-181 31001697-6 2019 Under optimal conditions obtained by ANN-MOEAD, the detection limit (S/N = 3), the quantitation limit(S/N = 10), and the linear range for Cu2+ were 0.05, 0.15, and 0.15-1000 mug L-1, respectively, and for Cd2+ were 0.07, 0.21, and 0.21-750 mug L-1, respectively. cupric ion 138-142 L1 cell adhesion molecule Homo sapiens 244-247 31001697-7 2019 The real sample recoveries at a spiking level of 0.05, 0.1, and 0.3 mg L-1 of Cu2+ and Cd2+ ions under the optimal conditions obtained by ANN-MOEA/D ranged from 94.8 to 105%. cupric ion 78-82 L1 cell adhesion molecule Homo sapiens 71-74 30682541-1 2019 In this study we describe the immobilization of arsenic as scorodite (FeAsO4.2H2O) by a thermophilic iron-oxidizing mixed culture from an acidic sulfate medium containing 500 mg L-1 of Fe(II), 500 mg L-1 As(III) and granular activated carbon (GAC) as the main arsenite oxidant. Arsenic 48-55 L1 cell adhesion molecule Homo sapiens 178-181 30682541-1 2019 In this study we describe the immobilization of arsenic as scorodite (FeAsO4.2H2O) by a thermophilic iron-oxidizing mixed culture from an acidic sulfate medium containing 500 mg L-1 of Fe(II), 500 mg L-1 As(III) and granular activated carbon (GAC) as the main arsenite oxidant. Arsenic 48-55 L1 cell adhesion molecule Homo sapiens 200-203 30682541-1 2019 In this study we describe the immobilization of arsenic as scorodite (FeAsO4.2H2O) by a thermophilic iron-oxidizing mixed culture from an acidic sulfate medium containing 500 mg L-1 of Fe(II), 500 mg L-1 As(III) and granular activated carbon (GAC) as the main arsenite oxidant. scorodite 70-81 L1 cell adhesion molecule Homo sapiens 178-181 30682541-1 2019 In this study we describe the immobilization of arsenic as scorodite (FeAsO4.2H2O) by a thermophilic iron-oxidizing mixed culture from an acidic sulfate medium containing 500 mg L-1 of Fe(II), 500 mg L-1 As(III) and granular activated carbon (GAC) as the main arsenite oxidant. scorodite 70-81 L1 cell adhesion molecule Homo sapiens 200-203 30743977-5 2019 Previously, preliminary experiments were carried out at laboratory scale using a photoreactor to optimize the Na2S2O8 (300 mg L-1) concentration on the rate constants of the found pesticides. sodium persulfate 110-117 L1 cell adhesion molecule Homo sapiens 126-129 30743977-6 2019 The residual levels of the studied pesticides in agro-wastewater (900 L) were in the range 0.02-1.17 mg L-1 for acrinathrin and fluopyram, respectively. acrinathrin 112-123 L1 cell adhesion molecule Homo sapiens 104-107 30743977-6 2019 The residual levels of the studied pesticides in agro-wastewater (900 L) were in the range 0.02-1.17 mg L-1 for acrinathrin and fluopyram, respectively. N-(2-(3-chloro-5-(trifluoromethyl)-2-pyridyl)ethyl)-alpha,alpha,alpha-trifluoro-o-toluamide 128-137 L1 cell adhesion molecule Homo sapiens 104-107 30896006-1 2019 The reactions between alcohols and the tetranuclear ethyl-Zn complexes of an ortho-phenylene-bridged polypyrrole macrocycle, Zn4Et4(L1) 1 and the related anthracenyl-bridged macrocyclic complex, Zn4Et4(THF)4(L2) 2 have been studied. Alcohols 22-30 L1 cell adhesion molecule Homo sapiens 125-137 30896006-1 2019 The reactions between alcohols and the tetranuclear ethyl-Zn complexes of an ortho-phenylene-bridged polypyrrole macrocycle, Zn4Et4(L1) 1 and the related anthracenyl-bridged macrocyclic complex, Zn4Et4(THF)4(L2) 2 have been studied. ethyl-zn 52-60 L1 cell adhesion molecule Homo sapiens 125-137 30896006-1 2019 The reactions between alcohols and the tetranuclear ethyl-Zn complexes of an ortho-phenylene-bridged polypyrrole macrocycle, Zn4Et4(L1) 1 and the related anthracenyl-bridged macrocyclic complex, Zn4Et4(THF)4(L2) 2 have been studied. Phenylephrine 83-92 L1 cell adhesion molecule Homo sapiens 125-137 30896006-1 2019 The reactions between alcohols and the tetranuclear ethyl-Zn complexes of an ortho-phenylene-bridged polypyrrole macrocycle, Zn4Et4(L1) 1 and the related anthracenyl-bridged macrocyclic complex, Zn4Et4(THF)4(L2) 2 have been studied. anthracenyl 154-165 L1 cell adhesion molecule Homo sapiens 125-137 31087936-2 2019 The study found that when the influent salinity was increased to 15 g L-1 and 30 g L-1, the nitrogen removal performance of the reactor decreased slightly, but was restored with the extension of the running time. Nitrogen 92-100 L1 cell adhesion molecule Homo sapiens 70-86 31087940-4 2019 The results showed that the dissolved N2O concentration in the agricultural headwater stream ranged from 0.26 to 1.28 mug L-1 with an annual mean value of 0.57 mug L-1, with nitrate (NO3--N, with an annual mean concentration of 1.45 mg L-1) as the predominant reactive N form. Nitrous Oxide 38-41 L1 cell adhesion molecule Homo sapiens 122-125 31087940-4 2019 The results showed that the dissolved N2O concentration in the agricultural headwater stream ranged from 0.26 to 1.28 mug L-1 with an annual mean value of 0.57 mug L-1, with nitrate (NO3--N, with an annual mean concentration of 1.45 mg L-1) as the predominant reactive N form. Nitrous Oxide 38-41 L1 cell adhesion molecule Homo sapiens 164-167 31087940-4 2019 The results showed that the dissolved N2O concentration in the agricultural headwater stream ranged from 0.26 to 1.28 mug L-1 with an annual mean value of 0.57 mug L-1, with nitrate (NO3--N, with an annual mean concentration of 1.45 mg L-1) as the predominant reactive N form. Nitrous Oxide 38-41 L1 cell adhesion molecule Homo sapiens 164-167 31087940-4 2019 The results showed that the dissolved N2O concentration in the agricultural headwater stream ranged from 0.26 to 1.28 mug L-1 with an annual mean value of 0.57 mug L-1, with nitrate (NO3--N, with an annual mean concentration of 1.45 mg L-1) as the predominant reactive N form. Nitrates 174-181 L1 cell adhesion molecule Homo sapiens 164-167 31087940-4 2019 The results showed that the dissolved N2O concentration in the agricultural headwater stream ranged from 0.26 to 1.28 mug L-1 with an annual mean value of 0.57 mug L-1, with nitrate (NO3--N, with an annual mean concentration of 1.45 mg L-1) as the predominant reactive N form. Nitrates 174-181 L1 cell adhesion molecule Homo sapiens 164-167 31087940-4 2019 The results showed that the dissolved N2O concentration in the agricultural headwater stream ranged from 0.26 to 1.28 mug L-1 with an annual mean value of 0.57 mug L-1, with nitrate (NO3--N, with an annual mean concentration of 1.45 mg L-1) as the predominant reactive N form. Nitrogen 38-39 L1 cell adhesion molecule Homo sapiens 122-125 31087940-4 2019 The results showed that the dissolved N2O concentration in the agricultural headwater stream ranged from 0.26 to 1.28 mug L-1 with an annual mean value of 0.57 mug L-1, with nitrate (NO3--N, with an annual mean concentration of 1.45 mg L-1) as the predominant reactive N form. Nitrogen 38-39 L1 cell adhesion molecule Homo sapiens 164-167 31087940-4 2019 The results showed that the dissolved N2O concentration in the agricultural headwater stream ranged from 0.26 to 1.28 mug L-1 with an annual mean value of 0.57 mug L-1, with nitrate (NO3--N, with an annual mean concentration of 1.45 mg L-1) as the predominant reactive N form. Nitrogen 38-39 L1 cell adhesion molecule Homo sapiens 164-167 31087940-5 2019 The seasonal mean concentrations of the dissolved N2O in winter, spring, summer, and autumn were 0.63, 0.45, 0.53, and 0.64 mug L-1, respectively, without significant seasonal variations. Nitrous Oxide 50-53 L1 cell adhesion molecule Homo sapiens 128-131 30976321-4 2019 The volumetric acetate production rate of MES with 12 mg cm-2 Mo2C was 0.19 +- 0.02 g L-1 day-1, which was 2.1 times higher than that of the control. Acetates 15-22 L1 cell adhesion molecule Homo sapiens 86-95 30976321-4 2019 The volumetric acetate production rate of MES with 12 mg cm-2 Mo2C was 0.19 +- 0.02 g L-1 day-1, which was 2.1 times higher than that of the control. 2-(N-morpholino)ethanesulfonic acid 42-45 L1 cell adhesion molecule Homo sapiens 86-95 30590292-5 2019 The removal efficiencies for TN and NH4N were greatest for an influent Fe2+ concentration of 50 mg L-1, while the greatest removal efficiencies for NO3N were observed at an influent Fe2+ concentration of 150 mg L-1. tn 29-31 L1 cell adhesion molecule Homo sapiens 99-102 30590292-5 2019 The removal efficiencies for TN and NH4N were greatest for an influent Fe2+ concentration of 50 mg L-1, while the greatest removal efficiencies for NO3N were observed at an influent Fe2+ concentration of 150 mg L-1. nh4n 36-40 L1 cell adhesion molecule Homo sapiens 99-102 30590292-5 2019 The removal efficiencies for TN and NH4N were greatest for an influent Fe2+ concentration of 50 mg L-1, while the greatest removal efficiencies for NO3N were observed at an influent Fe2+ concentration of 150 mg L-1. ammonium ferrous sulfate 71-75 L1 cell adhesion molecule Homo sapiens 99-102 30690262-4 2019 The 2H-phase M-MoS2 NSs dispersed in water were obtained with a high production yield of ~98.7%, a quite high monolayer ratio of ~95%, a homogenous lateral size of ~89 nm, and a large monodispersed concentration of ~0.41 g L-1. Deuterium 4-6 L1 cell adhesion molecule Homo sapiens 223-226 30996419-3 2019 The nanocomposite based biosensor shows comparatively high sensitivity (527 microA mg/L-1 cm-2), low detection limit (0.05 mg/L) in linear detection range 0.05-0.5 mg/L for formaldehyde detection using formaldehyde dehydrogenase (FDH) enzyme. Formaldehyde 173-185 L1 cell adhesion molecule Homo sapiens 86-94 30625553-4 2019 The signals detected at wavelength of 296 nm for Phe, 352 nm for 1H2NA and 307 nm for SA vary linearly when the concentrations in the range of 4.0-1.0 x 103 mug L-1, 4.0-1.2 x 103 mug L-1 and 4.0-8.0 x 102 mug L-1, respectively. phenanthrene 49-52 L1 cell adhesion molecule Homo sapiens 161-164 30625553-4 2019 The signals detected at wavelength of 296 nm for Phe, 352 nm for 1H2NA and 307 nm for SA vary linearly when the concentrations in the range of 4.0-1.0 x 103 mug L-1, 4.0-1.2 x 103 mug L-1 and 4.0-8.0 x 102 mug L-1, respectively. Salicylic Acid 86-88 L1 cell adhesion molecule Homo sapiens 161-164 30625553-4 2019 The signals detected at wavelength of 296 nm for Phe, 352 nm for 1H2NA and 307 nm for SA vary linearly when the concentrations in the range of 4.0-1.0 x 103 mug L-1, 4.0-1.2 x 103 mug L-1 and 4.0-8.0 x 102 mug L-1, respectively. Salicylic Acid 86-88 L1 cell adhesion molecule Homo sapiens 184-187 30625553-4 2019 The signals detected at wavelength of 296 nm for Phe, 352 nm for 1H2NA and 307 nm for SA vary linearly when the concentrations in the range of 4.0-1.0 x 103 mug L-1, 4.0-1.2 x 103 mug L-1 and 4.0-8.0 x 102 mug L-1, respectively. Salicylic Acid 86-88 L1 cell adhesion molecule Homo sapiens 184-187 30625553-5 2019 The detection limits were 0.08, 0.07 and 0.88 mug L-1 for Phe, 1H2NA and SA, with the relatively standard deviations less than 5.0%. phenanthrene 58-61 L1 cell adhesion molecule Homo sapiens 50-53 30625553-5 2019 The detection limits were 0.08, 0.07 and 0.88 mug L-1 for Phe, 1H2NA and SA, with the relatively standard deviations less than 5.0%. 1-hydroxy-2-naphthoic acid 63-68 L1 cell adhesion molecule Homo sapiens 50-53 30625553-5 2019 The detection limits were 0.08, 0.07 and 0.88 mug L-1 for Phe, 1H2NA and SA, with the relatively standard deviations less than 5.0%. Salicylic Acid 73-75 L1 cell adhesion molecule Homo sapiens 50-53 30379343-7 2019 The optimal extraction conditions for anthocyanin and antioxidant activity were found at extraction temperature of 20 C, extraction time of 44.95 min and beta-CD concentration of 45 g L-1 . Anthocyanins 38-49 L1 cell adhesion molecule Homo sapiens 185-188 30379343-7 2019 The optimal extraction conditions for anthocyanin and antioxidant activity were found at extraction temperature of 20 C, extraction time of 44.95 min and beta-CD concentration of 45 g L-1 . betadex 155-162 L1 cell adhesion molecule Homo sapiens 185-188 30598289-8 2019 The amount of BP and DiBP migrated from the PVC film was 83.53 mug L-1 and 31.30 mug L-1, respectively; whereas 71.62 mug L-1 of BP and 27.45 mug L-1 of DiBP migrated from the PP coffee capsules. benzophenone 14-16 L1 cell adhesion molecule Homo sapiens 67-70 30598289-8 2019 The amount of BP and DiBP migrated from the PVC film was 83.53 mug L-1 and 31.30 mug L-1, respectively; whereas 71.62 mug L-1 of BP and 27.45 mug L-1 of DiBP migrated from the PP coffee capsules. benzophenone 14-16 L1 cell adhesion molecule Homo sapiens 85-88 30598289-8 2019 The amount of BP and DiBP migrated from the PVC film was 83.53 mug L-1 and 31.30 mug L-1, respectively; whereas 71.62 mug L-1 of BP and 27.45 mug L-1 of DiBP migrated from the PP coffee capsules. benzophenone 14-16 L1 cell adhesion molecule Homo sapiens 85-88 30598289-8 2019 The amount of BP and DiBP migrated from the PVC film was 83.53 mug L-1 and 31.30 mug L-1, respectively; whereas 71.62 mug L-1 of BP and 27.45 mug L-1 of DiBP migrated from the PP coffee capsules. diisobutyl phthalate 21-25 L1 cell adhesion molecule Homo sapiens 67-70 30598289-8 2019 The amount of BP and DiBP migrated from the PVC film was 83.53 mug L-1 and 31.30 mug L-1, respectively; whereas 71.62 mug L-1 of BP and 27.45 mug L-1 of DiBP migrated from the PP coffee capsules. diisobutyl phthalate 21-25 L1 cell adhesion molecule Homo sapiens 85-88 30598289-8 2019 The amount of BP and DiBP migrated from the PVC film was 83.53 mug L-1 and 31.30 mug L-1, respectively; whereas 71.62 mug L-1 of BP and 27.45 mug L-1 of DiBP migrated from the PP coffee capsules. diisobutyl phthalate 21-25 L1 cell adhesion molecule Homo sapiens 85-88 30598289-8 2019 The amount of BP and DiBP migrated from the PVC film was 83.53 mug L-1 and 31.30 mug L-1, respectively; whereas 71.62 mug L-1 of BP and 27.45 mug L-1 of DiBP migrated from the PP coffee capsules. diisobutyl phthalate 153-157 L1 cell adhesion molecule Homo sapiens 122-138 30925688-8 2019 The complete degradation (100%) of MC-LR (10 mg L-1) was observed within 3 h, using as-synthesized co-modified TiO2 (0.4 g L-1) at pH 4 under visible light. cyanoginosin LR 35-40 L1 cell adhesion molecule Homo sapiens 48-51 30925688-8 2019 The complete degradation (100%) of MC-LR (10 mg L-1) was observed within 3 h, using as-synthesized co-modified TiO2 (0.4 g L-1) at pH 4 under visible light. cyanoginosin LR 35-40 L1 cell adhesion molecule Homo sapiens 123-126 30925688-8 2019 The complete degradation (100%) of MC-LR (10 mg L-1) was observed within 3 h, using as-synthesized co-modified TiO2 (0.4 g L-1) at pH 4 under visible light. titanium dioxide 111-115 L1 cell adhesion molecule Homo sapiens 123-126 30577117-2 2019 Firstly, sulphides (0.5 g L-1) and sulphites (2.5 g L-1) were catalytic oxidised at natural pH (8.7). Sulfides 9-18 L1 cell adhesion molecule Homo sapiens 26-29 30577117-2 2019 Firstly, sulphides (0.5 g L-1) and sulphites (2.5 g L-1) were catalytic oxidised at natural pH (8.7). Sulfides 9-18 L1 cell adhesion molecule Homo sapiens 52-55 30874074-5 2019 Our findings highlight the sensor"s capability of phenol detection in aqueous solutions with high sensitivity of 0.294x10-3 (mg L-1)-1, pH immunity ranging from 2.0 to 14.0, and high selectivity with a limit of detection of 30 mug L-1. Phenol 50-56 L1 cell adhesion molecule Homo sapiens 233-236 30899828-10 2019 Ordinance No 2914/2011 from the Brazilian Ministry of Health establishes the acceptable limits for atrazine and methyl parathion as 9 mug L-1 and 2 mug L-1. Atrazine 99-107 L1 cell adhesion molecule Homo sapiens 138-147 30899828-10 2019 Ordinance No 2914/2011 from the Brazilian Ministry of Health establishes the acceptable limits for atrazine and methyl parathion as 9 mug L-1 and 2 mug L-1. Atrazine 99-107 L1 cell adhesion molecule Homo sapiens 138-141 30899828-10 2019 Ordinance No 2914/2011 from the Brazilian Ministry of Health establishes the acceptable limits for atrazine and methyl parathion as 9 mug L-1 and 2 mug L-1. Methyl Parathion 112-128 L1 cell adhesion molecule Homo sapiens 138-147 30899828-10 2019 Ordinance No 2914/2011 from the Brazilian Ministry of Health establishes the acceptable limits for atrazine and methyl parathion as 9 mug L-1 and 2 mug L-1. Methyl Parathion 112-128 L1 cell adhesion molecule Homo sapiens 138-141 30590208-1 2019 An ammonia-oxidizing bacterium consortium showed approximately 100% removal of NH4+-N with an initial concentration of 262.28 +- 8.21 mg L-1 within 10 days, and only 16.54 +- 0.52% of NH4+-N was converted to NO2--N in this study. nh4+-n 79-85 L1 cell adhesion molecule Homo sapiens 137-140 30590208-4 2019 In a bioaugmentation treatment of eutrophic wastewater using the consortium, the removal efficiency of NH4+-N reached 90.85 +- 0.8% and 77.88 +- 1.86% at initial concentrations of 1.80 +- 0.04 mg L-1 and 40.31 +- 0.57 mg L-1, respectively, and the dissolved oxygen level had a significant impact on the consortium activity. nh4+-n 103-109 L1 cell adhesion molecule Homo sapiens 196-199 30590208-4 2019 In a bioaugmentation treatment of eutrophic wastewater using the consortium, the removal efficiency of NH4+-N reached 90.85 +- 0.8% and 77.88 +- 1.86% at initial concentrations of 1.80 +- 0.04 mg L-1 and 40.31 +- 0.57 mg L-1, respectively, and the dissolved oxygen level had a significant impact on the consortium activity. nh4+-n 103-109 L1 cell adhesion molecule Homo sapiens 221-224 30412882-6 2019 This study points to excess nutrients in HCMC"s water body with concentrations of NH4+ and PO43- averaging to 0.7 +- 0.6 mgN L-1 and 0.07 +- 0.06 mgP L-1, respectively in mean over the monitored period and rising up to 3 mgN L-1 and 0.2 mgP L-1, in extreme conditions. Water 48-53 L1 cell adhesion molecule Homo sapiens 125-128 30412882-6 2019 This study points to excess nutrients in HCMC"s water body with concentrations of NH4+ and PO43- averaging to 0.7 +- 0.6 mgN L-1 and 0.07 +- 0.06 mgP L-1, respectively in mean over the monitored period and rising up to 3 mgN L-1 and 0.2 mgP L-1, in extreme conditions. Water 48-53 L1 cell adhesion molecule Homo sapiens 150-153 30412882-6 2019 This study points to excess nutrients in HCMC"s water body with concentrations of NH4+ and PO43- averaging to 0.7 +- 0.6 mgN L-1 and 0.07 +- 0.06 mgP L-1, respectively in mean over the monitored period and rising up to 3 mgN L-1 and 0.2 mgP L-1, in extreme conditions. Water 48-53 L1 cell adhesion molecule Homo sapiens 225-244 30446169-9 2019 Remarkable concentrations of the sum of phenols and formaldehyde were detected also at the outflow of the Revelva river into the sea (R12) and were 0.24 mg L-1 in June and 0.35 mg L-1 in September 2016. Phenols 40-47 L1 cell adhesion molecule Homo sapiens 156-159 30446169-9 2019 Remarkable concentrations of the sum of phenols and formaldehyde were detected also at the outflow of the Revelva river into the sea (R12) and were 0.24 mg L-1 in June and 0.35 mg L-1 in September 2016. Phenols 40-47 L1 cell adhesion molecule Homo sapiens 180-183 30446169-9 2019 Remarkable concentrations of the sum of phenols and formaldehyde were detected also at the outflow of the Revelva river into the sea (R12) and were 0.24 mg L-1 in June and 0.35 mg L-1 in September 2016. Formaldehyde 52-64 L1 cell adhesion molecule Homo sapiens 156-159 30446169-9 2019 Remarkable concentrations of the sum of phenols and formaldehyde were detected also at the outflow of the Revelva river into the sea (R12) and were 0.24 mg L-1 in June and 0.35 mg L-1 in September 2016. Formaldehyde 52-64 L1 cell adhesion molecule Homo sapiens 180-183 30373012-5 2019 Under the optimized conditions, the linear range of the single-walled carbon nanohorns film modified electrode for both heavy metal ions varied from 1.0 to 60.0 mug L-1. Carbon 70-76 L1 cell adhesion molecule Homo sapiens 165-168 30373012-5 2019 Under the optimized conditions, the linear range of the single-walled carbon nanohorns film modified electrode for both heavy metal ions varied from 1.0 to 60.0 mug L-1. Metals 126-131 L1 cell adhesion molecule Homo sapiens 165-168 30373012-6 2019 The detection limit of cadmium (II) and lead (II) ions was 0.2 mug L-1 and 0.4 mug L-1. Cadmium 23-30 L1 cell adhesion molecule Homo sapiens 67-70 30373012-6 2019 The detection limit of cadmium (II) and lead (II) ions was 0.2 mug L-1 and 0.4 mug L-1. Cadmium 23-30 L1 cell adhesion molecule Homo sapiens 83-86 30373012-7 2019 Furthermore, the determination of cadmium (II) and lead (II) ions in honey and milk samples illustrates the prepared electrochemical sensor possesses excellent practicability for determining cadmium (II) and lead (II) ions in a low levels (mug L-1). Cadmium 34-41 L1 cell adhesion molecule Homo sapiens 244-247 30373012-7 2019 Furthermore, the determination of cadmium (II) and lead (II) ions in honey and milk samples illustrates the prepared electrochemical sensor possesses excellent practicability for determining cadmium (II) and lead (II) ions in a low levels (mug L-1). lead (ii) 51-60 L1 cell adhesion molecule Homo sapiens 244-247 30373012-7 2019 Furthermore, the determination of cadmium (II) and lead (II) ions in honey and milk samples illustrates the prepared electrochemical sensor possesses excellent practicability for determining cadmium (II) and lead (II) ions in a low levels (mug L-1). Cadmium 191-198 L1 cell adhesion molecule Homo sapiens 244-247 30373012-7 2019 Furthermore, the determination of cadmium (II) and lead (II) ions in honey and milk samples illustrates the prepared electrochemical sensor possesses excellent practicability for determining cadmium (II) and lead (II) ions in a low levels (mug L-1). lead (ii) 208-217 L1 cell adhesion molecule Homo sapiens 244-247 30529415-5 2019 The WWTP system was able to remove from 46% to 95% of the ABZ quantified in the influent, discharging an effluent with 16-441 ng L-1 of ABZ. wwtp 4-8 L1 cell adhesion molecule Homo sapiens 129-132 30529415-5 2019 The WWTP system was able to remove from 46% to 95% of the ABZ quantified in the influent, discharging an effluent with 16-441 ng L-1 of ABZ. Albendazole 136-139 L1 cell adhesion molecule Homo sapiens 129-132 30529415-7 2019 WWTP effluents fortified with 50 mug L-1 of ABZ required 26.7 mgO3 L-1 to remove ABZ and RBZ. Albendazole 44-47 L1 cell adhesion molecule Homo sapiens 37-40 30529415-7 2019 WWTP effluents fortified with 50 mug L-1 of ABZ required 26.7 mgO3 L-1 to remove ABZ and RBZ. Albendazole 44-47 L1 cell adhesion molecule Homo sapiens 67-70 30529415-7 2019 WWTP effluents fortified with 50 mug L-1 of ABZ required 26.7 mgO3 L-1 to remove ABZ and RBZ. mgo3 62-66 L1 cell adhesion molecule Homo sapiens 37-40 30529415-7 2019 WWTP effluents fortified with 50 mug L-1 of ABZ required 26.7 mgO3 L-1 to remove ABZ and RBZ. mgo3 62-66 L1 cell adhesion molecule Homo sapiens 67-70 30529415-7 2019 WWTP effluents fortified with 50 mug L-1 of ABZ required 26.7 mgO3 L-1 to remove ABZ and RBZ. Albendazole 81-84 L1 cell adhesion molecule Homo sapiens 37-40 30529415-7 2019 WWTP effluents fortified with 50 mug L-1 of ABZ required 26.7 mgO3 L-1 to remove ABZ and RBZ. Albendazole 81-84 L1 cell adhesion molecule Homo sapiens 67-70 30529415-7 2019 WWTP effluents fortified with 50 mug L-1 of ABZ required 26.7 mgO3 L-1 to remove ABZ and RBZ. albendazole sulfoxide 89-92 L1 cell adhesion molecule Homo sapiens 37-40 30529415-7 2019 WWTP effluents fortified with 50 mug L-1 of ABZ required 26.7 mgO3 L-1 to remove ABZ and RBZ. albendazole sulfoxide 89-92 L1 cell adhesion molecule Homo sapiens 67-70 30458415-5 2019 A nearly complete removal of Orange II (100 mg L-1) was attained in the MFC-MnFe2O4/PMS under the optimum conditions of 2 mM PMS, 10 mg cm-2 MnFe2O4 loading, pH 7-8 and 480 min reaction time. 2-naphthol orange 29-38 L1 cell adhesion molecule Homo sapiens 47-50 30577117-2 2019 Firstly, sulphides (0.5 g L-1) and sulphites (2.5 g L-1) were catalytic oxidised at natural pH (8.7). Sulfites 35-44 L1 cell adhesion molecule Homo sapiens 52-55 30577117-5 2019 Concentrations of sulphide and sulphite lower than 1.0 mg L-1 (emission limit value - ELV) were obtained after 5-h oxygenation or 1-min peroxidation under the best conditions, i.e. air flow rate of 1 Lair Lleachate-1 min-1 and H2O2:sulphur stoichiometric ratio. Sulfides 18-26 L1 cell adhesion molecule Homo sapiens 58-61 30577117-5 2019 Concentrations of sulphide and sulphite lower than 1.0 mg L-1 (emission limit value - ELV) were obtained after 5-h oxygenation or 1-min peroxidation under the best conditions, i.e. air flow rate of 1 Lair Lleachate-1 min-1 and H2O2:sulphur stoichiometric ratio. Sulfites 31-39 L1 cell adhesion molecule Homo sapiens 58-61 30577117-8 2019 Sulphates (13 g L-1) were removed by chemical precipitation as ettringite or barite applying different reactants contents and pH values. Sulfates 0-9 L1 cell adhesion molecule Homo sapiens 16-19 30577122-6 2019 The median concentrations were <100 ng L-1 and 220 ng g-1 (d.w.) in the water and sediments, respectively. Water 75-80 L1 cell adhesion molecule Homo sapiens 42-60 30633442-2 2019 L1 and L2 comprise pyridyl triazole chelating units with pendant diaminotriazine units, capable of donor-acceptor-donor (DAD) hydrogen bonding, while L3 and L4 contain ADA hydrogen bonding units proximal to N^N and N^O cleating sites, respectively. pyridyl-triazole 19-35 L1 cell adhesion molecule Homo sapiens 0-9 30633442-2 2019 L1 and L2 comprise pyridyl triazole chelating units with pendant diaminotriazine units, capable of donor-acceptor-donor (DAD) hydrogen bonding, while L3 and L4 contain ADA hydrogen bonding units proximal to N^N and N^O cleating sites, respectively. diaminotriazine 65-80 L1 cell adhesion molecule Homo sapiens 0-9 30633442-2 2019 L1 and L2 comprise pyridyl triazole chelating units with pendant diaminotriazine units, capable of donor-acceptor-donor (DAD) hydrogen bonding, while L3 and L4 contain ADA hydrogen bonding units proximal to N^N and N^O cleating sites, respectively. Hydrogen 126-134 L1 cell adhesion molecule Homo sapiens 0-9 30633442-3 2019 X-ray crystallography shows the L1 and L2 containing RuII complexes to assemble via R 2 2 8 hydrogen bonding dimers, while [RuII (bpy)2 L4] assembles via extended hydrogen bonding motifs to form one dimensional chains. Hydrogen 95-103 L1 cell adhesion molecule Homo sapiens 32-41 30633442-6 2019 The L1 and L2 complexes of IrIII and RuII complexes are emissive in the solid state and it seems likely that hydrogen bonding to complementary species may facilitate tuning of their 3 ILCT emission. Hydrogen 109-117 L1 cell adhesion molecule Homo sapiens 4-13 30293000-4 2019 In effluents, 23 CECs were >LOQ with caffeine and the UV-filter 4-hydroxybenzophenone (H-BP) present in the highest concentrations (<49,600 ng L-1 and <28,900 ng L-1, respectively) and most frequently detected (detection frequency; DFr > 83.3%). 4-hydroxybenzophenone 67-88 L1 cell adhesion molecule Homo sapiens 149-152 30293000-4 2019 In effluents, 23 CECs were >LOQ with caffeine and the UV-filter 4-hydroxybenzophenone (H-BP) present in the highest concentrations (<49,600 ng L-1 and <28,900 ng L-1, respectively) and most frequently detected (detection frequency; DFr > 83.3%). 4-hydroxybenzophenone 90-94 L1 cell adhesion molecule Homo sapiens 149-152 30628334-6 2019 The discoloration rate of ARB in the reduction stage was 96.8%, with an Fe0/alginate microsphere dosage of 0.24g L-1 and pH of 2.96 after reaction time of 180 min. fe0/alginate 72-84 L1 cell adhesion molecule Homo sapiens 113-116 30628334-8 2019 In the subsequent Fenton oxidation stage, the mineralization degree of ARB increased to 64.7% after the addition of 10.75 mmol L-1 H2O2. Hydrogen Peroxide 131-135 L1 cell adhesion molecule Homo sapiens 127-130 30443656-5 2019 The limit of detections were found as 0.23 microg L-1 for Cd(II) and 0.13 microg L-1 for Pb(II). cd(ii) 58-64 L1 cell adhesion molecule Homo sapiens 50-53 30388689-3 2019 The results indicated that the optimal condition was 7 mA cm-2 of current density, 10 g L-1 of initial concentration of CH3SNa, 9.0 of pH and 5.0 g L-1 of electrolyte concentration. ch3sna 120-126 L1 cell adhesion molecule Homo sapiens 88-91 30390586-3 2019 In a mixed batch reactor containing 10 mg L-1 Fe2+, 2 g L-1 of catalyst in powder form (1% Pd, 20 mg L-1 of Pd) and an initial pH of 3, chlorobenzene was degraded under 120 mA current following a first-order decay rate showing 96% removal within 60 min. ammonium ferrous sulfate 46-50 L1 cell adhesion molecule Homo sapiens 42-45 30390586-3 2019 In a mixed batch reactor containing 10 mg L-1 Fe2+, 2 g L-1 of catalyst in powder form (1% Pd, 20 mg L-1 of Pd) and an initial pH of 3, chlorobenzene was degraded under 120 mA current following a first-order decay rate showing 96% removal within 60 min. chlorobenzene 136-149 L1 cell adhesion molecule Homo sapiens 42-45 30390586-3 2019 In a mixed batch reactor containing 10 mg L-1 Fe2+, 2 g L-1 of catalyst in powder form (1% Pd, 20 mg L-1 of Pd) and an initial pH of 3, chlorobenzene was degraded under 120 mA current following a first-order decay rate showing 96% removal within 60 min. chlorobenzene 136-149 L1 cell adhesion molecule Homo sapiens 56-59 30390586-3 2019 In a mixed batch reactor containing 10 mg L-1 Fe2+, 2 g L-1 of catalyst in powder form (1% Pd, 20 mg L-1 of Pd) and an initial pH of 3, chlorobenzene was degraded under 120 mA current following a first-order decay rate showing 96% removal within 60 min. chlorobenzene 136-149 L1 cell adhesion molecule Homo sapiens 56-59 30390586-5 2019 In the column experiment with automatic pH adjustment, 71% of chlorobenzene was removed within 120 min with 10 mg L-1 Fe2+, and 2 g L-1 catalyst in pellet form (0.5% Pd, 10 mg L-1 of Pd) under 60 mA. chlorobenzene 62-75 L1 cell adhesion molecule Homo sapiens 114-117 30390586-5 2019 In the column experiment with automatic pH adjustment, 71% of chlorobenzene was removed within 120 min with 10 mg L-1 Fe2+, and 2 g L-1 catalyst in pellet form (0.5% Pd, 10 mg L-1 of Pd) under 60 mA. chlorobenzene 62-75 L1 cell adhesion molecule Homo sapiens 132-135 30390586-5 2019 In the column experiment with automatic pH adjustment, 71% of chlorobenzene was removed within 120 min with 10 mg L-1 Fe2+, and 2 g L-1 catalyst in pellet form (0.5% Pd, 10 mg L-1 of Pd) under 60 mA. chlorobenzene 62-75 L1 cell adhesion molecule Homo sapiens 132-135 30784206-9 2019 [3 H]GMOM (3 nmol L-1 and 10 nmol L-1 ) was inhibited with dual affinity by (+)-MK-801, (R,S)-ketamine and memantine, in both presence and absence of agonists. gmom 5-9 L1 cell adhesion molecule Homo sapiens 18-37 30784206-9 2019 [3 H]GMOM (3 nmol L-1 and 10 nmol L-1 ) was inhibited with dual affinity by (+)-MK-801, (R,S)-ketamine and memantine, in both presence and absence of agonists. Dizocilpine Maleate 76-86 L1 cell adhesion molecule Homo sapiens 18-37 30784206-9 2019 [3 H]GMOM (3 nmol L-1 and 10 nmol L-1 ) was inhibited with dual affinity by (+)-MK-801, (R,S)-ketamine and memantine, in both presence and absence of agonists. (r,s)-ketamine 88-102 L1 cell adhesion molecule Homo sapiens 18-37 30784206-9 2019 [3 H]GMOM (3 nmol L-1 and 10 nmol L-1 ) was inhibited with dual affinity by (+)-MK-801, (R,S)-ketamine and memantine, in both presence and absence of agonists. Memantine 107-116 L1 cell adhesion molecule Homo sapiens 18-37 30176470-7 2019 Humic acids (HA) played a double role as photosensitizer and inhibitor, observing an enhancement on DDVP photodegradation at low HA concentration (TOC = 2 mg L-1). Humic Substances 0-11 L1 cell adhesion molecule Homo sapiens 158-161 30009400-3 2019 Sulforaphane was efficiently encapsulated with beta-CD at just 3 mmol L-1 , and the sulforaphane formed was stable during 3 h at 22 C. On the other hand, 40 mmol L-1 alpha-CD retained a high glucoraphanin content in broccoli juice. sulforaphane 0-12 L1 cell adhesion molecule Homo sapiens 70-73 30009400-3 2019 Sulforaphane was efficiently encapsulated with beta-CD at just 3 mmol L-1 , and the sulforaphane formed was stable during 3 h at 22 C. On the other hand, 40 mmol L-1 alpha-CD retained a high glucoraphanin content in broccoli juice. sulforaphane 0-12 L1 cell adhesion molecule Homo sapiens 163-166 30009400-3 2019 Sulforaphane was efficiently encapsulated with beta-CD at just 3 mmol L-1 , and the sulforaphane formed was stable during 3 h at 22 C. On the other hand, 40 mmol L-1 alpha-CD retained a high glucoraphanin content in broccoli juice. alpha-cyclodextrin 167-175 L1 cell adhesion molecule Homo sapiens 163-166 30009400-3 2019 Sulforaphane was efficiently encapsulated with beta-CD at just 3 mmol L-1 , and the sulforaphane formed was stable during 3 h at 22 C. On the other hand, 40 mmol L-1 alpha-CD retained a high glucoraphanin content in broccoli juice. glucoraphanin 192-205 L1 cell adhesion molecule Homo sapiens 163-166 30565421-3 2019 Furthermore, the floating system exhibits an excellent photodegradation of tetracycline (TC; 40 mg L-1 ). Tetracycline 75-87 L1 cell adhesion molecule Homo sapiens 99-102 30565421-3 2019 Furthermore, the floating system exhibits an excellent photodegradation of tetracycline (TC; 40 mg L-1 ). Tetracycline 89-91 L1 cell adhesion molecule Homo sapiens 99-102 30740291-1 2019 A series of ionic (mono-/di-)phosphines (L2, L4, and L6) with structural similarity and their corresponding neutral counterparts (L1, L3, and L5) were applied to modulate the catalytic performance of RuCl3 3H2O. rucl3 3h2o 200-212 L1 cell adhesion molecule Homo sapiens 130-144 30199716-7 2019 The proposed method was also proved with certified water sample containing 60 mug L-1 Pb2+ giving an excellent accuracy and was then implied satisfactorily for ultra-trace determination of Pb2+ in drinking water and tap water samples. Water 51-56 L1 cell adhesion molecule Homo sapiens 82-85 31459392-2 2019 This paper deals with the design and development of a glucosyl conjugate of pyrene (L 1 ) along with control molecular systems, possessing anthracenyl (L 2 ), naphtyl (L 3 ), and phenyl (L 4 ) moieties, via Knoevenagel condensation of 2,4-pentanedione with d-glucose. pyrene 76-82 L1 cell adhesion molecule Homo sapiens 84-87 31459392-2 2019 This paper deals with the design and development of a glucosyl conjugate of pyrene (L 1 ) along with control molecular systems, possessing anthracenyl (L 2 ), naphtyl (L 3 ), and phenyl (L 4 ) moieties, via Knoevenagel condensation of 2,4-pentanedione with d-glucose. anthracenyl 139-150 L1 cell adhesion molecule Homo sapiens 84-87 31459392-3 2019 The selectivity of L 1 toward PA has been demonstrated on the basis of fluorescence and absorption spectroscopy, and the species of recognition by electrospray ionization mass spectrometry. picric acid 30-32 L1 cell adhesion molecule Homo sapiens 19-22 31459392-6 2019 L 1 was demonstrated to detect PA in solid state selectively over other nitroaromatic compounds (NACs). picric acid 31-33 L1 cell adhesion molecule Homo sapiens 0-3 31459392-6 2019 L 1 was demonstrated to detect PA in solid state selectively over other nitroaromatic compounds (NACs). nitroaromatic 72-85 L1 cell adhesion molecule Homo sapiens 0-3 31459392-6 2019 L 1 was demonstrated to detect PA in solid state selectively over other nitroaromatic compounds (NACs). nacs 97-101 L1 cell adhesion molecule Homo sapiens 0-3 31459392-7 2019 To study the utility of L 1 in film, cellulose paper strips coated with L 1 were used and demonstrated the selective detection of PA. picric acid 130-132 L1 cell adhesion molecule Homo sapiens 24-27 31459392-7 2019 To study the utility of L 1 in film, cellulose paper strips coated with L 1 were used and demonstrated the selective detection of PA. picric acid 130-132 L1 cell adhesion molecule Homo sapiens 72-75 31459392-9 2019 Thus, L 1 was demonstrated as a sensitive, selective, and inexpensive probe for PA over several NACs by visual, spectral, and microscopy methods. picric acid 80-82 L1 cell adhesion molecule Homo sapiens 6-9 31459392-9 2019 Thus, L 1 was demonstrated as a sensitive, selective, and inexpensive probe for PA over several NACs by visual, spectral, and microscopy methods. nacs 96-100 L1 cell adhesion molecule Homo sapiens 6-9 30482430-10 2019 The successful application of the fully validated method shows that, on average, the asthmatic patients had significantly higher concentrations of 11betaPGF2alpha (112.96 mug L-1vs 62.56 mug L-1 in normal controls), LTE4 (1.27 mug L-1vs 0.89 mug L-1 in normal controls), and LTB4 (1.39 mug L-1vs 0.76 mug L-1 in normal controls). 11betapgf2alpha 147-162 L1 cell adhesion molecule Homo sapiens 175-178 30482430-10 2019 The successful application of the fully validated method shows that, on average, the asthmatic patients had significantly higher concentrations of 11betaPGF2alpha (112.96 mug L-1vs 62.56 mug L-1 in normal controls), LTE4 (1.27 mug L-1vs 0.89 mug L-1 in normal controls), and LTB4 (1.39 mug L-1vs 0.76 mug L-1 in normal controls). 11betapgf2alpha 147-162 L1 cell adhesion molecule Homo sapiens 191-194 30482430-10 2019 The successful application of the fully validated method shows that, on average, the asthmatic patients had significantly higher concentrations of 11betaPGF2alpha (112.96 mug L-1vs 62.56 mug L-1 in normal controls), LTE4 (1.27 mug L-1vs 0.89 mug L-1 in normal controls), and LTB4 (1.39 mug L-1vs 0.76 mug L-1 in normal controls). 11betapgf2alpha 147-162 L1 cell adhesion molecule Homo sapiens 191-194 30482288-6 2019 The N, S-PC based sensor shows excellent sensitivity and selectivity for Cd(II) versus other metals, with a low detection limit of 0.1 mug L-1 (S/N = 3) over a wide concentration range of 4-80 mug L-1. cd(ii) 73-79 L1 cell adhesion molecule Homo sapiens 139-142 30482288-6 2019 The N, S-PC based sensor shows excellent sensitivity and selectivity for Cd(II) versus other metals, with a low detection limit of 0.1 mug L-1 (S/N = 3) over a wide concentration range of 4-80 mug L-1. cd(ii) 73-79 L1 cell adhesion molecule Homo sapiens 197-200 30180321-2 2019 In particular, nitrate concentrations exceeding the 50 mg L-1 limit established for drinking water pose the human health at risk. Nitrates 15-22 L1 cell adhesion molecule Homo sapiens 58-61 30180321-2 2019 In particular, nitrate concentrations exceeding the 50 mg L-1 limit established for drinking water pose the human health at risk. Water 93-98 L1 cell adhesion molecule Homo sapiens 58-61 30180321-12 2019 Nitrate was not homogeneously distributed in groundwater, being observed a large range of concentrations, from <1 up to 162 mg L-1. Nitrates 0-7 L1 cell adhesion molecule Homo sapiens 130-133 30628310-7 2019 The results show that, among the six different digestion methods, KOH digestion (100 g L-1, 60C) has the least influence on the fluorescence intensity of the microplastics and does not affect their surface morphology. potassium hydroxide 66-69 L1 cell adhesion molecule Homo sapiens 87-95 30179785-7 2019 The results showed that AO could be completely removed after 90 min electrolysis under the optimal condition: initial AO concentration was 30 mg L-1, current density was 50 mA cm-2, and the initial pH value was 5.0. Acridine Orange 24-26 L1 cell adhesion molecule Homo sapiens 145-148 30179785-7 2019 The results showed that AO could be completely removed after 90 min electrolysis under the optimal condition: initial AO concentration was 30 mg L-1, current density was 50 mA cm-2, and the initial pH value was 5.0. Acridine Orange 118-120 L1 cell adhesion molecule Homo sapiens 145-148 30458415-5 2019 A nearly complete removal of Orange II (100 mg L-1) was attained in the MFC-MnFe2O4/PMS under the optimum conditions of 2 mM PMS, 10 mg cm-2 MnFe2O4 loading, pH 7-8 and 480 min reaction time. manganese ferrite 76-83 L1 cell adhesion molecule Homo sapiens 47-50 30458415-5 2019 A nearly complete removal of Orange II (100 mg L-1) was attained in the MFC-MnFe2O4/PMS under the optimum conditions of 2 mM PMS, 10 mg cm-2 MnFe2O4 loading, pH 7-8 and 480 min reaction time. peroxymonosulfate 84-87 L1 cell adhesion molecule Homo sapiens 47-50 30059929-4 2019 Cd concentration in river water declined from its source at a tailings dam (304 mug L-1) to a point 14 km downstream (0.32 mug L-1). Cadmium 0-2 L1 cell adhesion molecule Homo sapiens 84-87 31459513-7 2019 At the optimum conditions (contact time: 85 min, pH: 6, adsorbent dose: 10 mg/20 mL, and initial Ni(II) concentration: 20 mg L-1), high removal efficiency (99.35%) was achieved, which is reasonably well predicted by the quadratic model. Nickel(2+) 97-103 L1 cell adhesion molecule Homo sapiens 125-128 31334042-9 2019 The limits of quantification of 3-heptanone and VPA were 0.04 mg L-1 and 0.2 mg L-1, respectively. ethyl-n-butyl ketone 32-43 L1 cell adhesion molecule Homo sapiens 65-76 31334042-9 2019 The limits of quantification of 3-heptanone and VPA were 0.04 mg L-1 and 0.2 mg L-1, respectively. Valproic Acid 48-51 L1 cell adhesion molecule Homo sapiens 65-76 30873897-4 2019 The results showed that for UW-BOS contents below 30 mg L-1, SDZ removal proceeds at pH 5 with similar rates for both CVT230 and FORSUD, regardless of Fe(III) concentration. Sulfadiazine 61-64 L1 cell adhesion molecule Homo sapiens 56-59 30873897-6 2019 In contrast, half-life times of 35-40 min can only be achieved under mildly acidic conditions with FORSUD for iron concentrations higher than 10 mg L-1. Iron 110-114 L1 cell adhesion molecule Homo sapiens 148-151 30544127-6 2019 In addition, isofraxidin is a time-dependent inhibitor for CYP3A4 with Kinact/KI value of 0.047/12.33 micromol/L-1min-1. isofraxidin 13-24 L1 cell adhesion molecule Homo sapiens 111-119 30059929-4 2019 Cd concentration in river water declined from its source at a tailings dam (304 mug L-1) to a point 14 km downstream (0.32 mug L-1). Cadmium 0-2 L1 cell adhesion molecule Homo sapiens 127-130 30025239-5 2018 Dissolved N2 in the river water ranged from 337 to 513 mumol N2 L-1, and dissolved N2O ranged from 10.4 to 15.4 nmol N2O L-1. Nitrogen 10-12 L1 cell adhesion molecule Homo sapiens 64-67 31587003-7 2019 In addition, cynaroside is a time-dependent inhibitor for CYP3A4 with Kinact/KI value of 0.049/11.62 mumol/L-1min-1. luteolin-7-glucoside 13-23 L1 cell adhesion molecule Homo sapiens 107-115 30280437-6 2018 RESULTS: When compared with direct analyte signal measurements, application of IS yielded enhanced analytical performance using either UC or PLS2; the method quantification limits were: 11.1 mug L-1 , 23.4 mug L-1 for Cu and 89.8 mug L-1 , 97.1 mug L-1 for Pb, respectively. Copper 218-220 L1 cell adhesion molecule Homo sapiens 210-213 30280437-6 2018 RESULTS: When compared with direct analyte signal measurements, application of IS yielded enhanced analytical performance using either UC or PLS2; the method quantification limits were: 11.1 mug L-1 , 23.4 mug L-1 for Cu and 89.8 mug L-1 , 97.1 mug L-1 for Pb, respectively. Copper 218-220 L1 cell adhesion molecule Homo sapiens 210-213 30280437-6 2018 RESULTS: When compared with direct analyte signal measurements, application of IS yielded enhanced analytical performance using either UC or PLS2; the method quantification limits were: 11.1 mug L-1 , 23.4 mug L-1 for Cu and 89.8 mug L-1 , 97.1 mug L-1 for Pb, respectively. Copper 218-220 L1 cell adhesion molecule Homo sapiens 210-213 30325090-1 2018 Ligands L1 and L2 have been designed, synthesized, and used to build for the first time bispidine-based coordination polymers (CPs) in combination with MnII . bispidine-based coordination polymers 88-125 L1 cell adhesion molecule Homo sapiens 8-17 30325090-1 2018 Ligands L1 and L2 have been designed, synthesized, and used to build for the first time bispidine-based coordination polymers (CPs) in combination with MnII . cps 127-130 L1 cell adhesion molecule Homo sapiens 8-17 30474969-3 2018 Fluvial concentrations of THg and MeHg downstream of RTSs on the Peel Plateau (Northwest Territories, Canada) were up to 2 orders of magnitude higher than upstream, reaching concentrations of 1,270 ng L-1 and 7 ng L-1, respectively, the highest ever measured in uncontaminated sites in Canada. Thioguanine 26-29 L1 cell adhesion molecule Homo sapiens 201-217 30243074-5 2018 The results showed that the addition of Na2SO4 electrolyte, MG concentration of 40 mg L-1 and solution pH of 5.2 improved the short circuit current density (Jsc) and power density (Pmax) in the as-constructed PFC. Methyl Green 60-62 L1 cell adhesion molecule Homo sapiens 86-89 30426735-7 2018 An application of the exfoliated van der Waals strings is presented for optical biosensing using photoluminescence of Bi2S3 nanoribbons, reaching detection limits of less than 10 nM L-1 in response to bovine serum albumin. Bismuth sulfide (Bi2S3) 118-123 L1 cell adhesion molecule Homo sapiens 182-185 30557309-13 2018 L1CAM was positive in 8/47 (17%) cases, all of them positive for LVSI and within the high-risk category of ESMO-ESGO-ESTRO. esmo-esgo-estro 107-122 L1 cell adhesion molecule Homo sapiens 0-5 30628390-3 2018 Based on the analysis of distribution patterns and sediment profiles of mercury in DH1, DH2, DH3, and DH4 during the wet and dry seasons in the Dahong Lake Reservoir, the total mercury concentration of the Dahong Lake Reservoir increases significantly during the wet season (the average of the wet season is 4.33 ng L-1, the average of the dry season is 1.85 ng L-1), especially in the downstream. Mercury 177-184 L1 cell adhesion molecule Homo sapiens 316-319 30628390-3 2018 Based on the analysis of distribution patterns and sediment profiles of mercury in DH1, DH2, DH3, and DH4 during the wet and dry seasons in the Dahong Lake Reservoir, the total mercury concentration of the Dahong Lake Reservoir increases significantly during the wet season (the average of the wet season is 4.33 ng L-1, the average of the dry season is 1.85 ng L-1), especially in the downstream. Mercury 177-184 L1 cell adhesion molecule Homo sapiens 362-365 29763971-9 2018 The [NaF 12 g L-1 + NaCl 1 g L-1 ] solution, and its NiTi-containing product had lower cytotoxicity than NaOCl at dilutions of 25% and 50% (P < 0.01). Sodium Fluoride 5-8 L1 cell adhesion molecule Homo sapiens 14-33 30025239-5 2018 Dissolved N2 in the river water ranged from 337 to 513 mumol N2 L-1, and dissolved N2O ranged from 10.4 to 15.4 nmol N2O L-1. Nitrous Oxide 83-86 L1 cell adhesion molecule Homo sapiens 121-124 30618636-0 2018 ROCK Inhibitor Y27632 Induced Morphological Shift and Enhanced Neurite Outgrowth-Promoting Property of Olfactory Ensheathing Cells via YAP-Dependent Up-Regulation of L1-CAM. Y 27632 15-21 L1 cell adhesion molecule Homo sapiens 166-172 30224129-7 2018 Water samples from city tap water and three rivers in Beijing are assessed using this technique, and the typical T&O compositions are observed with concentrations ranging from 0.2 to 297 ng L-1. Water 0-5 L1 cell adhesion molecule Homo sapiens 194-197 30224129-7 2018 Water samples from city tap water and three rivers in Beijing are assessed using this technique, and the typical T&O compositions are observed with concentrations ranging from 0.2 to 297 ng L-1. t& 113-118 L1 cell adhesion molecule Homo sapiens 194-197 30149253-4 2018 At perchlorate of 194 mg/L, acetate of 28.8 mg/L and hydraulic retention time of 0.9 h, the Half-order reaction rate constant and the sulfate production of SFSBR were 29.7 mg1/2/L1/2 h and 171 mg/L, respectively, which were superior to those of UFSBR. Sulfates 134-141 L1 cell adhesion molecule Homo sapiens 178-192 30167787-5 2018 In addition, the condition that provided the best 1,3-PD yield was applied to an anaerobic fluidized bed reactor fed with crude glycerol (26.0 g L-1), which was monitored as the hydraulic retention time (HRT) decreased from 36 to 12 h. The greatest 1,3-PD yield, of 0.31 g g-1 glycerol, was obtained with an HRT of 28 h. 1,3-pd 50-56 L1 cell adhesion molecule Homo sapiens 145-148 30167787-5 2018 In addition, the condition that provided the best 1,3-PD yield was applied to an anaerobic fluidized bed reactor fed with crude glycerol (26.0 g L-1), which was monitored as the hydraulic retention time (HRT) decreased from 36 to 12 h. The greatest 1,3-PD yield, of 0.31 g g-1 glycerol, was obtained with an HRT of 28 h. Glycerol 128-136 L1 cell adhesion molecule Homo sapiens 145-148 30176519-2 2018 For this purpose, addition of 0.25 g L-1 of NaNO3 allowed Spirulina to accumulate up to 49.3% (w w-1) of carbohydrates with the highest amount of CO2 (0.3 vvm injected for 5 min). Carbohydrates 105-118 L1 cell adhesion molecule Homo sapiens 37-49 30176519-2 2018 For this purpose, addition of 0.25 g L-1 of NaNO3 allowed Spirulina to accumulate up to 49.3% (w w-1) of carbohydrates with the highest amount of CO2 (0.3 vvm injected for 5 min). N2,N6-bis(4-(2-aminoethoxy)quinolin-2-yl)-4-((4-fluorobenzyl)oxy)pyridine-2,6-dicarboxamide 146-149 L1 cell adhesion molecule Homo sapiens 37-49 30098016-13 2018 Pneumococcal vaccination should be systematically recommended, and prophylaxis with co-trimoxazole and valaciclovir when the CD4 count is < 0 2 x 109 cells L-1 . Valacyclovir 103-115 L1 cell adhesion molecule Homo sapiens 159-162 30195167-6 2018 The low levels of NDPhA were detected in the two of twelve wastewater samples with concentrations of 5.6 ng L-1 and 3.6 ng L-1 with RSDs of 5.6% and 2.8%, respectively. N-nitrosodiphenylamine 18-23 L1 cell adhesion molecule Homo sapiens 108-111 30195167-6 2018 The low levels of NDPhA were detected in the two of twelve wastewater samples with concentrations of 5.6 ng L-1 and 3.6 ng L-1 with RSDs of 5.6% and 2.8%, respectively. N-nitrosodiphenylamine 18-23 L1 cell adhesion molecule Homo sapiens 123-126 30195167-6 2018 The low levels of NDPhA were detected in the two of twelve wastewater samples with concentrations of 5.6 ng L-1 and 3.6 ng L-1 with RSDs of 5.6% and 2.8%, respectively. rsds 132-136 L1 cell adhesion molecule Homo sapiens 123-126 30746067-5 2018 For A549 cells, L 1 (1.85 muM) and L 2 (4.37 muM) had higher anti-A549 activity than L 0 ; in particular, the IC50 value of L 1 was much lower than that of DOX. Doxorubicin 156-159 L1 cell adhesion molecule Homo sapiens 16-19 29034425-4 2018 Under the optimum operating conditions (T = 90 C; [Fe3+]0 = 50 mg L-1; [H2O2]0 = 100% of the stoichiometric amount), the complete removal of [C4mim]Cl (1000 mg L-1) was achieved at 1.5-min reaction time. c4mim]cl 143-151 L1 cell adhesion molecule Homo sapiens 161-164 30628230-3 2018 The experimental results showed that at an aerobic aeration rate of 0.8 L min-1 and aerobic duration time of 150 min, the effluent PO43--P concentration was about 1.5 mg L-1, with the effluent NH4+-N and NO3--N concentrations gradually decreasing from 10.28 and 8.14 mg L-1 to 0 and 2.27 mg L-1, respectively, and effluent NO2--N concentration increasing to 1.81 mg L-1. po43--p 131-138 L1 cell adhesion molecule Homo sapiens 270-284 30071432-6 2018 Cyclic voltammogram and electrochemical impedance spectroscopy revealed that high concentration of Cd2+ exceeding 5 mg L-1 can inhibit the secretion of outer membrane cytochromes, thus reducing the electron transfer between the EABs and the anode surface. eabs 228-232 L1 cell adhesion molecule Homo sapiens 119-122 30071432-7 2018 Analysis of bacterial structures showed a decrease in Geobacter accompanied by an increase in Stenotrophomonas and Azospira in response to Cd2+ at 10 and 20 mg L-1. azospira 115-123 L1 cell adhesion molecule Homo sapiens 160-163 30071434-4 2018 The results indicated that 100 mg L-1 PbBiFeO3 with 0.5 wt% rGO exhibited the highest degradation efficiency for 50 mg L-1 PFOA at pH = 2.0 from aqueous solution. pbbifeo3 38-46 L1 cell adhesion molecule Homo sapiens 34-37 30071434-4 2018 The results indicated that 100 mg L-1 PbBiFeO3 with 0.5 wt% rGO exhibited the highest degradation efficiency for 50 mg L-1 PFOA at pH = 2.0 from aqueous solution. pbbifeo3 38-46 L1 cell adhesion molecule Homo sapiens 119-122 30071434-4 2018 The results indicated that 100 mg L-1 PbBiFeO3 with 0.5 wt% rGO exhibited the highest degradation efficiency for 50 mg L-1 PFOA at pH = 2.0 from aqueous solution. perfluorooctanoic acid 123-127 L1 cell adhesion molecule Homo sapiens 34-37 30071434-4 2018 The results indicated that 100 mg L-1 PbBiFeO3 with 0.5 wt% rGO exhibited the highest degradation efficiency for 50 mg L-1 PFOA at pH = 2.0 from aqueous solution. perfluorooctanoic acid 123-127 L1 cell adhesion molecule Homo sapiens 119-122 30071434-5 2018 The removal rate of PFOA reached 69.6% after 8 h UV irradiation under the optimal conditions (PFOA concentration of 50 mg L-1, Pb BiFeO3/0.5% rGO concentration of 100 mg L-1, and pH of 2.0). perfluorooctanoic acid 20-24 L1 cell adhesion molecule Homo sapiens 122-125 30071434-5 2018 The removal rate of PFOA reached 69.6% after 8 h UV irradiation under the optimal conditions (PFOA concentration of 50 mg L-1, Pb BiFeO3/0.5% rGO concentration of 100 mg L-1, and pH of 2.0). perfluorooctanoic acid 20-24 L1 cell adhesion molecule Homo sapiens 170-173 30071434-5 2018 The removal rate of PFOA reached 69.6% after 8 h UV irradiation under the optimal conditions (PFOA concentration of 50 mg L-1, Pb BiFeO3/0.5% rGO concentration of 100 mg L-1, and pH of 2.0). perfluorooctanoic acid 94-98 L1 cell adhesion molecule Homo sapiens 122-125 28825349-5 2018 BPA with initial concentration of 20 mg L-1 was completely removed within 30 min and the total organic carbon removal reached 44.60%. bisphenol A 0-3 L1 cell adhesion molecule Homo sapiens 40-43 29859427-5 2018 CaCl2 was used as a source of cation bridge to enhance the flocculation of kaolin particles, and its optimum dosage was 150 mg L-1. Calcium Chloride 0-5 L1 cell adhesion molecule Homo sapiens 127-130 29859427-6 2018 At dosage of 30 mg L-1 and pH of 5.0, the turbidity removal efficiency of CS-g-P(AM-IA) reached the maximum of 93.8%, whereas those of CS-g-PAM and CS were 96.7% and 76.9%, respectively. cs-g-p 74-80 L1 cell adhesion molecule Homo sapiens 19-22 29859427-6 2018 At dosage of 30 mg L-1 and pH of 5.0, the turbidity removal efficiency of CS-g-P(AM-IA) reached the maximum of 93.8%, whereas those of CS-g-PAM and CS were 96.7% and 76.9%, respectively. cs-g-pam 135-143 L1 cell adhesion molecule Homo sapiens 19-22 29859427-6 2018 At dosage of 30 mg L-1 and pH of 5.0, the turbidity removal efficiency of CS-g-P(AM-IA) reached the maximum of 93.8%, whereas those of CS-g-PAM and CS were 96.7% and 76.9%, respectively. Cesium 74-76 L1 cell adhesion molecule Homo sapiens 19-22 30086909-6 2018 A detection limit (3sigma criterion) of 3 ng L-1 Hg was achieved, which is far below the guideline value of Hg in drinking water set by WHO, viz., 1 mug L-1. Drinking Water 114-128 L1 cell adhesion molecule Homo sapiens 45-48 30280728-5 2018 Under the optimal conditions, the linear range and limit of detection for H2O2 sensitive detection were 5.0 x 10-8 mol L-1-1.0 x 10-3 mol L-1 and 4.8 x 10-9 mol L-1, respectively. Hydrogen Peroxide 74-78 L1 cell adhesion molecule Homo sapiens 138-156 30362034-3 2018 The results showed that metal concentrations in sediments (4.05-7.14, 16.68-18.13, 164-213 mg kg-1 for Cd, Pb, and Zn, respectively) and water samples (0.16-0.44, 0.15-0.26, and 0.32-0.48 mg L-1 for Cd, Pb, and Zn, respectively) were below the threshold effects concentration of the sediment quality guidelines for adverse effects to occur and the marine water quality standards of Thailand. Metals 24-29 L1 cell adhesion molecule Homo sapiens 191-194 30055442-3 2018 The pollutants of MO (10 mg L-1) and phenol (45 mg L-1) could be efficiently degraded by m-Bi2O4/NCDs within 30 and 120 min, respectively, which is much better than that of the single m-Bi2O4, indicating that the introduction of NCDs into m-Bi2O4 can effectively improve the photocatalytic activity. Phenol 37-43 L1 cell adhesion molecule Homo sapiens 51-54 30055442-3 2018 The pollutants of MO (10 mg L-1) and phenol (45 mg L-1) could be efficiently degraded by m-Bi2O4/NCDs within 30 and 120 min, respectively, which is much better than that of the single m-Bi2O4, indicating that the introduction of NCDs into m-Bi2O4 can effectively improve the photocatalytic activity. m-bi2o4 89-96 L1 cell adhesion molecule Homo sapiens 28-31 30055442-3 2018 The pollutants of MO (10 mg L-1) and phenol (45 mg L-1) could be efficiently degraded by m-Bi2O4/NCDs within 30 and 120 min, respectively, which is much better than that of the single m-Bi2O4, indicating that the introduction of NCDs into m-Bi2O4 can effectively improve the photocatalytic activity. m-bi2o4 89-96 L1 cell adhesion molecule Homo sapiens 51-54 30055442-3 2018 The pollutants of MO (10 mg L-1) and phenol (45 mg L-1) could be efficiently degraded by m-Bi2O4/NCDs within 30 and 120 min, respectively, which is much better than that of the single m-Bi2O4, indicating that the introduction of NCDs into m-Bi2O4 can effectively improve the photocatalytic activity. Bismuth tetraoxide 91-96 L1 cell adhesion molecule Homo sapiens 28-31 30055442-3 2018 The pollutants of MO (10 mg L-1) and phenol (45 mg L-1) could be efficiently degraded by m-Bi2O4/NCDs within 30 and 120 min, respectively, which is much better than that of the single m-Bi2O4, indicating that the introduction of NCDs into m-Bi2O4 can effectively improve the photocatalytic activity. Bismuth tetraoxide 91-96 L1 cell adhesion molecule Homo sapiens 51-54 30055442-3 2018 The pollutants of MO (10 mg L-1) and phenol (45 mg L-1) could be efficiently degraded by m-Bi2O4/NCDs within 30 and 120 min, respectively, which is much better than that of the single m-Bi2O4, indicating that the introduction of NCDs into m-Bi2O4 can effectively improve the photocatalytic activity. m-bi2o4 184-191 L1 cell adhesion molecule Homo sapiens 28-31 30055442-3 2018 The pollutants of MO (10 mg L-1) and phenol (45 mg L-1) could be efficiently degraded by m-Bi2O4/NCDs within 30 and 120 min, respectively, which is much better than that of the single m-Bi2O4, indicating that the introduction of NCDs into m-Bi2O4 can effectively improve the photocatalytic activity. m-bi2o4 184-191 L1 cell adhesion molecule Homo sapiens 51-54 30335954-4 2018 As the electrode, GF@N-C exhibits a superior rate constant and catalytic efficiency at 370 mA cm-2 and enables the vanadium redox flow battery to operate steadily at 200 mA cm-2 with an energy efficiency of 74.3% and a discharge specific capacity of 23 A h L-1. Vanadium 115-123 L1 cell adhesion molecule Homo sapiens 257-260 30230322-3 2018 In comparison, the pyrite oxidation rate at circumneutral pH (7.4 +- 0.4) decreased with increasing added Al3+ with 98% reduction in long-term (282 days) dissolution rates in the presence of 20 mg L-1 Al3+. pyrite 19-25 L1 cell adhesion molecule Homo sapiens 198-201 30746067-1 2018 To seek more efficient and lower toxicity anticancer compounds, several imidazole combining dehydroabietylamine derivatives including organic salts (L 1 -L 2 ) and amides (L 3 -L 5 ) were synthesized. imidazole 72-81 L1 cell adhesion molecule Homo sapiens 149-152 30239192-5 2018 As far as the quantification of phospholipids, acceptable linearity ( R2 >= 0.9985) and relative standard deviations (RSDs <= 8.9%) were obtained within the range of 0.1-500 mug L-1 for LysoPC(14:0) and LysoPC(16:0) in raw urine samples. Phospholipids 32-45 L1 cell adhesion molecule Homo sapiens 184-187 30239192-6 2018 Limit of detection (LOD) <= 0.025 mug L-1 and recovery rates of 94.8-101.6% were obtained for these phospholipids. Phospholipids 103-116 L1 cell adhesion molecule Homo sapiens 41-44 30280885-2 2018 The limit of detection was 0.42 pg L-1 226Ra (15 mBq L-1, 0.42 pCi L-1), which is compliant with the specifications for methods used for routine analysis of drinking water quality according to European and U.S. regulations. Drinking Water 157-171 L1 cell adhesion molecule Homo sapiens 35-38 30280885-4 2018 Water samples with high total dissolved solids (conductivity >100 mS cm-1) were also successfully analyzed after a simple dilution, yet the associated detection limit was higher (17 pg L-1, 0.61 Bq L-1, 16 pCi L-1). Water 0-5 L1 cell adhesion molecule Homo sapiens 188-191 30280885-4 2018 Water samples with high total dissolved solids (conductivity >100 mS cm-1) were also successfully analyzed after a simple dilution, yet the associated detection limit was higher (17 pg L-1, 0.61 Bq L-1, 16 pCi L-1). Water 0-5 L1 cell adhesion molecule Homo sapiens 201-204 30280885-4 2018 Water samples with high total dissolved solids (conductivity >100 mS cm-1) were also successfully analyzed after a simple dilution, yet the associated detection limit was higher (17 pg L-1, 0.61 Bq L-1, 16 pCi L-1). Water 0-5 L1 cell adhesion molecule Homo sapiens 201-204 30230322-3 2018 In comparison, the pyrite oxidation rate at circumneutral pH (7.4 +- 0.4) decreased with increasing added Al3+ with 98% reduction in long-term (282 days) dissolution rates in the presence of 20 mg L-1 Al3+. ALUMINUM ION 106-110 L1 cell adhesion molecule Homo sapiens 198-201 30230322-3 2018 In comparison, the pyrite oxidation rate at circumneutral pH (7.4 +- 0.4) decreased with increasing added Al3+ with 98% reduction in long-term (282 days) dissolution rates in the presence of 20 mg L-1 Al3+. ALUMINUM ION 202-206 L1 cell adhesion molecule Homo sapiens 198-201 30230322-4 2018 Al3+ was added to the solution and allowed to equilibrate prior to pyrite addition (2 g L-1). ALUMINUM ION 0-4 L1 cell adhesion molecule Homo sapiens 88-91 30230322-7 2018 %) on the pyrite surface reacted at pH 7.4 with 20 mg L-1 added Al3+, but no Al3+ on pyrite surfaces reacted at pH 2.0 and 4.0 with added Al3+. pyrite 10-16 L1 cell adhesion molecule Homo sapiens 54-57 30066492-10 2018 Particularly, we found a low energy consumption (1.63 Wh L-1 ) for seawater desalination and a high water production rate (25 L m-2 h-1 ) for brackish water. Water 70-75 L1 cell adhesion molecule Homo sapiens 57-60 30402102-5 2018 The detection limits were of 11.0 mug L-1 for Cd(II) and 11.5 mug L-1 for Pb(II), confirming that proposed method is attractive and suitable for heavy metals determination. cd(ii) 46-52 L1 cell adhesion molecule Homo sapiens 38-41 30014919-5 2018 Process parameters influence on CWPO of phenol were evaluated and a maximum removal of phenol and TOC was observed at pH 3 and 60 C, using 3 g L-1 of the catalyst containing 5.6% of iron and 11.8 mmol L-1 of H2O2. Phenol 40-46 L1 cell adhesion molecule Homo sapiens 144-147 30014919-5 2018 Process parameters influence on CWPO of phenol were evaluated and a maximum removal of phenol and TOC was observed at pH 3 and 60 C, using 3 g L-1 of the catalyst containing 5.6% of iron and 11.8 mmol L-1 of H2O2. Phenol 40-46 L1 cell adhesion molecule Homo sapiens 202-205 30014919-5 2018 Process parameters influence on CWPO of phenol were evaluated and a maximum removal of phenol and TOC was observed at pH 3 and 60 C, using 3 g L-1 of the catalyst containing 5.6% of iron and 11.8 mmol L-1 of H2O2. Phenol 87-93 L1 cell adhesion molecule Homo sapiens 144-147 30014919-5 2018 Process parameters influence on CWPO of phenol were evaluated and a maximum removal of phenol and TOC was observed at pH 3 and 60 C, using 3 g L-1 of the catalyst containing 5.6% of iron and 11.8 mmol L-1 of H2O2. Phenol 87-93 L1 cell adhesion molecule Homo sapiens 202-205 30014919-5 2018 Process parameters influence on CWPO of phenol were evaluated and a maximum removal of phenol and TOC was observed at pH 3 and 60 C, using 3 g L-1 of the catalyst containing 5.6% of iron and 11.8 mmol L-1 of H2O2. Hydrogen Peroxide 209-213 L1 cell adhesion molecule Homo sapiens 202-205 30014919-8 2018 The degradation process achieved 98.2% of phenol conversion, 68.2% of mineralization and 2.11 mg L-1 of iron leaching in 150 min of reaction. Iron 104-108 L1 cell adhesion molecule Homo sapiens 97-100 30077462-5 2018 The developed method provided a wide linear range from 0.005 to 500 mug L-1 for dibutyl phthalate, 0.01 to 500 mug L-1 for diethyl phthalate, benzylbutyl phthalate and bis(2-ethylhexyl) phthalate, and 0.02 to 500 mug L-1 for dimethyl phthalate and di-n-octyl phthalate. Dibutyl Phthalate 80-97 L1 cell adhesion molecule Homo sapiens 72-75 30077462-5 2018 The developed method provided a wide linear range from 0.005 to 500 mug L-1 for dibutyl phthalate, 0.01 to 500 mug L-1 for diethyl phthalate, benzylbutyl phthalate and bis(2-ethylhexyl) phthalate, and 0.02 to 500 mug L-1 for dimethyl phthalate and di-n-octyl phthalate. diethyl phthalate 123-140 L1 cell adhesion molecule Homo sapiens 115-118 30077462-5 2018 The developed method provided a wide linear range from 0.005 to 500 mug L-1 for dibutyl phthalate, 0.01 to 500 mug L-1 for diethyl phthalate, benzylbutyl phthalate and bis(2-ethylhexyl) phthalate, and 0.02 to 500 mug L-1 for dimethyl phthalate and di-n-octyl phthalate. diethyl phthalate 123-140 L1 cell adhesion molecule Homo sapiens 115-118 30077462-5 2018 The developed method provided a wide linear range from 0.005 to 500 mug L-1 for dibutyl phthalate, 0.01 to 500 mug L-1 for diethyl phthalate, benzylbutyl phthalate and bis(2-ethylhexyl) phthalate, and 0.02 to 500 mug L-1 for dimethyl phthalate and di-n-octyl phthalate. dimethyl phthalate 225-243 L1 cell adhesion molecule Homo sapiens 115-118 30077462-5 2018 The developed method provided a wide linear range from 0.005 to 500 mug L-1 for dibutyl phthalate, 0.01 to 500 mug L-1 for diethyl phthalate, benzylbutyl phthalate and bis(2-ethylhexyl) phthalate, and 0.02 to 500 mug L-1 for dimethyl phthalate and di-n-octyl phthalate. dimethyl phthalate 225-243 L1 cell adhesion molecule Homo sapiens 115-118 30077462-5 2018 The developed method provided a wide linear range from 0.005 to 500 mug L-1 for dibutyl phthalate, 0.01 to 500 mug L-1 for diethyl phthalate, benzylbutyl phthalate and bis(2-ethylhexyl) phthalate, and 0.02 to 500 mug L-1 for dimethyl phthalate and di-n-octyl phthalate. di-n-octyl phthalate 248-268 L1 cell adhesion molecule Homo sapiens 115-118 30077462-5 2018 The developed method provided a wide linear range from 0.005 to 500 mug L-1 for dibutyl phthalate, 0.01 to 500 mug L-1 for diethyl phthalate, benzylbutyl phthalate and bis(2-ethylhexyl) phthalate, and 0.02 to 500 mug L-1 for dimethyl phthalate and di-n-octyl phthalate. di-n-octyl phthalate 248-268 L1 cell adhesion molecule Homo sapiens 115-118 29894961-5 2018 Under optimized conditions, the fluorescence intensities of Tb-dtpa-bdap solution towards different uric acid concentrations show a linear response in the range from 1.00 x 10-5 mol L-1 to 5.00 x 10-5 mol L-1 with a linear correlation coefficient (R2) of 0.9877. tb-dtpa 60-67 L1 cell adhesion molecule Homo sapiens 182-185 29894961-5 2018 Under optimized conditions, the fluorescence intensities of Tb-dtpa-bdap solution towards different uric acid concentrations show a linear response in the range from 1.00 x 10-5 mol L-1 to 5.00 x 10-5 mol L-1 with a linear correlation coefficient (R2) of 0.9877. tb-dtpa 60-67 L1 cell adhesion molecule Homo sapiens 205-208 29894961-5 2018 Under optimized conditions, the fluorescence intensities of Tb-dtpa-bdap solution towards different uric acid concentrations show a linear response in the range from 1.00 x 10-5 mol L-1 to 5.00 x 10-5 mol L-1 with a linear correlation coefficient (R2) of 0.9877. 1,3-bis(dibutylamino)propan-2-ol 68-72 L1 cell adhesion molecule Homo sapiens 182-185 29894961-5 2018 Under optimized conditions, the fluorescence intensities of Tb-dtpa-bdap solution towards different uric acid concentrations show a linear response in the range from 1.00 x 10-5 mol L-1 to 5.00 x 10-5 mol L-1 with a linear correlation coefficient (R2) of 0.9877. 1,3-bis(dibutylamino)propan-2-ol 68-72 L1 cell adhesion molecule Homo sapiens 205-208 29894961-5 2018 Under optimized conditions, the fluorescence intensities of Tb-dtpa-bdap solution towards different uric acid concentrations show a linear response in the range from 1.00 x 10-5 mol L-1 to 5.00 x 10-5 mol L-1 with a linear correlation coefficient (R2) of 0.9877. Uric Acid 100-109 L1 cell adhesion molecule Homo sapiens 182-185 29894961-5 2018 Under optimized conditions, the fluorescence intensities of Tb-dtpa-bdap solution towards different uric acid concentrations show a linear response in the range from 1.00 x 10-5 mol L-1 to 5.00 x 10-5 mol L-1 with a linear correlation coefficient (R2) of 0.9877. Uric Acid 100-109 L1 cell adhesion molecule Homo sapiens 205-208 29894961-6 2018 And the obtained limit of detection (LOD) is about 5.80 x 10-6 mol L-1, which is lower than the level of uric acid in actual urine. Uric Acid 105-114 L1 cell adhesion molecule Homo sapiens 67-70 29902756-3 2018 The results indicated that the sensor L1 and L2 exhibited highly selective and sensitive recognition for Zn2+ ions. Zinc 105-109 L1 cell adhesion molecule Homo sapiens 38-47 29902756-6 2018 These results indicated that L1 and L2 can be applied as chemosensor for the detection of Zn2+ ion. Zinc 90-94 L1 cell adhesion molecule Homo sapiens 29-38 30287813-5 2018 We here show that H2S is stabilized by reaction with oleylamine (the most common and versatile ligand in nanoparticle synthesis) to form an ionic liquid precursor that addresses all major principles of green chemistry: it is made in one exothermic step, it leaves the reaction yielding a safer product and allowing the separate recycling of the precursors, and it produces high quality nanocrystals with high yields (sulfur yield > 70%) and concentrations (90 g L-1) in ambient conditions. Hydrogen Sulfide 18-21 L1 cell adhesion molecule Homo sapiens 465-468 30287813-5 2018 We here show that H2S is stabilized by reaction with oleylamine (the most common and versatile ligand in nanoparticle synthesis) to form an ionic liquid precursor that addresses all major principles of green chemistry: it is made in one exothermic step, it leaves the reaction yielding a safer product and allowing the separate recycling of the precursors, and it produces high quality nanocrystals with high yields (sulfur yield > 70%) and concentrations (90 g L-1) in ambient conditions. oleylamine 53-63 L1 cell adhesion molecule Homo sapiens 465-468 29883867-6 2018 In addition, factorial effects for Fe-Ver-C-H2 in photo-Fenton system were also investigated and optimized as: pH of 5, dosage of 0.2 g L-1 and H2O2 concentration of 20 mM. fe-ver-c 35-43 L1 cell adhesion molecule Homo sapiens 136-148 30068042-8 2018 Increasing H2O2 concentration results in increasing in EDTA removal up to 92.1%, while decreasing initial EDTA concentration up to 22.5 mg L-1 gives a complete removal in only 90 min. Edetic Acid 106-110 L1 cell adhesion molecule Homo sapiens 139-142 30132283-4 2018 PF reaction was evaluated at different pH values (2.8, 3.5, and 4.0) and iron concentrations (2, 5, 10, and 20 mg L-1). pyrazofurin 0-2 L1 cell adhesion molecule Homo sapiens 114-117 30132283-10 2018 On the other hand, at an invariable iron concentration of 5 mg Fe2+ L-1, the increase in pH was accompanied by a decrease in the molar fraction of the most photoactive iron complex (FeOH2+) and ferric hydroxides precipitation, leading to a reduction in the fluorene degradation rate. Iron 36-40 L1 cell adhesion molecule Homo sapiens 68-71 30132283-12 2018 PFF has shown to be more efficient than the PF under the same pH (4) and iron concentration (2 mg L-1). 4-fluorofentanyl 0-3 L1 cell adhesion molecule Homo sapiens 98-101 30132283-12 2018 PFF has shown to be more efficient than the PF under the same pH (4) and iron concentration (2 mg L-1). pyrazofurin 0-2 L1 cell adhesion molecule Homo sapiens 98-101 30058954-9 2018 Results showed that the reduction efficiencies for BPA and 2,4-Di-tert-butylphenol at pH 7.5 were 76% and 84% at LBG dosage of 500 mg L-1 and 400 mg L-1, respectively. bisphenol A 51-54 L1 cell adhesion molecule Homo sapiens 134-152 30058954-9 2018 Results showed that the reduction efficiencies for BPA and 2,4-Di-tert-butylphenol at pH 7.5 were 76% and 84% at LBG dosage of 500 mg L-1 and 400 mg L-1, respectively. 2,4-di-tert-butylphenol 59-82 L1 cell adhesion molecule Homo sapiens 134-152 30151540-4 2018 The standard addition experimental results of two real water samples with an addition level of 10 and 50 mug L-1 showed that the recoveries were between 92.4% and 108.9% with RSDs from 2.01% to 3.22%. Water 55-60 L1 cell adhesion molecule Homo sapiens 109-112 30253737-0 2018 Combination of lutetium-177 labelled anti-L1CAM antibody chCE7 with the clinically relevant protein kinase inhibitor MK1775: a novel combination against human ovarian carcinoma. Lutetium-177 15-27 L1 cell adhesion molecule Homo sapiens 42-47 30253737-5 2018 We combined selected PKIs with 177Lu-labelled anti-L1CAM monoclonal antibody chCE7 for our investigations. Lutetium-177 31-36 L1 cell adhesion molecule Homo sapiens 51-56 29776535-6 2018 A total of 33 different pesticides were found in these samples with MCPA present at the highest concentration, in excess of 130 ng L-1. 2-Methyl-4-chlorophenoxyacetic Acid 68-72 L1 cell adhesion molecule Homo sapiens 131-134 30091480-1 2018 The crystal structure of the polymeric complex [Au5 Ag2 Tl3 (C6 F5 )10 (L1 )2 ]n (L1 =1-aza-4,10-dithia-7-oxacyclododecane) displays heterotrimetallic Ag Au Tl moieties and is held by unsupported metallophilic interactions. 1-Oxa-4,10-dithia-7-azacyclododecane 86-122 L1 cell adhesion molecule Homo sapiens 61-77 30118599-9 2018 Furthermore, reactive blue 2 can be concentrated from 2.01 to 31.80 g L-1. Cibacron Blue F 3GA 13-28 L1 cell adhesion molecule Homo sapiens 70-73 30188054-4 2018 Na+, Ca2+, Mg2+, and SO42- were the major ions present in water, with mean concentrations of 202.8, 86.0, 78.6, and 431.2 mg L-1 respectively. Sulfates 21-26 L1 cell adhesion molecule Homo sapiens 125-128 29804022-4 2018 In the experiments, the initial concentration of arsenates was 10 mg L-1 (as As) and the concentrations of ions varied in the range from 5 to 100 mg L-1 of element in ionic form and humic acid. Arsenates 49-58 L1 cell adhesion molecule Homo sapiens 69-72 29803879-9 2018 Furthermore, the energy and material costs of the UVA/Fe2O3-Mn2O3 system for photocatalytic oxidation of 1 mg L-1 As(III) in the 1 L laboratory scale reactor was 0.0051 $. Iron(III) oxide 54-59 L1 cell adhesion molecule Homo sapiens 111-114 29803879-9 2018 Furthermore, the energy and material costs of the UVA/Fe2O3-Mn2O3 system for photocatalytic oxidation of 1 mg L-1 As(III) in the 1 L laboratory scale reactor was 0.0051 $. Manganese(III) oxide 60-65 L1 cell adhesion molecule Homo sapiens 111-114 29763862-6 2018 Moreover, 6.7 mg L-1 of H2O2 reduced microcystin and enhanced phytoplankton diversity, while causing relatively small negative effects on zooplankton abundance. microcystin 37-48 L1 cell adhesion molecule Homo sapiens 17-28 30167785-6 2018 Figures of merit for detection of Cd(II) include (a) a low and well separated working potential of -0.80 V (vs. Ag/AgCl), (b) a wide linear range (from 7 to 120 mug L-1), and a low detection limits 0.47 mug L-1. cd(ii) 34-40 L1 cell adhesion molecule Homo sapiens 165-168 30167785-6 2018 Figures of merit for detection of Cd(II) include (a) a low and well separated working potential of -0.80 V (vs. Ag/AgCl), (b) a wide linear range (from 7 to 120 mug L-1), and a low detection limits 0.47 mug L-1. cd(ii) 34-40 L1 cell adhesion molecule Homo sapiens 207-210 29998675-6 2018 Five different NO3--N content import levels were set:0, 0.5, 1.0, 5.0, and 10 mg L-1, which were denoted as N0, N1, N2, N3, and N4, respectively. no3--n 15-21 L1 cell adhesion molecule Homo sapiens 81-84 30188054-4 2018 Na+, Ca2+, Mg2+, and SO42- were the major ions present in water, with mean concentrations of 202.8, 86.0, 78.6, and 431.2 mg L-1 respectively. Water 58-63 L1 cell adhesion molecule Homo sapiens 125-128 29635095-4 2018 Influence of catalysts concentration on kinetic parameters of loxapine photodecomposition was evaluated, and TiO2 at medium concentration (100 mg L-1) turned out to be the most effective. titanium dioxide 109-113 L1 cell adhesion molecule Homo sapiens 146-149 29655108-5 2018 The chronic no observed effect concentrations (NOECs) of naproxen for reproduction were determined to be 10 mg L-1 in D. magna and 0.3 mg L-1 in M. macrocopa. Naproxen 57-65 L1 cell adhesion molecule Homo sapiens 111-114 29655108-5 2018 The chronic no observed effect concentrations (NOECs) of naproxen for reproduction were determined to be 10 mg L-1 in D. magna and 0.3 mg L-1 in M. macrocopa. Naproxen 57-65 L1 cell adhesion molecule Homo sapiens 138-141 29655108-7 2018 Concentration of 17beta-estradiol (E2) and the ratio of E2 and testosterone were significantly increased in H295R cells at 10 mg L-1, suggesting that naproxen could modulate sex hormone production. Estradiol 17-33 L1 cell adhesion molecule Homo sapiens 129-132 29655108-7 2018 Concentration of 17beta-estradiol (E2) and the ratio of E2 and testosterone were significantly increased in H295R cells at 10 mg L-1, suggesting that naproxen could modulate sex hormone production. Naproxen 150-158 L1 cell adhesion molecule Homo sapiens 129-132 29679945-2 2018 The results revealed that metoprolol (MTP) and venlafaxine (VFX) were of the highest concentrations among the five determined pharmaceuticals with mean concentrations of 803 ng L-1 and 408 ng L-1, respectively in influents, and 354 ng L-1 and 165 ng L-1 in effluents, respectively. Metoprolol 26-36 L1 cell adhesion molecule Homo sapiens 177-195 29679945-2 2018 The results revealed that metoprolol (MTP) and venlafaxine (VFX) were of the highest concentrations among the five determined pharmaceuticals with mean concentrations of 803 ng L-1 and 408 ng L-1, respectively in influents, and 354 ng L-1 and 165 ng L-1 in effluents, respectively. Metoprolol 26-36 L1 cell adhesion molecule Homo sapiens 235-253 29679945-2 2018 The results revealed that metoprolol (MTP) and venlafaxine (VFX) were of the highest concentrations among the five determined pharmaceuticals with mean concentrations of 803 ng L-1 and 408 ng L-1, respectively in influents, and 354 ng L-1 and 165 ng L-1 in effluents, respectively. Metoprolol 38-41 L1 cell adhesion molecule Homo sapiens 177-195 29679945-2 2018 The results revealed that metoprolol (MTP) and venlafaxine (VFX) were of the highest concentrations among the five determined pharmaceuticals with mean concentrations of 803 ng L-1 and 408 ng L-1, respectively in influents, and 354 ng L-1 and 165 ng L-1 in effluents, respectively. Metoprolol 38-41 L1 cell adhesion molecule Homo sapiens 235-253 29679945-2 2018 The results revealed that metoprolol (MTP) and venlafaxine (VFX) were of the highest concentrations among the five determined pharmaceuticals with mean concentrations of 803 ng L-1 and 408 ng L-1, respectively in influents, and 354 ng L-1 and 165 ng L-1 in effluents, respectively. Venlafaxine Hydrochloride 47-58 L1 cell adhesion molecule Homo sapiens 177-195 29679945-2 2018 The results revealed that metoprolol (MTP) and venlafaxine (VFX) were of the highest concentrations among the five determined pharmaceuticals with mean concentrations of 803 ng L-1 and 408 ng L-1, respectively in influents, and 354 ng L-1 and 165 ng L-1 in effluents, respectively. Venlafaxine Hydrochloride 47-58 L1 cell adhesion molecule Homo sapiens 235-253 29679945-2 2018 The results revealed that metoprolol (MTP) and venlafaxine (VFX) were of the highest concentrations among the five determined pharmaceuticals with mean concentrations of 803 ng L-1 and 408 ng L-1, respectively in influents, and 354 ng L-1 and 165 ng L-1 in effluents, respectively. Venlafaxine Hydrochloride 60-63 L1 cell adhesion molecule Homo sapiens 177-195 29679945-2 2018 The results revealed that metoprolol (MTP) and venlafaxine (VFX) were of the highest concentrations among the five determined pharmaceuticals with mean concentrations of 803 ng L-1 and 408 ng L-1, respectively in influents, and 354 ng L-1 and 165 ng L-1 in effluents, respectively. Venlafaxine Hydrochloride 60-63 L1 cell adhesion molecule Homo sapiens 235-253 29734026-5 2018 Metronidazole was detected in all the samples with concentrations ranging from 0.05 to 13.51 ng L-1. Metronidazole 0-13 L1 cell adhesion molecule Homo sapiens 96-99 29734026-6 2018 Trimethoprim had the second highest frequency of detection (95%) with the highest concentration (17.20 ng L-1). Trimethoprim 0-12 L1 cell adhesion molecule Homo sapiens 106-109 29734026-7 2018 The ranges of concentration and detection frequency of sulfonamides and macrolides were <LOD-11.35 and <LOD-16.68 ng L-1; 35-70 and 60-85%, respectively, whereas carbamazepine was in the range of <LOD-8.80 ng L-1 and had a detection frequency of 65%. Sulfonamides 55-67 L1 cell adhesion molecule Homo sapiens 123-126 29734026-7 2018 The ranges of concentration and detection frequency of sulfonamides and macrolides were <LOD-11.35 and <LOD-16.68 ng L-1; 35-70 and 60-85%, respectively, whereas carbamazepine was in the range of <LOD-8.80 ng L-1 and had a detection frequency of 65%. Sulfonamides 55-67 L1 cell adhesion molecule Homo sapiens 218-221 29802870-6 2018 Phenelzine treatment up-regulated the expression and proteolysis of L1.1 (a homolog of the mammalian recognition molecule L1) and phosphorylation of Erk in the spinal cord caudal to lesion site. Phenelzine 0-10 L1 cell adhesion molecule Homo sapiens 68-70 30211921-8 2018 Degradation rates were only slightly different in the presence of Suwannee River Humic Acid (5 mg L-1), and quenching experiments pointed to excited triplet state dissolved organic matter (3DOM*) as the dominant reactive intermediate responsible for the indirect photolysis of diBrE2. Humic Substances 81-91 L1 cell adhesion molecule Homo sapiens 98-101 29897361-2 2018 The concentration levels of selected antidepressants in wastewater and receiving water were both at ng L-1 level, but those antidepressants that were found in wastewater were typically in a range of one and even two orders of magnitude higher than those that were present in the receiving water except for the concentration levels of paroxetine, norfluoxetine, and nortriptyline. Water 81-86 L1 cell adhesion molecule Homo sapiens 103-106 29897361-3 2018 Venlafaxine and its metabolite O-desmethylvenlafaxine were the primary compounds (reaching up to 132.04 and 173.68 ng L-1 as well as 3.03 and 4.53 ng L-1 in wastewater and receiving water, respectively). Venlafaxine Hydrochloride 0-11 L1 cell adhesion molecule Homo sapiens 118-121 29897361-3 2018 Venlafaxine and its metabolite O-desmethylvenlafaxine were the primary compounds (reaching up to 132.04 and 173.68 ng L-1 as well as 3.03 and 4.53 ng L-1 in wastewater and receiving water, respectively). Venlafaxine Hydrochloride 0-11 L1 cell adhesion molecule Homo sapiens 150-153 29897361-3 2018 Venlafaxine and its metabolite O-desmethylvenlafaxine were the primary compounds (reaching up to 132.04 and 173.68 ng L-1 as well as 3.03 and 4.53 ng L-1 in wastewater and receiving water, respectively). Desvenlafaxine Succinate 31-53 L1 cell adhesion molecule Homo sapiens 118-121 29897361-3 2018 Venlafaxine and its metabolite O-desmethylvenlafaxine were the primary compounds (reaching up to 132.04 and 173.68 ng L-1 as well as 3.03 and 4.53 ng L-1 in wastewater and receiving water, respectively). Desvenlafaxine Succinate 31-53 L1 cell adhesion molecule Homo sapiens 150-153 29897361-3 2018 Venlafaxine and its metabolite O-desmethylvenlafaxine were the primary compounds (reaching up to 132.04 and 173.68 ng L-1 as well as 3.03 and 4.53 ng L-1 in wastewater and receiving water, respectively). Water 162-167 L1 cell adhesion molecule Homo sapiens 150-153 29679891-7 2018 In highly contaminated water (100 mug L-1), the adsorbent polishes the water quality to well below the current WHO limits. Water 23-28 L1 cell adhesion molecule Homo sapiens 38-41 29679891-7 2018 In highly contaminated water (100 mug L-1), the adsorbent polishes the water quality to well below the current WHO limits. Water 71-76 L1 cell adhesion molecule Homo sapiens 38-41 29603909-8 2018 The relative quantification of the isolated products was performed by HPLC-MS after derivatization with 2,4-dinitrophenilhydrazyne yielding a concentration of total degradation products of 1.62 g L-1 . 2,4-dinitrophenilhydrazyne 104-130 L1 cell adhesion molecule Homo sapiens 196-199 29524913-7 2018 The mediated electron transfer capacities of the POMs were also evaluated in a glucose sensor setup and showed very satisfying performances for glucose detection, including a sensitivity of 0.198 mA mol L-1 cm-2, a satisfying linear range between 1 mmol L-1 and 20 mmol L-1, and good reproducibility for the P2Mo18 electrode. Glucose 79-86 L1 cell adhesion molecule Homo sapiens 203-211 29524913-7 2018 The mediated electron transfer capacities of the POMs were also evaluated in a glucose sensor setup and showed very satisfying performances for glucose detection, including a sensitivity of 0.198 mA mol L-1 cm-2, a satisfying linear range between 1 mmol L-1 and 20 mmol L-1, and good reproducibility for the P2Mo18 electrode. Glucose 144-151 L1 cell adhesion molecule Homo sapiens 203-211 29782153-2 2018 Metallacycles M1 and M2 were prepared via the coordination-driven self-assembly of a 120 triarylamine ligand L1 and a 120 diplatinum(II) acceptor Pt-1 or 180 diplatinum(II) acceptor Pt-2, respectively. triarylamine 90-102 L1 cell adhesion molecule Homo sapiens 110-189 28648547-4 2018 Indeed, for an aqueous pH of 5.2 and a phosphorus concentration of 75 mg L-1, the recovered amounts increased from 19.2 mg g-1 to 33.8 mg g-1 when the used pyrolysis temperature was raised from 400 C to 600 C. For all the tested biochars, the phosphorus recovery kinetics data were well fitted by the pseudo-second-order model, and the equilibrium state was obtained after 180 min of contact time. Phosphorus 39-49 L1 cell adhesion molecule Homo sapiens 73-76 29554533-8 2018 Finally, GBP and GBP-Lactam were found in potable water with concentrations up to 0.64 and 0.07 mug L-1, respectively. Water 50-55 L1 cell adhesion molecule Homo sapiens 100-103 29635185-1 2018 Two novel acridine-based fluorescence chemosensors (L1 and L2) were prepared and their metal ions sensing properties were investigated. Acridines 10-18 L1 cell adhesion molecule Homo sapiens 52-61 29635185-1 2018 Two novel acridine-based fluorescence chemosensors (L1 and L2) were prepared and their metal ions sensing properties were investigated. Metals 87-92 L1 cell adhesion molecule Homo sapiens 52-61 29635185-3 2018 The detection limits of L1 and L2 were calculated by the fluorescence titration to be 4.13muM and 1.52muM, respectively, which were below the maximum permissive level of Fe3+ and Ni2+ ions in drinking water set by the EPA. ferric sulfate 170-174 L1 cell adhesion molecule Homo sapiens 24-33 29635185-3 2018 The detection limits of L1 and L2 were calculated by the fluorescence titration to be 4.13muM and 1.52muM, respectively, which were below the maximum permissive level of Fe3+ and Ni2+ ions in drinking water set by the EPA. Nickel(2+) 179-183 L1 cell adhesion molecule Homo sapiens 24-33 29635185-3 2018 The detection limits of L1 and L2 were calculated by the fluorescence titration to be 4.13muM and 1.52muM, respectively, which were below the maximum permissive level of Fe3+ and Ni2+ ions in drinking water set by the EPA. Water 201-206 L1 cell adhesion molecule Homo sapiens 24-33 28648547-4 2018 Indeed, for an aqueous pH of 5.2 and a phosphorus concentration of 75 mg L-1, the recovered amounts increased from 19.2 mg g-1 to 33.8 mg g-1 when the used pyrolysis temperature was raised from 400 C to 600 C. For all the tested biochars, the phosphorus recovery kinetics data were well fitted by the pseudo-second-order model, and the equilibrium state was obtained after 180 min of contact time. Phosphorus 245-255 L1 cell adhesion molecule Homo sapiens 73-76 29702093-6 2018 Neuronally-derived exosomes were isolated using a biotin-tagged L1 Cell Adhesion Molecule (L1CAM) specific antibody and streptavidin-tagged agarose resin. Biotin 50-56 L1 cell adhesion molecule Homo sapiens 64-89 29702093-6 2018 Neuronally-derived exosomes were isolated using a biotin-tagged L1 Cell Adhesion Molecule (L1CAM) specific antibody and streptavidin-tagged agarose resin. Biotin 50-56 L1 cell adhesion molecule Homo sapiens 91-96 29946540-7 2018 Specifically, up to 83.1% of NH4+ -N (initial concentration 50 mg L-1, catalyst dosage 2 g L-1, pH 10) was removed within 2 h retention time under Xe lamp irradiation. nh4+ -n 29-36 L1 cell adhesion molecule Homo sapiens 66-69 29850671-3 2018 By using the MiniEC with screen printed electrodes, the LOD (limit of detection) for Cd2+ and Pb2+ is as low as 1 mug L-1 and 0.5 mug L-1, respectively. Lead 94-98 L1 cell adhesion molecule Homo sapiens 118-129 29946540-7 2018 Specifically, up to 83.1% of NH4+ -N (initial concentration 50 mg L-1, catalyst dosage 2 g L-1, pH 10) was removed within 2 h retention time under Xe lamp irradiation. nh4+ -n 29-36 L1 cell adhesion molecule Homo sapiens 91-101 29660257-5 2018 Furthermore, a significantly high formate concentration of 41.5 g L-1 is obtained as a one-path product at 343 K with high PCD (51.7 mA cm-2 ) and high Faradaic efficiency (93.3 %) via continuous operation in a full flow cell at a low cell voltage of 2.2 V. formic acid 34-41 L1 cell adhesion molecule Homo sapiens 66-69 30229073-5 2018 The obtained optimal experimental conditions for the photodegradation process were the following: zinc stannate (ZTO) dosage=300 mg L-1, initial concentration of TC= 10 mg L-1, reaction time= 100 min and pH=4.5. Zinc Stannate 98-111 L1 cell adhesion molecule Homo sapiens 132-135 30229073-5 2018 The obtained optimal experimental conditions for the photodegradation process were the following: zinc stannate (ZTO) dosage=300 mg L-1, initial concentration of TC= 10 mg L-1, reaction time= 100 min and pH=4.5. zinc chromate 113-116 L1 cell adhesion molecule Homo sapiens 132-135 30229073-5 2018 The obtained optimal experimental conditions for the photodegradation process were the following: zinc stannate (ZTO) dosage=300 mg L-1, initial concentration of TC= 10 mg L-1, reaction time= 100 min and pH=4.5. Technetium 162-164 L1 cell adhesion molecule Homo sapiens 172-175 29573474-1 2018 Novel phenanthroline Schiff base fluorescent sensors L1, L2, and D1 were designed and synthesized. phenanthroline schiff base 6-32 L1 cell adhesion molecule Homo sapiens 53-67 29573474-3 2018 The compounds L1, L2, and D1 could act as Eu3+ ion turn-off fluorescent sensors based on ligand-to-metal binding mechanism in DMSO-H2 O solution (v/v = 1:1, 10 mM Tris, pH = 7.4). Metals 99-104 L1 cell adhesion molecule Homo sapiens 14-28 29573474-3 2018 The compounds L1, L2, and D1 could act as Eu3+ ion turn-off fluorescent sensors based on ligand-to-metal binding mechanism in DMSO-H2 O solution (v/v = 1:1, 10 mM Tris, pH = 7.4). Dimethyl Sulfoxide 126-130 L1 cell adhesion molecule Homo sapiens 14-28 29573474-3 2018 The compounds L1, L2, and D1 could act as Eu3+ ion turn-off fluorescent sensors based on ligand-to-metal binding mechanism in DMSO-H2 O solution (v/v = 1:1, 10 mM Tris, pH = 7.4). Water 131-135 L1 cell adhesion molecule Homo sapiens 14-28 29573474-3 2018 The compounds L1, L2, and D1 could act as Eu3+ ion turn-off fluorescent sensors based on ligand-to-metal binding mechanism in DMSO-H2 O solution (v/v = 1:1, 10 mM Tris, pH = 7.4). Tromethamine 163-167 L1 cell adhesion molecule Homo sapiens 14-28 29582322-4 2018 If the optimum parameters were used, i.e., pH 5 or higher, a biochar dosage of 12 g L-1, a 10 mg L-1 Cd initial concentration, and 15-min equilibrium time, at 25 C, then Cd removal could reach about 100%. Cadmium 101-103 L1 cell adhesion molecule Homo sapiens 97-100 29747152-3 2018 The total hydrocarbon (TPHs) concentration in WAF was 2.18 mg L-1. Hydrocarbons 10-21 L1 cell adhesion molecule Homo sapiens 62-65 29747152-3 2018 The total hydrocarbon (TPHs) concentration in WAF was 2.18 mg L-1. tphs 23-27 L1 cell adhesion molecule Homo sapiens 62-65 29747152-4 2018 The dissipation rates of hydrocarbons in WAF showed a first-order kinetics, with half-lives ranging between 65 h-200 h. Amphipods from LB showed acute and chronic LC50 values of 0.33 and 0.018 mg L-1, respectively. Hydrocarbons 25-37 L1 cell adhesion molecule Homo sapiens 196-199 29898564-12 2018 CD is most efficient in remobilizing Cu and Pb at 400 mg L-1 CD concentration and under low ionic strength (ca. Cadmium 0-2 L1 cell adhesion molecule Homo sapiens 57-60 29567166-8 2018 The two methods are suitable for concentration ranges from about 0.1-1.65 mg L-1 and from about 0.3-3.3 mg L-1, respectively for PAA and H2O2. Peracetic Acid 129-132 L1 cell adhesion molecule Homo sapiens 77-80 29944132-5 2018 When the concentration was above 400 mg L-1, the PAM precipitation tended to be maximum, followed by NaOH adjustment of pH to 8.0 that could enhance PAM flocculation successively. Sodium Hydroxide 101-105 L1 cell adhesion molecule Homo sapiens 40-43 29944132-6 2018 The sewage sludge (SS) remained and residue oil reduced to 25 mg L-1 and 34mg L-1 respectively. Oils 44-47 L1 cell adhesion molecule Homo sapiens 65-75 29944132-6 2018 The sewage sludge (SS) remained and residue oil reduced to 25 mg L-1 and 34mg L-1 respectively. Oils 44-47 L1 cell adhesion molecule Homo sapiens 65-68 29567166-8 2018 The two methods are suitable for concentration ranges from about 0.1-1.65 mg L-1 and from about 0.3-3.3 mg L-1, respectively for PAA and H2O2. Peracetic Acid 129-132 L1 cell adhesion molecule Homo sapiens 107-110 29567166-8 2018 The two methods are suitable for concentration ranges from about 0.1-1.65 mg L-1 and from about 0.3-3.3 mg L-1, respectively for PAA and H2O2. Hydrogen Peroxide 137-141 L1 cell adhesion molecule Homo sapiens 107-110 29567169-10 2018 Load of sample solution (6 microL) resulted in the length of red-violet color product on the threads being proportional to the concentration of Mg(II) in waters and rubber latex samples with the working concentration range of 25-1000 mg L-1. mg(ii) 144-150 L1 cell adhesion molecule Homo sapiens 237-240 29567169-12 2018 After sample loading (3 microL), the initially red-brown threads turned into white corresponding to formation of AgCl(s) on the threads with a working concentration range of 75-600 mg L-1. silver chloride 113-117 L1 cell adhesion molecule Homo sapiens 184-187 28443369-4 2018 A mineralization degree of around 80% with Na2SO4 and 92% in presence of NaCl was achieved at 30 C using 2.15 g L-1 PS at the lowest current density tested (1 mA cm-2). Sodium Chloride 73-77 L1 cell adhesion molecule Homo sapiens 112-115 30016266-8 2018 The substrate exhibited a high sensitivity for arsenic detection with a limit of detection down to 1.5 mug L-1, which is much lower than permissible limit (10 mug L-1) set by the WHO. Arsenic 47-54 L1 cell adhesion molecule Homo sapiens 107-110 30016266-8 2018 The substrate exhibited a high sensitivity for arsenic detection with a limit of detection down to 1.5 mug L-1, which is much lower than permissible limit (10 mug L-1) set by the WHO. Arsenic 47-54 L1 cell adhesion molecule Homo sapiens 163-166 29475109-4 2018 Heterogeneous photocatalysis using TiO2-P25 and assisted with H2O2 (P25/H2O2) was the most efficient process on the degradation of the chemical organic micropollutants, attaining levels below the limits of quantification in less than 4 h of treatment (corresponding to QUV < 40 kJ L-1). tio2-p25 35-43 L1 cell adhesion molecule Homo sapiens 284-287 29475109-4 2018 Heterogeneous photocatalysis using TiO2-P25 and assisted with H2O2 (P25/H2O2) was the most efficient process on the degradation of the chemical organic micropollutants, attaining levels below the limits of quantification in less than 4 h of treatment (corresponding to QUV < 40 kJ L-1). Hydrogen Peroxide 62-66 L1 cell adhesion molecule Homo sapiens 284-287 29346024-8 2018 The mean concentrations of PAHs in the polluted surface water and hospital wastewater were relatively high: 3.9 +- 1.7 and 21.5 +- 2.8 microg L-1, respectively. Polycyclic Aromatic Hydrocarbons 27-31 L1 cell adhesion molecule Homo sapiens 142-145 29433099-3 2018 Mean concentrations of the estrone and 17beta-estradiol were 55.1 ng L-1 and 56.1 ng L-1 in groundwater, 32.5 ng g-1 and 23.1 ng g-1 in soil, respectively. Estradiol 39-55 L1 cell adhesion molecule Homo sapiens 69-88 29512924-11 2018 Compared with THP alone (400 mumol L-1 , 50 muL), the combination with metformin (60 mmol L-1 , 50 muL) stopped growth of bladder cancer completely in vivo (combination group VS normal group P = .078). Metformin 71-80 L1 cell adhesion molecule Homo sapiens 90-102 29488201-2 2018 First of all, a chemical oxygen demand (COD) and color removal efficiency of 66 and 63% was achieved at initial pH of 6.8, 25 mmol L-1 of H2O2, and 2 g L-1 of Fe0 in the Fe0/H2O2 reaction. Oxygen 25-31 L1 cell adhesion molecule Homo sapiens 131-134 29488201-2 2018 First of all, a chemical oxygen demand (COD) and color removal efficiency of 66 and 63% was achieved at initial pH of 6.8, 25 mmol L-1 of H2O2, and 2 g L-1 of Fe0 in the Fe0/H2O2 reaction. Oxygen 25-31 L1 cell adhesion molecule Homo sapiens 152-162 29488201-2 2018 First of all, a chemical oxygen demand (COD) and color removal efficiency of 66 and 63% was achieved at initial pH of 6.8, 25 mmol L-1 of H2O2, and 2 g L-1 of Fe0 in the Fe0/H2O2 reaction. Hydrogen Peroxide 174-178 L1 cell adhesion molecule Homo sapiens 152-162 29488201-5 2018 A low operational cost of 0.35 $ m-3 was achieved because pH adjustment and iron-containing sludge disposal could be avoided since a total COD and color removal efficiency of 85 and 79% could be achieved at an original pH of 6.8 by the above sequential process with a ferric ion concentration below 0.8 mg L-1 after the Fe0/H2O2 reaction. Ferric enterobactin ion 268-274 L1 cell adhesion molecule Homo sapiens 306-309 31458644-5 2018 The results disclosed that 50 mg L-1 of the compounds (1-4) in 1 M HCl provided the maximum inhibition efficiency as 93% (1), 88% (2), 82% (3), and 86% (4). Hydrochloric Acid 67-70 L1 cell adhesion molecule Homo sapiens 33-36 28229576-8 2018 A moderate effect was apparent for C concentrations T4 in (ES=-0.95, CT1; 230+-69, CT2; 314+-105 nmol/L-1). Hydrocortisone 35-36 L1 cell adhesion molecule Homo sapiens 102-105 29696383-2 2018 After optimization, the automatic system enabled highly sensitive determinations of As and Se species with detection limits as low as 0.004-0.033 mug L-1 for As and 0.061-0.128 mug L-1 for Se. Arsenic 84-86 L1 cell adhesion molecule Homo sapiens 150-153 29696383-2 2018 After optimization, the automatic system enabled highly sensitive determinations of As and Se species with detection limits as low as 0.004-0.033 mug L-1 for As and 0.061-0.128 mug L-1 for Se. Arsenic 84-86 L1 cell adhesion molecule Homo sapiens 181-184 29696383-2 2018 After optimization, the automatic system enabled highly sensitive determinations of As and Se species with detection limits as low as 0.004-0.033 mug L-1 for As and 0.061-0.128 mug L-1 for Se. Selenium 91-93 L1 cell adhesion molecule Homo sapiens 150-153 29696383-2 2018 After optimization, the automatic system enabled highly sensitive determinations of As and Se species with detection limits as low as 0.004-0.033 mug L-1 for As and 0.061-0.128 mug L-1 for Se. Selenium 91-93 L1 cell adhesion molecule Homo sapiens 181-184 29696383-2 2018 After optimization, the automatic system enabled highly sensitive determinations of As and Se species with detection limits as low as 0.004-0.033 mug L-1 for As and 0.061-0.128 mug L-1 for Se. Arsenic 158-160 L1 cell adhesion molecule Homo sapiens 150-153 29696383-2 2018 After optimization, the automatic system enabled highly sensitive determinations of As and Se species with detection limits as low as 0.004-0.033 mug L-1 for As and 0.061-0.128 mug L-1 for Se. Selenium 189-191 L1 cell adhesion molecule Homo sapiens 181-184 29543991-4 2018 These fully 3D printed and packaged LIBs, which are encased between two glassy carbon current collectors, deliver an areal capacity of 4.45 mAh cm-2 at a current density of 0.14 mA cm-2 , which is equivalent to 17.3 Ah L-1 . libs 36-40 L1 cell adhesion molecule Homo sapiens 219-222 29349741-7 2018 The TCS removal rate increased from 85.33 to 99.75% when the ClO2 concentration increased from 0.25 to 1.5 mg L-1. Triclosan 4-7 L1 cell adhesion molecule Homo sapiens 110-113 28561993-6 2018 Co-Cr alloys processed by L-1 and L-2 showed higher (p < 0.05) hardness (14-19%), yield strength (10-13%), and fatigue resistance (71-72%) compared to CC alloys. co-cr 0-5 L1 cell adhesion molecule Homo sapiens 26-29 29442916-6 2018 The catalyst shows high catalytic activity in cipfloxacin photodegradation reaction with the cipfloxacin conversion efficiency higher than 95.61% at experimental conditions (catalyst dose, 0.75 g L-1; H2O2 dose, 200 mg L-1; solution pH, 5.0). cipfloxacin 46-57 L1 cell adhesion molecule Homo sapiens 198-207 29442916-6 2018 The catalyst shows high catalytic activity in cipfloxacin photodegradation reaction with the cipfloxacin conversion efficiency higher than 95.61% at experimental conditions (catalyst dose, 0.75 g L-1; H2O2 dose, 200 mg L-1; solution pH, 5.0). cipfloxacin 46-57 L1 cell adhesion molecule Homo sapiens 198-201 29442916-6 2018 The catalyst shows high catalytic activity in cipfloxacin photodegradation reaction with the cipfloxacin conversion efficiency higher than 95.61% at experimental conditions (catalyst dose, 0.75 g L-1; H2O2 dose, 200 mg L-1; solution pH, 5.0). cipfloxacin 93-104 L1 cell adhesion molecule Homo sapiens 198-201 29525378-0 2018 Celecoxib suppresses proliferation and metastasis of pancreatic cancer cells by down-regulating STAT3 / NF-kB and L1CAM activities. Celecoxib 0-9 L1 cell adhesion molecule Homo sapiens 114-119 29525378-6 2018 Over-expression of L1CAM activated the STAT3/NF-kappaB signaling pathway in Panc-1 and Bxpc-3 pancreatic cancer cells and celecoxib inhibited their viability and the expressions of STAT3, p-STAT3, NF-kappaB, p-NF-kappaB as well as full length L1CAM in a concentration dependent manner. Celecoxib 122-131 L1 cell adhesion molecule Homo sapiens 19-24 29525378-6 2018 Over-expression of L1CAM activated the STAT3/NF-kappaB signaling pathway in Panc-1 and Bxpc-3 pancreatic cancer cells and celecoxib inhibited their viability and the expressions of STAT3, p-STAT3, NF-kappaB, p-NF-kappaB as well as full length L1CAM in a concentration dependent manner. Celecoxib 122-131 L1 cell adhesion molecule Homo sapiens 243-248 29525378-8 2018 L1CAM activated the STAT/NF-kappaB signaling pathway and celecoxib could inhibit the activity of L1CAM, STAT3 and the NF-kappaB signaling pathway resulting in decreased growth and invasion of pancreatic cancer cells. Celecoxib 57-66 L1 cell adhesion molecule Homo sapiens 97-102 29349741-7 2018 The TCS removal rate increased from 85.33 to 99.75% when the ClO2 concentration increased from 0.25 to 1.5 mg L-1. chlorine dioxide 61-65 L1 cell adhesion molecule Homo sapiens 110-113 29349741-8 2018 TCS degradation can be promoted at low NOM level (1, 3, and 5 mg L-1), whereas was inhibited at high NOM concentrations of 7 and 9 mg L-1. Triclosan 0-3 L1 cell adhesion molecule Homo sapiens 65-68 29349741-8 2018 TCS degradation can be promoted at low NOM level (1, 3, and 5 mg L-1), whereas was inhibited at high NOM concentrations of 7 and 9 mg L-1. Triclosan 0-3 L1 cell adhesion molecule Homo sapiens 134-137 29349741-9 2018 While adding H2O2, the degradation rate of TCS increased with increasing H2O2 concentration from 1 to 3 mg L-1; however, too low or overdosed H2O2 (0.5 and 5 mg L-1) hindered TCS degradation. Hydrogen Peroxide 13-17 L1 cell adhesion molecule Homo sapiens 107-110 29349741-9 2018 While adding H2O2, the degradation rate of TCS increased with increasing H2O2 concentration from 1 to 3 mg L-1; however, too low or overdosed H2O2 (0.5 and 5 mg L-1) hindered TCS degradation. Hydrogen Peroxide 13-17 L1 cell adhesion molecule Homo sapiens 161-164 29349741-9 2018 While adding H2O2, the degradation rate of TCS increased with increasing H2O2 concentration from 1 to 3 mg L-1; however, too low or overdosed H2O2 (0.5 and 5 mg L-1) hindered TCS degradation. Triclosan 43-46 L1 cell adhesion molecule Homo sapiens 107-110 29349741-9 2018 While adding H2O2, the degradation rate of TCS increased with increasing H2O2 concentration from 1 to 3 mg L-1; however, too low or overdosed H2O2 (0.5 and 5 mg L-1) hindered TCS degradation. Triclosan 43-46 L1 cell adhesion molecule Homo sapiens 161-164 29349741-9 2018 While adding H2O2, the degradation rate of TCS increased with increasing H2O2 concentration from 1 to 3 mg L-1; however, too low or overdosed H2O2 (0.5 and 5 mg L-1) hindered TCS degradation. Hydrogen Peroxide 73-77 L1 cell adhesion molecule Homo sapiens 107-110 29349741-9 2018 While adding H2O2, the degradation rate of TCS increased with increasing H2O2 concentration from 1 to 3 mg L-1; however, too low or overdosed H2O2 (0.5 and 5 mg L-1) hindered TCS degradation. Hydrogen Peroxide 73-77 L1 cell adhesion molecule Homo sapiens 107-110 29349741-9 2018 While adding H2O2, the degradation rate of TCS increased with increasing H2O2 concentration from 1 to 3 mg L-1; however, too low or overdosed H2O2 (0.5 and 5 mg L-1) hindered TCS degradation. Triclosan 175-178 L1 cell adhesion molecule Homo sapiens 161-164 30623697-7 2018 Limits of detection and quantitation of the 23 PFAS test compounds in water samples were 0.5-10 ng L-1 and 2-20 ng L-1, respectively. Water 70-75 L1 cell adhesion molecule Homo sapiens 99-102 29165649-6 2018 Results of 190 water samples shows radon concentrations from 0.2 to 28.0 Bq L-1, with a geometric mean of 5.0 Bq L-1. Water 15-20 L1 cell adhesion molecule Homo sapiens 76-79 29165649-6 2018 Results of 190 water samples shows radon concentrations from 0.2 to 28.0 Bq L-1, with a geometric mean of 5.0 Bq L-1. Water 15-20 L1 cell adhesion molecule Homo sapiens 113-116 29615539-5 2018 L1CAM was: 1) induced in premature forms of cellular senescence triggered chemically and by gamma-radiation, but not in Ras-induced senescence; 2) induced upon inhibition of cyclin-dependent kinases by p16INK4a; 3) induced by TGFbeta and suppressed by RAS/MAPK(Erk) signaling (the latter explaining the lack of L1CAM induction in RAS-induced senescence); and 4) induced upon downregulation of growth-associated gene ANT2, growth in low-glucose medium or inhibition of the mevalonate pathway. Glucose 436-443 L1 cell adhesion molecule Homo sapiens 0-5 29615539-5 2018 L1CAM was: 1) induced in premature forms of cellular senescence triggered chemically and by gamma-radiation, but not in Ras-induced senescence; 2) induced upon inhibition of cyclin-dependent kinases by p16INK4a; 3) induced by TGFbeta and suppressed by RAS/MAPK(Erk) signaling (the latter explaining the lack of L1CAM induction in RAS-induced senescence); and 4) induced upon downregulation of growth-associated gene ANT2, growth in low-glucose medium or inhibition of the mevalonate pathway. Mevalonic Acid 472-482 L1 cell adhesion molecule Homo sapiens 0-5 29965476-2 2018 The results showed that adding 50 mg L-1 organic carbon accelerated the start-up of the CANON granular sludge process. Carbon 49-55 L1 cell adhesion molecule Homo sapiens 37-40 29307069-3 2018 With initial methyl orange (MO) and NaCl of 50 and 3000 mg L-1, decolorization and desalination efficiencies of 70.2 and 88.7% were achieved after 6-h treatment with applied voltage of 6 V. Increasing applied voltages resulted in the improvements of both color and salt removal, while higher MO concentrations suppressed decolorization and higher NaCl concentration accelerated desalination rate. methyl orange 13-26 L1 cell adhesion molecule Homo sapiens 59-62 29307069-3 2018 With initial methyl orange (MO) and NaCl of 50 and 3000 mg L-1, decolorization and desalination efficiencies of 70.2 and 88.7% were achieved after 6-h treatment with applied voltage of 6 V. Increasing applied voltages resulted in the improvements of both color and salt removal, while higher MO concentrations suppressed decolorization and higher NaCl concentration accelerated desalination rate. Sodium Chloride 36-40 L1 cell adhesion molecule Homo sapiens 59-62 29137783-2 2018 It was found that sonication at 600 kHz and 120 W completely remove PhE (10 mg L-1) from aerated solutions within 100 min of irradiation. phenoxyethanol 68-71 L1 cell adhesion molecule Homo sapiens 79-82 29137783-6 2018 Finally, analyzing the degradation rates at various initial PhE concentrations (2-400 mg L-1) with a heterogeneous Langmuir type mechanism underlined the predominance of interfacial radical reactions during the oxidation of PhE, particularly at high initial pollutant concentrations. phenoxyethanol 224-227 L1 cell adhesion molecule Homo sapiens 89-92 29172962-7 2018 Moreover, the useful life of the GAC bed is increased from 45 min in the column fed with raw leachate to 170 min in the column fed with pretreated leachate and 5000 mg L-1 of H2O2 at pH of 8 that subsequently increased the activated carbon adsorption capacity. Carbon 233-239 L1 cell adhesion molecule Homo sapiens 168-179 29874776-1 2018 This study investigated the fate of tetracycline at four different concentrations of 20 mug L-1, 50 mug L-1, 2 and 5 mg L-1 in the enhanced biological nutrient removal processes. Tetracycline 36-48 L1 cell adhesion molecule Homo sapiens 92-116 29874776-1 2018 This study investigated the fate of tetracycline at four different concentrations of 20 mug L-1, 50 mug L-1, 2 and 5 mg L-1 in the enhanced biological nutrient removal processes. Tetracycline 36-48 L1 cell adhesion molecule Homo sapiens 92-95 29874776-2 2018 At the tetracycline concentration below 50 mug L-1, no obvious inhibition on the biological N&P removal was observed, while the inhibition appeared after the tetracycline concentration was increased to 2 and 5 mg L-1. Tetracycline 162-174 L1 cell adhesion molecule Homo sapiens 217-220 29250622-1 2018 Copper(ii) complexes [Cu(L1/L2/L3)(A)] (1-3), where H2A HCl is a vitamin B6 Schiff base, viz. cupric ion 0-10 L1 cell adhesion molecule Homo sapiens 25-30 29215959-6 2018 When the PB4 impellers were placed in best configuration, c/Dt = 0.5, s/Di = 1, the maximum bioH2 productivity obtained was 440 mL L-1 hr-1, with a bioH2 molar yield of 1.8. MMP-13 Inhibitor 9-12 L1 cell adhesion molecule Homo sapiens 131-139 29215959-6 2018 When the PB4 impellers were placed in best configuration, c/Dt = 0.5, s/Di = 1, the maximum bioH2 productivity obtained was 440 mL L-1 hr-1, with a bioH2 molar yield of 1.8. bioh2 92-97 L1 cell adhesion molecule Homo sapiens 131-139 29215959-7 2018 The second best configuration obtained with the PB4 impellers presented a bioH2 productivity of 407.94 mL L-1 hr-1. bioh2 74-79 L1 cell adhesion molecule Homo sapiens 106-114 29215959-8 2018 The configurations based on Rushton impellers showed a lower bioH2 productivity and bioH2 molar yield of 177.065 mL L-1 hr-1 and 0.71, respectively. bioh2 84-89 L1 cell adhesion molecule Homo sapiens 116-133 29194777-1 2018 Rechargeable magnesium/sulfur battery is of significant interest because its energy density (1700 Wh kg-1 and 3200 Wh L-1 ) is among the highest of all battery chemistries (lower than Li/O2 and Mg/O2 but comparable to Li/S), and Mg metal allows reversible operation (100% Coulombic efficiency) with no dendrite formation. Magnesium 13-22 L1 cell adhesion molecule Homo sapiens 118-121 29194777-1 2018 Rechargeable magnesium/sulfur battery is of significant interest because its energy density (1700 Wh kg-1 and 3200 Wh L-1 ) is among the highest of all battery chemistries (lower than Li/O2 and Mg/O2 but comparable to Li/S), and Mg metal allows reversible operation (100% Coulombic efficiency) with no dendrite formation. Sulfur 23-29 L1 cell adhesion molecule Homo sapiens 118-121 29278989-4 2018 The concentration of arsenic in 163 collected samples from different locations during four seasons ranged from 0 to 99 mug L-1. Arsenic 21-28 L1 cell adhesion molecule Homo sapiens 123-126 29456682-5 2018 The present study demonstrated that overexpressing L1CAM promoted paclitaxel resistance and regulated paclitaxel resistance-associated microRNA expression in HEC-1A cells. Paclitaxel 66-76 L1 cell adhesion molecule Homo sapiens 51-56 29456682-5 2018 The present study demonstrated that overexpressing L1CAM promoted paclitaxel resistance and regulated paclitaxel resistance-associated microRNA expression in HEC-1A cells. Paclitaxel 102-112 L1 cell adhesion molecule Homo sapiens 51-56 29251308-5 2018 In vitro assays in combination with various sample enrichment methods have been used with limits of detection as low as 0.0027 ng L-1 in water, and 0.0026 ng g-1 in sediments for estrogenicity, 0.1 ng L-1 in water, and 0.5 ng g-1 in sediments for androgenicity, and 5 ng L-1 in water for progestogenicity expressed as equivalent concentrations of standard reference compounds of 17beta-estradiol, dihydrotestosterone and progesterone, respectively. Water 137-142 L1 cell adhesion molecule Homo sapiens 130-133 31458510-1 2018 We report the synthesis, structure, and adsorption properties of two new metal-organic frameworks (MOFs) {[Cu2(bpp)3(L1)] (bpp) (4H2O)} (1) and {[Cu2(bipy)2(L2)(H2O)2] (bipy) (5H2O)} (2) obtained from two different flexible tetracarboxylate linkers (L1 and L2) of variable lengths and flexibility. Metals 73-78 L1 cell adhesion molecule Homo sapiens 250-259 29215874-5 2018 This enhancement in binding capability of magnetite for NA is still observed in the presence of environmentally relevant ligands (e.g., 10 mg L-1 of HA or 100 muM of silicates). Silicates 166-175 L1 cell adhesion molecule Homo sapiens 142-162 30623697-7 2018 Limits of detection and quantitation of the 23 PFAS test compounds in water samples were 0.5-10 ng L-1 and 2-20 ng L-1, respectively. Water 70-75 L1 cell adhesion molecule Homo sapiens 115-118 29054370-6 2017 Silencing endogenous L1CAM with intrathecal L1CAM specific siRNA, disrupting lipid rafts with the perineurial cholesterol-sequestering agent MbetaCD, as well as suppressing NGF receptor activation with the perineurial NGF receptor inhibitor K252a abrogated MOR axonal membrane integration, functional coupling, and agonist-elicited antinociception at sites of nerve injury. Cholesterol 110-121 L1 cell adhesion molecule Homo sapiens 21-26 29054370-6 2017 Silencing endogenous L1CAM with intrathecal L1CAM specific siRNA, disrupting lipid rafts with the perineurial cholesterol-sequestering agent MbetaCD, as well as suppressing NGF receptor activation with the perineurial NGF receptor inhibitor K252a abrogated MOR axonal membrane integration, functional coupling, and agonist-elicited antinociception at sites of nerve injury. mbetacd 141-148 L1 cell adhesion molecule Homo sapiens 21-26 29054370-6 2017 Silencing endogenous L1CAM with intrathecal L1CAM specific siRNA, disrupting lipid rafts with the perineurial cholesterol-sequestering agent MbetaCD, as well as suppressing NGF receptor activation with the perineurial NGF receptor inhibitor K252a abrogated MOR axonal membrane integration, functional coupling, and agonist-elicited antinociception at sites of nerve injury. staurosporine aglycone 241-246 L1 cell adhesion molecule Homo sapiens 21-26 28974576-0 2017 MicroRNA miR-128 represses LINE-1 (L1) retrotransposition by down-regulating the nuclear import factor TNPO1. mir-128 9-16 L1 cell adhesion molecule Homo sapiens 27-37 29186238-6 2017 The efficiency of Au@FeS2 (1 g L-1) in the degradation of the textile dye NRH (1 mg L-1) is found to be 96.02% in just 60 minutes, which is considerably higher than that of FeS2 (1 g L-1) (95.63% in 120 minutes). Gold 18-20 L1 cell adhesion molecule Homo sapiens 31-34 29186238-6 2017 The efficiency of Au@FeS2 (1 g L-1) in the degradation of the textile dye NRH (1 mg L-1) is found to be 96.02% in just 60 minutes, which is considerably higher than that of FeS2 (1 g L-1) (95.63% in 120 minutes). Gold 18-20 L1 cell adhesion molecule Homo sapiens 84-87 29186238-6 2017 The efficiency of Au@FeS2 (1 g L-1) in the degradation of the textile dye NRH (1 mg L-1) is found to be 96.02% in just 60 minutes, which is considerably higher than that of FeS2 (1 g L-1) (95.63% in 120 minutes). Gold 18-20 L1 cell adhesion molecule Homo sapiens 84-87 29186238-6 2017 The efficiency of Au@FeS2 (1 g L-1) in the degradation of the textile dye NRH (1 mg L-1) is found to be 96.02% in just 60 minutes, which is considerably higher than that of FeS2 (1 g L-1) (95.63% in 120 minutes). fes2 21-25 L1 cell adhesion molecule Homo sapiens 31-34 29186238-6 2017 The efficiency of Au@FeS2 (1 g L-1) in the degradation of the textile dye NRH (1 mg L-1) is found to be 96.02% in just 60 minutes, which is considerably higher than that of FeS2 (1 g L-1) (95.63% in 120 minutes). fes2 21-25 L1 cell adhesion molecule Homo sapiens 84-87 29186238-6 2017 The efficiency of Au@FeS2 (1 g L-1) in the degradation of the textile dye NRH (1 mg L-1) is found to be 96.02% in just 60 minutes, which is considerably higher than that of FeS2 (1 g L-1) (95.63% in 120 minutes). fes2 21-25 L1 cell adhesion molecule Homo sapiens 84-87 29964573-5 2017 The effluent chemical oxygen demand (COD) concentration could be lowered to 23 mg L-1. Oxygen 22-28 L1 cell adhesion molecule Homo sapiens 82-85 29964573-8 2017 A gradient experiment revealed that the high Na2SO4 inflow could be treated when the influent COD ranged from 18000 mg L-1to 21000 mg L-1, the concentration of SO42- ranged between 9082 mg L-1 and 9600 mg L-1, and the COD/SO42-=2. sodium sulfate 45-51 L1 cell adhesion molecule Homo sapiens 119-122 29964573-8 2017 A gradient experiment revealed that the high Na2SO4 inflow could be treated when the influent COD ranged from 18000 mg L-1to 21000 mg L-1, the concentration of SO42- ranged between 9082 mg L-1 and 9600 mg L-1, and the COD/SO42-=2. sodium sulfate 45-51 L1 cell adhesion molecule Homo sapiens 134-137 29964573-8 2017 A gradient experiment revealed that the high Na2SO4 inflow could be treated when the influent COD ranged from 18000 mg L-1to 21000 mg L-1, the concentration of SO42- ranged between 9082 mg L-1 and 9600 mg L-1, and the COD/SO42-=2. sodium sulfate 45-51 L1 cell adhesion molecule Homo sapiens 134-137 29964576-2 2017 The experimental results under different conditions showed that shortcut nitrification in the MBR was achieved by controlling the dissolved oxygen (DO) concentration to low levels (0.5-1.0 mg L-1 to 0.3-0.7 mg L-1) and changing the effective volume of the MBR to control hydraulic retention time (HRT), with the HRT in the ABR equal to 6 h, sludge reflux ratio of 100%, NOx--N reflux ratio of 300%, and temperature of 30C+-2C. Oxygen 140-146 L1 cell adhesion molecule Homo sapiens 192-195 29964576-2 2017 The experimental results under different conditions showed that shortcut nitrification in the MBR was achieved by controlling the dissolved oxygen (DO) concentration to low levels (0.5-1.0 mg L-1 to 0.3-0.7 mg L-1) and changing the effective volume of the MBR to control hydraulic retention time (HRT), with the HRT in the ABR equal to 6 h, sludge reflux ratio of 100%, NOx--N reflux ratio of 300%, and temperature of 30C+-2C. do 148-150 L1 cell adhesion molecule Homo sapiens 192-195 29964576-4 2017 The analysis of the influencing factors of shortcut nitrification showed that maintaining low DO concentration (0.3-0.7 mg L-1) and gradually shortening HRT were the key factors. do 94-96 L1 cell adhesion molecule Homo sapiens 123-126 29964576-6 2017 During the period of shortcut nitrification, a stable and high efficiency removal of COD and NH4+-N were achieved, and the average concentration of the effluent of COD and NH4+-N, whose removal rates were above 90%, were below 50 mg L-1 and 2 mg L-1, respectively, and the removal efficiency of total nitrogen (TN) reached 72%. nh4+-n 172-178 L1 cell adhesion molecule Homo sapiens 233-242 29964576-6 2017 During the period of shortcut nitrification, a stable and high efficiency removal of COD and NH4+-N were achieved, and the average concentration of the effluent of COD and NH4+-N, whose removal rates were above 90%, were below 50 mg L-1 and 2 mg L-1, respectively, and the removal efficiency of total nitrogen (TN) reached 72%. nh4+-n 172-178 L1 cell adhesion molecule Homo sapiens 233-236 28112035-7 2017 Glyphosate concentration (C0 = 16.9 mg L-1) decreased up to 0.6 mg L-1 when the optimal conditions were imposed (current intensity of 4.77 A and treatment time of 173 min). glyphosate 0-10 L1 cell adhesion molecule Homo sapiens 39-42 31565320-6 2018 The amount of fluoride adsorbed increases from 11.32 to 26 mg L-1 when the number of substrates increases from 1 to 5. Fluorides 14-22 L1 cell adhesion molecule Homo sapiens 62-65 31565320-7 2018 A 68% removal of fluoride is observed when 20 bilayers of PSS/Al2O3 thin films with three slides at an initial fluoride concentration of 5 mg L-1 are used, thereby bringing down the fluoride concentration level below the World Health Organization permissible limit. Fluorides 17-25 L1 cell adhesion molecule Homo sapiens 142-145 31565320-7 2018 A 68% removal of fluoride is observed when 20 bilayers of PSS/Al2O3 thin films with three slides at an initial fluoride concentration of 5 mg L-1 are used, thereby bringing down the fluoride concentration level below the World Health Organization permissible limit. styrenesulfonic acid polymer 58-61 L1 cell adhesion molecule Homo sapiens 142-145 31565320-7 2018 A 68% removal of fluoride is observed when 20 bilayers of PSS/Al2O3 thin films with three slides at an initial fluoride concentration of 5 mg L-1 are used, thereby bringing down the fluoride concentration level below the World Health Organization permissible limit. Aluminum 62-67 L1 cell adhesion molecule Homo sapiens 142-145 28918289-7 2017 Moreover, high concentrations of HA (10 mgTOC L-1), which notably complexes with and dissolves nMnO2 (more than 78%), resulted in higher residual Tl(I) and Tl(III). nmno2 95-100 L1 cell adhesion molecule Homo sapiens 46-49 28948427-3 2017 The results showed that 47-89% Fe(III) reduction by ascorbic acid caused approximately 10-69% (~ 37-260 mg L-1) arsenic release and 4.5-63% (~ 13-176 mg L-1) Fe(II) release at pH 5-8. ferric sulfate 31-38 L1 cell adhesion molecule Homo sapiens 107-110 28948427-3 2017 The results showed that 47-89% Fe(III) reduction by ascorbic acid caused approximately 10-69% (~ 37-260 mg L-1) arsenic release and 4.5-63% (~ 13-176 mg L-1) Fe(II) release at pH 5-8. ferric sulfate 31-38 L1 cell adhesion molecule Homo sapiens 153-156 28948427-3 2017 The results showed that 47-89% Fe(III) reduction by ascorbic acid caused approximately 10-69% (~ 37-260 mg L-1) arsenic release and 4.5-63% (~ 13-176 mg L-1) Fe(II) release at pH 5-8. Ascorbic Acid 52-65 L1 cell adhesion molecule Homo sapiens 107-110 28948427-3 2017 The results showed that 47-89% Fe(III) reduction by ascorbic acid caused approximately 10-69% (~ 37-260 mg L-1) arsenic release and 4.5-63% (~ 13-176 mg L-1) Fe(II) release at pH 5-8. Ascorbic Acid 52-65 L1 cell adhesion molecule Homo sapiens 153-156 28112035-7 2017 Glyphosate concentration (C0 = 16.9 mg L-1) decreased up to 0.6 mg L-1 when the optimal conditions were imposed (current intensity of 4.77 A and treatment time of 173 min). glyphosate 0-10 L1 cell adhesion molecule Homo sapiens 67-70 28112035-7 2017 Glyphosate concentration (C0 = 16.9 mg L-1) decreased up to 0.6 mg L-1 when the optimal conditions were imposed (current intensity of 4.77 A and treatment time of 173 min). c0 26-28 L1 cell adhesion molecule Homo sapiens 39-42 28112035-7 2017 Glyphosate concentration (C0 = 16.9 mg L-1) decreased up to 0.6 mg L-1 when the optimal conditions were imposed (current intensity of 4.77 A and treatment time of 173 min). c0 26-28 L1 cell adhesion molecule Homo sapiens 67-70 29236023-5 2017 Conversely, the carbon supply shortage, under low C/N ratios, increased N2O emission (0.040 mgN2O-N L-1), due to incomplete denitrification. Carbon 16-22 L1 cell adhesion molecule Homo sapiens 100-103 29236023-5 2017 Conversely, the carbon supply shortage, under low C/N ratios, increased N2O emission (0.040 mgN2O-N L-1), due to incomplete denitrification. Nitrous Oxide 72-75 L1 cell adhesion molecule Homo sapiens 100-103 29236023-3 2017 N2O production was 2.06 mg L-1 during the anoxic phase, with N2O emission during air pulses and the aeration phase of 1.6% of the nitrogen loading rate. Nitrous Oxide 0-3 L1 cell adhesion molecule Homo sapiens 27-30 29236023-4 2017 Batch tests with AGS from the pilot reactor verified that at the greatest COD/N ratio (1.55), the N2O production (1.08 mgN2O-N L-1) and consumption (up to 0.05 mgN2O-N L-1), resulted in the lowest remaining dissolved N2O (0.03 mgN2O-N L-1), stripping the minimum N2O gas (0.018 mgN2O-N L-1). Nitrogen 78-79 L1 cell adhesion molecule Homo sapiens 127-130 29185908-3 2017 The highest specific growth rate of 0.0206 and 0.019 hr-1 was observed at 60 g L-1 of gluconate and 10 g L-1 of methanol, respectively. gluconic acid 86-95 L1 cell adhesion molecule Homo sapiens 79-82 29236023-4 2017 Batch tests with AGS from the pilot reactor verified that at the greatest COD/N ratio (1.55), the N2O production (1.08 mgN2O-N L-1) and consumption (up to 0.05 mgN2O-N L-1), resulted in the lowest remaining dissolved N2O (0.03 mgN2O-N L-1), stripping the minimum N2O gas (0.018 mgN2O-N L-1). Nitrous Oxide 98-101 L1 cell adhesion molecule Homo sapiens 127-130 29236023-4 2017 Batch tests with AGS from the pilot reactor verified that at the greatest COD/N ratio (1.55), the N2O production (1.08 mgN2O-N L-1) and consumption (up to 0.05 mgN2O-N L-1), resulted in the lowest remaining dissolved N2O (0.03 mgN2O-N L-1), stripping the minimum N2O gas (0.018 mgN2O-N L-1). Nitrous Oxide 98-101 L1 cell adhesion molecule Homo sapiens 168-171 29236023-4 2017 Batch tests with AGS from the pilot reactor verified that at the greatest COD/N ratio (1.55), the N2O production (1.08 mgN2O-N L-1) and consumption (up to 0.05 mgN2O-N L-1), resulted in the lowest remaining dissolved N2O (0.03 mgN2O-N L-1), stripping the minimum N2O gas (0.018 mgN2O-N L-1). Nitrous Oxide 98-101 L1 cell adhesion molecule Homo sapiens 168-171 29236023-4 2017 Batch tests with AGS from the pilot reactor verified that at the greatest COD/N ratio (1.55), the N2O production (1.08 mgN2O-N L-1) and consumption (up to 0.05 mgN2O-N L-1), resulted in the lowest remaining dissolved N2O (0.03 mgN2O-N L-1), stripping the minimum N2O gas (0.018 mgN2O-N L-1). Nitrous Oxide 98-101 L1 cell adhesion molecule Homo sapiens 168-171 29185908-3 2017 The highest specific growth rate of 0.0206 and 0.019 hr-1 was observed at 60 g L-1 of gluconate and 10 g L-1 of methanol, respectively. Methanol 112-120 L1 cell adhesion molecule Homo sapiens 79-82 29185908-3 2017 The highest specific growth rate of 0.0206 and 0.019 hr-1 was observed at 60 g L-1 of gluconate and 10 g L-1 of methanol, respectively. Methanol 112-120 L1 cell adhesion molecule Homo sapiens 105-108 28980361-4 2017 By using highly soluble FeCl2 /ZnBr2 species, a charge energy density of 56.30 Wh L-1 can be achieved. ferrous chloride 24-29 L1 cell adhesion molecule Homo sapiens 82-85 28980361-4 2017 By using highly soluble FeCl2 /ZnBr2 species, a charge energy density of 56.30 Wh L-1 can be achieved. Zinc bromide (ZnBr2) 31-36 L1 cell adhesion molecule Homo sapiens 82-85 29124366-5 2017 The water temperatures are consistently above 25 C, which impairs dissolved oxygen levels (3.1 to 6.7 mg L-1) and may suggest eutrophication. Water 4-9 L1 cell adhesion molecule Homo sapiens 106-109 29087184-6 2017 The superoxide dismutase (SOD) activities of the Cu2+/Cu2+ and Cu2+/Zn2+ complexes of L1 and L2 have been evaluated using nitro blue tetrazolium assays at pH 7.4. cupric ion 49-53 L1 cell adhesion molecule Homo sapiens 86-95 29087184-6 2017 The superoxide dismutase (SOD) activities of the Cu2+/Cu2+ and Cu2+/Zn2+ complexes of L1 and L2 have been evaluated using nitro blue tetrazolium assays at pH 7.4. Zinc 68-72 L1 cell adhesion molecule Homo sapiens 86-95 29087184-6 2017 The superoxide dismutase (SOD) activities of the Cu2+/Cu2+ and Cu2+/Zn2+ complexes of L1 and L2 have been evaluated using nitro blue tetrazolium assays at pH 7.4. Nitroblue Tetrazolium 122-144 L1 cell adhesion molecule Homo sapiens 86-95 29087184-8 2017 Interestingly, the binuclear Cu2+ complexes of L1 and L2 have low toxicity in cultures of mammalian cell lines and show significant antioxidant activity in a copper-dependent SOD (SOD1)-defective yeast model. cupric ion 29-33 L1 cell adhesion molecule Homo sapiens 47-56 29087184-8 2017 Interestingly, the binuclear Cu2+ complexes of L1 and L2 have low toxicity in cultures of mammalian cell lines and show significant antioxidant activity in a copper-dependent SOD (SOD1)-defective yeast model. Copper 158-164 L1 cell adhesion molecule Homo sapiens 47-56 29038812-2 2017 Then, on treatment with NaOAc and Li2PdCl4, palladacycles, [Pd(L1-H/L2-H)Cl] (1/2) were formed at room temperature, in which L1/L2 are ligated as an unsymmetric (C-, N, E) pincer. Sodium Acetate 24-29 L1 cell adhesion molecule Homo sapiens 125-130 29038812-2 2017 Then, on treatment with NaOAc and Li2PdCl4, palladacycles, [Pd(L1-H/L2-H)Cl] (1/2) were formed at room temperature, in which L1/L2 are ligated as an unsymmetric (C-, N, E) pincer. Li2PdCl4 34-42 L1 cell adhesion molecule Homo sapiens 125-130 29038812-4 2017 The reactions of L3/L4 at room temperature, similar to those of L1/L2, resulted in the formation of complex [Pd(L3/L4)Cl2] (3/4), in which the ligand is coordinated in a bidentate (N, E) mode. [pd(l3/l4)cl2 108-121 L1 cell adhesion molecule Homo sapiens 64-69 29965398-2 2017 These results showed that macrolides have the highest average concentration of all antibiotics in the surface water of the LRB of 201.88 ng L-1, followed by quinolones, trimethoprim, and sulfonamides with average concentrations of 113.40 ng L-1, 93.93 ng L-1, and 124.27 ng L-1, respectively. Macrolides 26-36 L1 cell adhesion molecule Homo sapiens 140-143 29965398-2 2017 These results showed that macrolides have the highest average concentration of all antibiotics in the surface water of the LRB of 201.88 ng L-1, followed by quinolones, trimethoprim, and sulfonamides with average concentrations of 113.40 ng L-1, 93.93 ng L-1, and 124.27 ng L-1, respectively. Macrolides 26-36 L1 cell adhesion molecule Homo sapiens 241-244 29965398-2 2017 These results showed that macrolides have the highest average concentration of all antibiotics in the surface water of the LRB of 201.88 ng L-1, followed by quinolones, trimethoprim, and sulfonamides with average concentrations of 113.40 ng L-1, 93.93 ng L-1, and 124.27 ng L-1, respectively. Macrolides 26-36 L1 cell adhesion molecule Homo sapiens 241-244 29965398-2 2017 These results showed that macrolides have the highest average concentration of all antibiotics in the surface water of the LRB of 201.88 ng L-1, followed by quinolones, trimethoprim, and sulfonamides with average concentrations of 113.40 ng L-1, 93.93 ng L-1, and 124.27 ng L-1, respectively. Macrolides 26-36 L1 cell adhesion molecule Homo sapiens 241-244 29965398-2 2017 These results showed that macrolides have the highest average concentration of all antibiotics in the surface water of the LRB of 201.88 ng L-1, followed by quinolones, trimethoprim, and sulfonamides with average concentrations of 113.40 ng L-1, 93.93 ng L-1, and 124.27 ng L-1, respectively. Water 110-115 L1 cell adhesion molecule Homo sapiens 140-143 29965398-3 2017 Tetracycline demonstrated the lowest concentration at 24.37 ng L-1. Tetracycline 0-12 L1 cell adhesion molecule Homo sapiens 63-66 29124366-5 2017 The water temperatures are consistently above 25 C, which impairs dissolved oxygen levels (3.1 to 6.7 mg L-1) and may suggest eutrophication. Oxygen 77-83 L1 cell adhesion molecule Homo sapiens 106-109 29071365-8 2017 The proposed analytical method was applied to the analysis of surface water samples, containing concentrations of these contaminants ranging from 100 ng L-1 to 2 mug L-1. Water 70-75 L1 cell adhesion molecule Homo sapiens 153-161 28780371-4 2017 Modelling indicates that aqueous uranium accumulates in parallel with total dissolved solids (or groundwater mineralisation M - regarded as an indicator of degree of hydrochemical evolution), accumulating most rapidly when M = 550-1000 mg L-1. Uranium 33-40 L1 cell adhesion molecule Homo sapiens 239-242 28825291-5 2017 The optimal concentration for the Ni NPs suspension was determined to be 30 mg L-1; increasing the concentration up to 30 mg L-1 showed a significant increase in the dissolution of CO2 bubbles, but increasing from 30 to 50 mg L-1 displayed a decrease in catalytic potential, due to the decreased translational diffusion coefficient that occurs at higher concentrations. Carbon Dioxide 181-184 L1 cell adhesion molecule Homo sapiens 79-82 29068421-7 2017 The Cu(II)-ligands, given here, present the highest catalytic activity (72.920 mumol L-1 min-1) among the catalysts recently reported in the existing literature. cu(ii) 4-10 L1 cell adhesion molecule Homo sapiens 85-94 31457282-1 2017 Structures of different solvates and solute-solvent interactions of 4-(3-(4-nitrophenyl)urido)benzoate (L 1 ) and methyl-4-(3-(4-nitrophenyl)thiourido)benzoate (L 2 ) with different solvents are analyzed. 4-(3-(4-nitrophenyl)urido)benzoate 68-102 L1 cell adhesion molecule Homo sapiens 104-107 31457282-2 2017 The solution of L 1 with tetrabutylammonium acetate (TBAA) in dimethylsulfoxide (DMSO) is colorless, but a similar solution of L 2 with TBAA is orange. Tetrabutylammonium acetate 25-51 L1 cell adhesion molecule Homo sapiens 16-19 31457282-2 2017 The solution of L 1 with tetrabutylammonium acetate (TBAA) in dimethylsulfoxide (DMSO) is colorless, but a similar solution of L 2 with TBAA is orange. tert-butyl acetoacetate 53-57 L1 cell adhesion molecule Homo sapiens 16-19 31457282-2 2017 The solution of L 1 with tetrabutylammonium acetate (TBAA) in dimethylsulfoxide (DMSO) is colorless, but a similar solution of L 2 with TBAA is orange. Dimethyl Sulfoxide 62-79 L1 cell adhesion molecule Homo sapiens 16-19 31457282-2 2017 The solution of L 1 with tetrabutylammonium acetate (TBAA) in dimethylsulfoxide (DMSO) is colorless, but a similar solution of L 2 with TBAA is orange. Dimethyl Sulfoxide 81-85 L1 cell adhesion molecule Homo sapiens 16-19 31457282-4 2017 Urea derivative L 1 facilitates the reaction of TBAF with glass to form tetrabutylammonium hexafluorosilicate, which on further interaction with L 1 forms cocrystal 2L 1 (TBA)2SiF6. Urea 0-4 L1 cell adhesion molecule Homo sapiens 16-19 31457282-4 2017 Urea derivative L 1 facilitates the reaction of TBAF with glass to form tetrabutylammonium hexafluorosilicate, which on further interaction with L 1 forms cocrystal 2L 1 (TBA)2SiF6. Urea 0-4 L1 cell adhesion molecule Homo sapiens 145-148 31457282-4 2017 Urea derivative L 1 facilitates the reaction of TBAF with glass to form tetrabutylammonium hexafluorosilicate, which on further interaction with L 1 forms cocrystal 2L 1 (TBA)2SiF6. tetrabutylammonium 48-52 L1 cell adhesion molecule Homo sapiens 16-19 31457282-4 2017 Urea derivative L 1 facilitates the reaction of TBAF with glass to form tetrabutylammonium hexafluorosilicate, which on further interaction with L 1 forms cocrystal 2L 1 (TBA)2SiF6. tetrabutylammonium 48-52 L1 cell adhesion molecule Homo sapiens 145-148 31457282-4 2017 Urea derivative L 1 facilitates the reaction of TBAF with glass to form tetrabutylammonium hexafluorosilicate, which on further interaction with L 1 forms cocrystal 2L 1 (TBA)2SiF6. tetrabutylammonium hexafluorosilicate 72-109 L1 cell adhesion molecule Homo sapiens 16-19 31457282-4 2017 Urea derivative L 1 facilitates the reaction of TBAF with glass to form tetrabutylammonium hexafluorosilicate, which on further interaction with L 1 forms cocrystal 2L 1 (TBA)2SiF6. tetrabutylammonium hexafluorosilicate 72-109 L1 cell adhesion molecule Homo sapiens 145-148 31457282-7 2017 Solvates of L 1 with DMSO, dimethylformamide (DMF), and dimethylacetamide are quasi-isostructural. Dimethyl Sulfoxide 21-25 L1 cell adhesion molecule Homo sapiens 12-15 31457282-7 2017 Solvates of L 1 with DMSO, dimethylformamide (DMF), and dimethylacetamide are quasi-isostructural. Dimethylformamide 27-44 L1 cell adhesion molecule Homo sapiens 12-15 31457282-7 2017 Solvates of L 1 with DMSO, dimethylformamide (DMF), and dimethylacetamide are quasi-isostructural. Dimethylformamide 46-49 L1 cell adhesion molecule Homo sapiens 12-15 31457282-7 2017 Solvates of L 1 with DMSO, dimethylformamide (DMF), and dimethylacetamide are quasi-isostructural. dimethylacetamide 56-73 L1 cell adhesion molecule Homo sapiens 12-15 31457282-9 2017 Significant differences in self-assemblies of the respective DMSO solvate of L 1 and L 2 are observed; self-assembly of the former has dimeric subassemblies as repeat units, whereas the latter has monomeric subassemblies. Dimethyl Sulfoxide 61-65 L1 cell adhesion molecule Homo sapiens 77-88 31457282-10 2017 DMF solvates of L 1 and dimethylacetamide of L 1 are built by dimeric subassemblies to form self-assembled structures, but these subassemblies differ in the orientation of the carbomethoxy group across the urea units. Dimethylformamide 0-3 L1 cell adhesion molecule Homo sapiens 16-48 31457282-10 2017 DMF solvates of L 1 and dimethylacetamide of L 1 are built by dimeric subassemblies to form self-assembled structures, but these subassemblies differ in the orientation of the carbomethoxy group across the urea units. Urea 206-210 L1 cell adhesion molecule Homo sapiens 16-48 28825291-5 2017 The optimal concentration for the Ni NPs suspension was determined to be 30 mg L-1; increasing the concentration up to 30 mg L-1 showed a significant increase in the dissolution of CO2 bubbles, but increasing from 30 to 50 mg L-1 displayed a decrease in catalytic potential, due to the decreased translational diffusion coefficient that occurs at higher concentrations. Carbon Dioxide 181-184 L1 cell adhesion molecule Homo sapiens 125-128 28825291-5 2017 The optimal concentration for the Ni NPs suspension was determined to be 30 mg L-1; increasing the concentration up to 30 mg L-1 showed a significant increase in the dissolution of CO2 bubbles, but increasing from 30 to 50 mg L-1 displayed a decrease in catalytic potential, due to the decreased translational diffusion coefficient that occurs at higher concentrations. Carbon Dioxide 181-184 L1 cell adhesion molecule Homo sapiens 125-128 28956596-2 2017 The ligand L1 and complexes 1 and 2 have been meticulously characterized by elemental analyses and spectral studies (IR, electrospray ionization mass spectrometry, 1H and 13C NMR, UV/vis, fluorescence) and their structures explicitly authenticated by single-crystal X-ray analyses. Hydrogen 164-166 L1 cell adhesion molecule Homo sapiens 11-35 28956596-2 2017 The ligand L1 and complexes 1 and 2 have been meticulously characterized by elemental analyses and spectral studies (IR, electrospray ionization mass spectrometry, 1H and 13C NMR, UV/vis, fluorescence) and their structures explicitly authenticated by single-crystal X-ray analyses. 13c 171-174 L1 cell adhesion molecule Homo sapiens 11-35 28668632-7 2017 In contrast, marine stations had concentrations of coprostanol lower than a suggested regulation limit for tropical marine coastal waters (30 ng L-1), ranging between 6 and 28 ng L-1. Cholestanol 51-62 L1 cell adhesion molecule Homo sapiens 145-148 28668632-8 2017 During the rainy season a dilution effect was detected in the river, however significantly higher concentrations of coprostanol in the marine stations were detected ranging between 15 and 215 ng L-1, higher than the tentative tropical regulation range (30-100 ng L-1). Cholestanol 116-127 L1 cell adhesion molecule Homo sapiens 195-198 28668632-8 2017 During the rainy season a dilution effect was detected in the river, however significantly higher concentrations of coprostanol in the marine stations were detected ranging between 15 and 215 ng L-1, higher than the tentative tropical regulation range (30-100 ng L-1). Cholestanol 116-127 L1 cell adhesion molecule Homo sapiens 263-266 28959998-4 2017 Thus, a sensing platform for the determination of urea and urease was successfully constructed, with the limits of detection for urea and urease being 27 muM and 2.6 U L-1, respectively. Urea 50-54 L1 cell adhesion molecule Homo sapiens 168-171 28668632-5 2017 The concentration of coprostanol in the SPM was 3621 +- 98 ng L-1 comprising 26% of total sterols. Cholestanol 21-32 L1 cell adhesion molecule Homo sapiens 62-65 28668632-6 2017 During the dry season, the river was contaminated upstream with human feces as evidenced by coprostanol at 1823 ng L-1, the 5beta-coprostanol: cholesterol ratio at 0.5, and 5beta-coprostanol: [5alpha-cholestanol+5beta-coprostanol] at 0.7. Cholestanol 92-103 L1 cell adhesion molecule Homo sapiens 115-118 28689149-6 2017 These upward trends in ANC were limited by coincident decreases in base cations (-1.3 mueq L-1 yr-1 for calcium + magnesium). Calcium 104-111 L1 cell adhesion molecule Homo sapiens 91-99 28689149-6 2017 These upward trends in ANC were limited by coincident decreases in base cations (-1.3 mueq L-1 yr-1 for calcium + magnesium). Magnesium 114-123 L1 cell adhesion molecule Homo sapiens 91-99 28689149-9 2017 Tightly coupled decreasing trends in stream-water silicon (Si) (-0.2 mueq L-1 yr-1) and base cations suggest a decrease in the soil mineral weathering rate. Water 44-49 L1 cell adhesion molecule Homo sapiens 74-82 28689149-9 2017 Tightly coupled decreasing trends in stream-water silicon (Si) (-0.2 mueq L-1 yr-1) and base cations suggest a decrease in the soil mineral weathering rate. Silicon 50-57 L1 cell adhesion molecule Homo sapiens 74-82 28689149-9 2017 Tightly coupled decreasing trends in stream-water silicon (Si) (-0.2 mueq L-1 yr-1) and base cations suggest a decrease in the soil mineral weathering rate. Silicon 59-61 L1 cell adhesion molecule Homo sapiens 74-82 28512780-1 2017 Novel chiral fluorescence sensors L-1 and D-1 incorporating N-Boc-protected alanine and acridine moieties were synthesized. Alanine 76-83 L1 cell adhesion molecule Homo sapiens 34-65 28512780-1 2017 Novel chiral fluorescence sensors L-1 and D-1 incorporating N-Boc-protected alanine and acridine moieties were synthesized. Acridines 88-96 L1 cell adhesion molecule Homo sapiens 34-65 28601007-4 2017 While the total I-THM concentrations ranged from 128 to 967 ng L-1 in Taihu Lake and 267-680 ng L-1 in the Huangpu River. i-thm 16-21 L1 cell adhesion molecule Homo sapiens 63-66 28601007-10 2017 Strikingly high concentrations of total I-THMs were observed in the finished water (2848 ng L-1 in conventional DWTP and 356 ng L-1 in advanced DWTP). i-thms 40-46 L1 cell adhesion molecule Homo sapiens 92-95 28601007-10 2017 Strikingly high concentrations of total I-THMs were observed in the finished water (2848 ng L-1 in conventional DWTP and 356 ng L-1 in advanced DWTP). i-thms 40-46 L1 cell adhesion molecule Homo sapiens 128-131 28601007-10 2017 Strikingly high concentrations of total I-THMs were observed in the finished water (2848 ng L-1 in conventional DWTP and 356 ng L-1 in advanced DWTP). Water 77-82 L1 cell adhesion molecule Homo sapiens 92-95 28959998-4 2017 Thus, a sensing platform for the determination of urea and urease was successfully constructed, with the limits of detection for urea and urease being 27 muM and 2.6 U L-1, respectively. Urea 59-63 L1 cell adhesion molecule Homo sapiens 168-171 28792450-2 2017 The limits of detection and quantification were 25 and 80 microg L-1 for Zn(II), 3 and 10 microg L-1 for Cd(II), 3 and 10 microg L-1 for Pb(II), 3 and 10 microg L-1 for Cu(II), and 3 and 10 microg L-1 for Ag(I), respectively. Cadmium 105-107 L1 cell adhesion molecule Homo sapiens 97-100 28575712-5 2017 Quasi-complete increases in fluorescence intensity and chromophoric DOM (CDOM) abundance were reached after 90, 60, and 50 min irradiation for TiO2 concentrations of 0, 2, and 5 mg L-1, respectively. titanium dioxide 143-147 L1 cell adhesion molecule Homo sapiens 181-184 28849809-10 2017 Comparison of the stability constants of the ligand L1 and L2 complexes clearly revealed that the higher electron-donating ability of the hexyl with respect to the methyl group is of considerable importance in determining the equilibria of the complexation reactions. dipicrylamine 138-143 L1 cell adhesion molecule Homo sapiens 52-61 29965258-3 2017 After biofilm formation and the biochemical system startup and operation by H2O2, the system was successfully started and steadily operated when H2O2was added into reactor A with the H2O2 voluve fraction of 3 mL L-1, doses of 100.0 mL, the flow velocity of 0.67 mL min-1, and dosing frequency of once a day. h2o2was 145-152 L1 cell adhesion molecule Homo sapiens 212-215 29965258-3 2017 After biofilm formation and the biochemical system startup and operation by H2O2, the system was successfully started and steadily operated when H2O2was added into reactor A with the H2O2 voluve fraction of 3 mL L-1, doses of 100.0 mL, the flow velocity of 0.67 mL min-1, and dosing frequency of once a day. Hydrogen Peroxide 145-149 L1 cell adhesion molecule Homo sapiens 212-215 29965259-3 2017 The results showed that the average effluent concentration of soluble phosphorus under different influent C/N conditions were 0.22, 0.34, 0.39, 0.42, and 2.45 mg L-1 and the low influent C/N ratio was beneficial to phosphate removal. Phosphorus 70-80 L1 cell adhesion molecule Homo sapiens 162-165 28570896-1 2017 A mechano-/photo- bi-catalyst of piezoelectric-ZnO@photoelectric-TiO2 core-shell nanofibers was hydrothermally synthesized for Methyl Orange (10 mg L-1) decomposition. Zinc Oxide 47-50 L1 cell adhesion molecule Homo sapiens 148-151 28570896-1 2017 A mechano-/photo- bi-catalyst of piezoelectric-ZnO@photoelectric-TiO2 core-shell nanofibers was hydrothermally synthesized for Methyl Orange (10 mg L-1) decomposition. titanium dioxide 65-69 L1 cell adhesion molecule Homo sapiens 148-151 28570896-1 2017 A mechano-/photo- bi-catalyst of piezoelectric-ZnO@photoelectric-TiO2 core-shell nanofibers was hydrothermally synthesized for Methyl Orange (10 mg L-1) decomposition. methyl orange 127-140 L1 cell adhesion molecule Homo sapiens 148-151 28525809-3 2017 85.78% degradation efficiency for 20 mg L-1 paraquat was achieved in the modified process under desired operational conditions (i.e. current intensity of 300 mA, catalyst amount of 1 g L-1, pH = 6, and background electrolyte (Na2SO4) concentration of 0.05 mol L-1) which was higher than the 41.03% for the unmodified one after 150 min of treatment. Paraquat 44-52 L1 cell adhesion molecule Homo sapiens 40-43 28525809-3 2017 85.78% degradation efficiency for 20 mg L-1 paraquat was achieved in the modified process under desired operational conditions (i.e. current intensity of 300 mA, catalyst amount of 1 g L-1, pH = 6, and background electrolyte (Na2SO4) concentration of 0.05 mol L-1) which was higher than the 41.03% for the unmodified one after 150 min of treatment. Paraquat 44-52 L1 cell adhesion molecule Homo sapiens 185-188 28525809-3 2017 85.78% degradation efficiency for 20 mg L-1 paraquat was achieved in the modified process under desired operational conditions (i.e. current intensity of 300 mA, catalyst amount of 1 g L-1, pH = 6, and background electrolyte (Na2SO4) concentration of 0.05 mol L-1) which was higher than the 41.03% for the unmodified one after 150 min of treatment. Paraquat 44-52 L1 cell adhesion molecule Homo sapiens 185-188 28525809-3 2017 85.78% degradation efficiency for 20 mg L-1 paraquat was achieved in the modified process under desired operational conditions (i.e. current intensity of 300 mA, catalyst amount of 1 g L-1, pH = 6, and background electrolyte (Na2SO4) concentration of 0.05 mol L-1) which was higher than the 41.03% for the unmodified one after 150 min of treatment. sodium sulfate 226-232 L1 cell adhesion molecule Homo sapiens 40-43 28722398-2 2017 Due to a nascent barrier layer with a loose architecture, the obtained TFC-BDSA-0.2 membrane showed an ultrahigh pure water permeability of 48.1 +- 2.1 L-1 m-2 h-1 bar-1, and a considerably low NaCl retention ability of <1.8% over a concentration range of 10-100 g L-1. Water 118-123 L1 cell adhesion molecule Homo sapiens 152-155 28574600-9 2017 The expressions of L1CAM, VEGF-A, and EMT-related proteins (Slug, Snail, MMP-2) were inhibited by DATS. diallyl trisulfide 98-102 L1 cell adhesion molecule Homo sapiens 19-24 28792450-2 2017 The limits of detection and quantification were 25 and 80 microg L-1 for Zn(II), 3 and 10 microg L-1 for Cd(II), 3 and 10 microg L-1 for Pb(II), 3 and 10 microg L-1 for Cu(II), and 3 and 10 microg L-1 for Ag(I), respectively. Cadmium 105-107 L1 cell adhesion molecule Homo sapiens 97-100 28792450-2 2017 The limits of detection and quantification were 25 and 80 microg L-1 for Zn(II), 3 and 10 microg L-1 for Cd(II), 3 and 10 microg L-1 for Pb(II), 3 and 10 microg L-1 for Cu(II), and 3 and 10 microg L-1 for Ag(I), respectively. Cadmium 105-107 L1 cell adhesion molecule Homo sapiens 97-100 28792450-2 2017 The limits of detection and quantification were 25 and 80 microg L-1 for Zn(II), 3 and 10 microg L-1 for Cd(II), 3 and 10 microg L-1 for Pb(II), 3 and 10 microg L-1 for Cu(II), and 3 and 10 microg L-1 for Ag(I), respectively. Cadmium 105-107 L1 cell adhesion molecule Homo sapiens 97-100 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Cadmium 68-75 L1 cell adhesion molecule Homo sapiens 154-157 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Cadmium 68-75 L1 cell adhesion molecule Homo sapiens 180-183 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Cadmium 68-75 L1 cell adhesion molecule Homo sapiens 180-183 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Cadmium 68-75 L1 cell adhesion molecule Homo sapiens 180-183 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Copper 77-83 L1 cell adhesion molecule Homo sapiens 154-157 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Copper 77-83 L1 cell adhesion molecule Homo sapiens 180-183 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Copper 77-83 L1 cell adhesion molecule Homo sapiens 180-183 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Copper 77-83 L1 cell adhesion molecule Homo sapiens 180-183 28792450-4 2017 The limits of detection for the simultaneous determination of zinc, cadmium, copper and lead on the screen printed electrodes were found to be 350 microg L-1 for Zn(II), 25 microg L-1 for Cd(II), 3 microg L-1 for Pb(II) and 3 microg L-1 for Cu(II). Zinc 162-168 L1 cell adhesion molecule Homo sapiens 154-157 28664333-2 2017 An electrochemically pretreated pencil-graphite electrode was prepared by performing potential cycling between -0.3 V and 2.0 V in 0.1 mol L-1 H3PO4 solution to improve its ability to electrochemically sense Pb2+ and Cd2+ ions. Graphite 39-47 L1 cell adhesion molecule Homo sapiens 139-142 28664333-2 2017 An electrochemically pretreated pencil-graphite electrode was prepared by performing potential cycling between -0.3 V and 2.0 V in 0.1 mol L-1 H3PO4 solution to improve its ability to electrochemically sense Pb2+ and Cd2+ ions. phosphoric acid 143-148 L1 cell adhesion molecule Homo sapiens 139-142 28664333-9 2017 Under the optimized conditions, the limits of detection were 0.46 mug L-1 for Pb2+ and 1.11 mug L-1 for Cd2+ using the electrode. Lead 78-82 L1 cell adhesion molecule Homo sapiens 70-73 28664333-11 2017 The linear working ranges of the electrode for Pb2+ and Cd2+ ion detection were 5-45 mug L-1 and 10-40 mug L-1, respectively. Lead 47-51 L1 cell adhesion molecule Homo sapiens 89-110 28648922-1 2017 Two novel oxovanadium(IV) complexes [VOL1]SO4(1) and [VOL2]SO4(2) containing Knoevenagel condensate Schiff base ligand (L1/L2) have been synthesized and characterized by physical, spectral and analytical methods. Vanadium(II) oxide 10-21 L1 cell adhesion molecule Homo sapiens 120-125 28648922-1 2017 Two novel oxovanadium(IV) complexes [VOL1]SO4(1) and [VOL2]SO4(2) containing Knoevenagel condensate Schiff base ligand (L1/L2) have been synthesized and characterized by physical, spectral and analytical methods. Schiff Bases 100-111 L1 cell adhesion molecule Homo sapiens 120-125 28597602-8 2017 As for low-weight biotin molecule, the detection limit is estimated below 1 x 10-15 m (1 x 10-15 mol L-1 , 1300 biotin mm-2 ). Biotin 18-24 L1 cell adhesion molecule Homo sapiens 101-104 28575701-4 2017 The analysis revealed that an optimum in oxalic acid degradation is observed when the TiO2 concentration was controlled in the 20-40 mg L-1 range (depending on lamp irradiance). Oxalic Acid 41-52 L1 cell adhesion molecule Homo sapiens 136-139 28575701-4 2017 The analysis revealed that an optimum in oxalic acid degradation is observed when the TiO2 concentration was controlled in the 20-40 mg L-1 range (depending on lamp irradiance). titanium dioxide 86-90 L1 cell adhesion molecule Homo sapiens 136-139 28425679-8 2017 Nonspecific interactions destabilize ACTR helicity in 300 g L-1 Ficoll because ACTR engages with the Ficoll polymer mesh. Polymers 108-115 L1 cell adhesion molecule Homo sapiens 60-63 28597602-8 2017 As for low-weight biotin molecule, the detection limit is estimated below 1 x 10-15 m (1 x 10-15 mol L-1 , 1300 biotin mm-2 ). Biotin 112-118 L1 cell adhesion molecule Homo sapiens 101-104 28814831-7 2017 The molecular docking revealed weak interaction between L1/L2 and P-glycoprotein (P-gp), the most important drug efflux pump and intracellular Rhodamine 123 accumulation indicated that the activity of P-gp was not inhibited by L1 and L2. Rhodamine 123 143-156 L1 cell adhesion molecule Homo sapiens 56-61 28410517-5 2017 Results revealed that the adsorption was more efficient at the etheramine concentration of 400 mg L-1, pH 10 and adsorbent mass of 0.1 g for NK and 0.2 g for KA-01, KA-02 and KA-05. etheramine 63-73 L1 cell adhesion molecule Homo sapiens 98-101 28605894-6 2017 Furthermore, the volumetric energy density of assembled holey graphene/PPy film symmetric supercapacitor can show high as 22.3 Wh L-1. Graphite 62-70 L1 cell adhesion molecule Homo sapiens 130-133 28437020-4 2017 Experimental and theoretical evidence support that the metal-reduced [CoI (L1 )]- is in tautomeric equilibrium with the ligand-reduced [CoII (L1. )]- species. Metals 55-60 L1 cell adhesion molecule Homo sapiens 142-145 29964620-2 2017 DGT-P ranged from 0.00 mg L-1 to 0.43 mg L-1. deoxyguanosine triphosphate 0-5 L1 cell adhesion molecule Homo sapiens 26-29 29964620-2 2017 DGT-P ranged from 0.00 mg L-1 to 0.43 mg L-1. deoxyguanosine triphosphate 0-5 L1 cell adhesion molecule Homo sapiens 41-44 29964620-4 2017 DGT-S ranged from 0.00 mg L-1 to 0.10 mg L-1. dgt-s 0-5 L1 cell adhesion molecule Homo sapiens 26-29 29964620-4 2017 DGT-S ranged from 0.00 mg L-1 to 0.10 mg L-1. dgt-s 0-5 L1 cell adhesion molecule Homo sapiens 41-44 28581287-5 2017 This method is appropriate for routine environmental monitoring and drinking water quality assessment since the guideline value set by the US Environmental Protection Agency (EPA) for inorganic mercury in drinking water is 0.002 mg L-1 (10 nM). Mercury 194-201 L1 cell adhesion molecule Homo sapiens 232-235 28557454-3 2017 Coupling an iron mineral cathode with metallic lead in a galvanic cell increased lead release by 531 mug L-1 on average-a 9-fold increase over uniform corrosion in the absence of iron. Iron 12-16 L1 cell adhesion molecule Homo sapiens 105-108 28713791-1 2017 In Europe sulfur dioxide (SO2) and sulfites in foods and beverages at concentrations of more than 10 mg kg-1 or 10 mg L-1 expressed as SO2 equivalents are subject to mandatory labelling. Sulfur Dioxide 10-24 L1 cell adhesion molecule Homo sapiens 118-121 28713791-1 2017 In Europe sulfur dioxide (SO2) and sulfites in foods and beverages at concentrations of more than 10 mg kg-1 or 10 mg L-1 expressed as SO2 equivalents are subject to mandatory labelling. Sulfur Dioxide 26-29 L1 cell adhesion molecule Homo sapiens 118-121 28506057-2 2017 The dissolved Pb2+ is readily converted to volatile species by LSDBD plasma induced chemical processes in the presence of 5% (v/v) formic acid in a supporting electrolyte (HCl, 0.01 mol L-1). Lead 14-18 L1 cell adhesion molecule Homo sapiens 186-189 28506057-5 2017 Under optimized conditions, the detection limit of Pb was found to be 0.003 mug L-1. Lead 51-53 L1 cell adhesion molecule Homo sapiens 80-83 28558203-4 2017 The beta-CD polymer reduces PFOA concentrations from 1 mug L-1 to <10 ng L-1, at least 7 times lower than the 2016 U.S. EPA advisory level (70 ng L-1), and was regenerated and reused multiple times by washing with MeOH. betadex 4-11 L1 cell adhesion molecule Homo sapiens 59-62 29965350-4 2017 The results showed that the maximum value of Chl-a in Pengxi river reached 60.5 mug L-1 in spring, and was only 7.8 mug L-1 in summer, while in Modao river the Chl-a content was 2.92 mug L-1 in spring and 7.48 mug L-1in summer. chl- 45-49 L1 cell adhesion molecule Homo sapiens 84-87 29965350-4 2017 The results showed that the maximum value of Chl-a in Pengxi river reached 60.5 mug L-1 in spring, and was only 7.8 mug L-1 in summer, while in Modao river the Chl-a content was 2.92 mug L-1 in spring and 7.48 mug L-1in summer. chl- 45-49 L1 cell adhesion molecule Homo sapiens 120-123 29965350-4 2017 The results showed that the maximum value of Chl-a in Pengxi river reached 60.5 mug L-1 in spring, and was only 7.8 mug L-1 in summer, while in Modao river the Chl-a content was 2.92 mug L-1 in spring and 7.48 mug L-1in summer. chl- 45-49 L1 cell adhesion molecule Homo sapiens 120-123 29965353-4 2017 The results showed that the concentrations of the heavy metals (Ni, Cd, Cu and Pb) was 49.27 mug L-1, 2.19 mug L-1, 12.18 mug L-1, 12.13 mug L-1(water) and 78.46 mg kg-1, 77.13 mg kg-1, 650.13 mg kg-1 and 134.22 mg kg-1 (sediment). Cadmium 68-70 L1 cell adhesion molecule Homo sapiens 97-106 29965353-4 2017 The results showed that the concentrations of the heavy metals (Ni, Cd, Cu and Pb) was 49.27 mug L-1, 2.19 mug L-1, 12.18 mug L-1, 12.13 mug L-1(water) and 78.46 mg kg-1, 77.13 mg kg-1, 650.13 mg kg-1 and 134.22 mg kg-1 (sediment). Copper 72-74 L1 cell adhesion molecule Homo sapiens 97-106 29965353-4 2017 The results showed that the concentrations of the heavy metals (Ni, Cd, Cu and Pb) was 49.27 mug L-1, 2.19 mug L-1, 12.18 mug L-1, 12.13 mug L-1(water) and 78.46 mg kg-1, 77.13 mg kg-1, 650.13 mg kg-1 and 134.22 mg kg-1 (sediment). Lead 79-81 L1 cell adhesion molecule Homo sapiens 97-106 28558203-4 2017 The beta-CD polymer reduces PFOA concentrations from 1 mug L-1 to <10 ng L-1, at least 7 times lower than the 2016 U.S. EPA advisory level (70 ng L-1), and was regenerated and reused multiple times by washing with MeOH. betadex 4-11 L1 cell adhesion molecule Homo sapiens 76-79 28621407-6 2017 Mean concentrations of Zn, Fe, and Cu in human milk samples were 5.35, 0.47 and 0.83 mg L-1, respectively while these values in infant formula were ranged from 3.52-4.75 mg L-1, 3.37-4.56 mg L-1 and 0.28-0.41 mg L-1, respectively. Zinc 23-25 L1 cell adhesion molecule Homo sapiens 88-91 28621407-6 2017 Mean concentrations of Zn, Fe, and Cu in human milk samples were 5.35, 0.47 and 0.83 mg L-1, respectively while these values in infant formula were ranged from 3.52-4.75 mg L-1, 3.37-4.56 mg L-1 and 0.28-0.41 mg L-1, respectively. Copper 35-37 L1 cell adhesion molecule Homo sapiens 88-91 28558203-4 2017 The beta-CD polymer reduces PFOA concentrations from 1 mug L-1 to <10 ng L-1, at least 7 times lower than the 2016 U.S. EPA advisory level (70 ng L-1), and was regenerated and reused multiple times by washing with MeOH. betadex 4-11 L1 cell adhesion molecule Homo sapiens 76-79 27805310-5 2017 The fluorescence of beta-CD protected Cu NCs could be quenched in the presence of GO with a lowest detection concentration of 0.1 mg L-1 . betadex 20-27 L1 cell adhesion molecule Homo sapiens 133-136 27805310-5 2017 The fluorescence of beta-CD protected Cu NCs could be quenched in the presence of GO with a lowest detection concentration of 0.1 mg L-1 . Copper 38-40 L1 cell adhesion molecule Homo sapiens 133-136 27805310-5 2017 The fluorescence of beta-CD protected Cu NCs could be quenched in the presence of GO with a lowest detection concentration of 0.1 mg L-1 . graphene oxide 82-84 L1 cell adhesion molecule Homo sapiens 133-136 28094884-1 2017 Deprotonation of ligand-appended alkoxyl groups in mononuclear copper(II) complexes of N,O ligands L1 and L2 , gave dinuclear complexes sharing symmetrical Cu2 O2 cores. cupric ion 63-73 L1 cell adhesion molecule Homo sapiens 99-108 28094884-1 2017 Deprotonation of ligand-appended alkoxyl groups in mononuclear copper(II) complexes of N,O ligands L1 and L2 , gave dinuclear complexes sharing symmetrical Cu2 O2 cores. cu2 o2 156-162 L1 cell adhesion molecule Homo sapiens 99-108 28385507-2 2017 The biological evaluation results showed that Bis(N,N"-disalicylidene)-3,4-phenylenediamine-cobalt(II) 1 and Bis(N,N"-disalicylidene)-1,2-cyclohexanediamine-cobalt(II) 2 are much more effective than the parent Schiff bases (L1 and L2). bis(n,n"-disalicylidene)-3,4-phenylenediamine-cobalt(ii) 1 46-104 L1 cell adhesion molecule Homo sapiens 224-233 28385507-2 2017 The biological evaluation results showed that Bis(N,N"-disalicylidene)-3,4-phenylenediamine-cobalt(II) 1 and Bis(N,N"-disalicylidene)-1,2-cyclohexanediamine-cobalt(II) 2 are much more effective than the parent Schiff bases (L1 and L2). bis(n,n"-disalicylidene)-1,2-cyclohexanediamine-cobalt(ii) 2 109-169 L1 cell adhesion molecule Homo sapiens 224-233 29965089-3 2017 The ranges of geometric mean values were 0-655 ng L-1 and 0-252 ng L-1 in water samples from urban rivers and lakes,respectively. Water 74-79 L1 cell adhesion molecule Homo sapiens 50-70 28187386-4 2017 The total nitrogen (TN) removal efficiency was as high as 95.8% with influent NH4+-N of 63.58 mg L-1 and NO3--N of 69.24 mg L-1. Nitrogen 10-18 L1 cell adhesion molecule Homo sapiens 124-127 28277081-6 2017 The addition of 1 mL min-1 hydrogen peroxide has shown complete CBF degradation and 76% chemical oxygen demand removal under the following operating conditions of CBF ~50 mg L-1, TiO2 ~5 mg L-1 and feed flow rate ~82.5 mL min-1. Hydrogen Peroxide 27-44 L1 cell adhesion molecule Homo sapiens 174-177 28277081-6 2017 The addition of 1 mL min-1 hydrogen peroxide has shown complete CBF degradation and 76% chemical oxygen demand removal under the following operating conditions of CBF ~50 mg L-1, TiO2 ~5 mg L-1 and feed flow rate ~82.5 mL min-1. Hydrogen Peroxide 27-44 L1 cell adhesion molecule Homo sapiens 190-193 28187386-4 2017 The total nitrogen (TN) removal efficiency was as high as 95.8% with influent NH4+-N of 63.58 mg L-1 and NO3--N of 69.24 mg L-1. Nitrogen 10-18 L1 cell adhesion molecule Homo sapiens 97-100 27566160-5 2017 Experimental design performed in this study indicated optimum condition for solar photo-Fenton reaction (20 mg L-1 of Fe2+ and 500 mg L-1 of H2O2; pH 2.8), which achieved 96 % removal of dissolved organic carbon (DOC) and 99 % absorbance removal. Carbon 205-211 L1 cell adhesion molecule Homo sapiens 134-145 27566160-5 2017 Experimental design performed in this study indicated optimum condition for solar photo-Fenton reaction (20 mg L-1 of Fe2+ and 500 mg L-1 of H2O2; pH 2.8), which achieved 96 % removal of dissolved organic carbon (DOC) and 99 % absorbance removal. Desoxycorticosterone 213-216 L1 cell adhesion molecule Homo sapiens 134-145 28621407-5 2017 The limit of quantification for both Zn and Cu was 5 mug L-1 and 10 mug L-1 for Fe and the recovery for Zn, Fe and Cu was ranged from 90% to 94%, 97% to 103% and 90% to 102%, respectively. Zinc 37-39 L1 cell adhesion molecule Homo sapiens 57-75 28751968-11 2017 In 17 (15.8%) cases the proximal end of the LP shunt was placed at L1/L2 level or above. leucylproline 44-46 L1 cell adhesion molecule Homo sapiens 67-72 29965140-4 2017 DO ranged from 1.95 mg L-1 to 8.25 mg L-1 and the average concentration was 5.10 mg L-1. do 0-2 L1 cell adhesion molecule Homo sapiens 23-26 29965140-4 2017 DO ranged from 1.95 mg L-1 to 8.25 mg L-1 and the average concentration was 5.10 mg L-1. do 0-2 L1 cell adhesion molecule Homo sapiens 38-41 29965140-4 2017 DO ranged from 1.95 mg L-1 to 8.25 mg L-1 and the average concentration was 5.10 mg L-1. do 0-2 L1 cell adhesion molecule Homo sapiens 38-41 29965140-5 2017 Low-oxygen zones appeared between 12 m and 20 m and the minimum concentration was 1.95 mg L-1 at 17 m. The concentration of DO maintained at a high level between 0 m and 12 m and the vertical variance was small. do 124-126 L1 cell adhesion molecule Homo sapiens 90-93 29965140-6 2017 Sudden drop of DO occurred between 12 m and 20 m and there was an anoxic zone (<4.0 mg L-1). do 15-17 L1 cell adhesion molecule Homo sapiens 90-93 29965146-6 2017 With Phoslock added at the rate of 630 g m-2, sediment phosphorus release was successfully controlled, which reduced the phosphorus concentration in the lake water to less than 0.010 mg L-1. Phosphorus 56-66 L1 cell adhesion molecule Homo sapiens 187-190 29965151-9 2017 When treating eutrophic lake water with a phosphate concentration of 2 mg L-1, the phosphate concentration level could meet the III rank of Surface Water Environment Quality Standard of China by adopting the dosage of zirconium modified diatomite >=1.25 g L-1. Water 29-34 L1 cell adhesion molecule Homo sapiens 74-77 29965151-9 2017 When treating eutrophic lake water with a phosphate concentration of 2 mg L-1, the phosphate concentration level could meet the III rank of Surface Water Environment Quality Standard of China by adopting the dosage of zirconium modified diatomite >=1.25 g L-1. Phosphates 42-51 L1 cell adhesion molecule Homo sapiens 74-77 29965151-9 2017 When treating eutrophic lake water with a phosphate concentration of 2 mg L-1, the phosphate concentration level could meet the III rank of Surface Water Environment Quality Standard of China by adopting the dosage of zirconium modified diatomite >=1.25 g L-1. Phosphates 83-92 L1 cell adhesion molecule Homo sapiens 74-77 29965151-9 2017 When treating eutrophic lake water with a phosphate concentration of 2 mg L-1, the phosphate concentration level could meet the III rank of Surface Water Environment Quality Standard of China by adopting the dosage of zirconium modified diatomite >=1.25 g L-1. Phosphates 83-92 L1 cell adhesion molecule Homo sapiens 259-262 29965151-9 2017 When treating eutrophic lake water with a phosphate concentration of 2 mg L-1, the phosphate concentration level could meet the III rank of Surface Water Environment Quality Standard of China by adopting the dosage of zirconium modified diatomite >=1.25 g L-1. Water 148-153 L1 cell adhesion molecule Homo sapiens 74-77 29965151-9 2017 When treating eutrophic lake water with a phosphate concentration of 2 mg L-1, the phosphate concentration level could meet the III rank of Surface Water Environment Quality Standard of China by adopting the dosage of zirconium modified diatomite >=1.25 g L-1. Zirconium 218-227 L1 cell adhesion molecule Homo sapiens 74-77 29965151-9 2017 When treating eutrophic lake water with a phosphate concentration of 2 mg L-1, the phosphate concentration level could meet the III rank of Surface Water Environment Quality Standard of China by adopting the dosage of zirconium modified diatomite >=1.25 g L-1. Zirconium 218-227 L1 cell adhesion molecule Homo sapiens 259-262 28381862-6 2017 A wide linear concentration range from 2.3 to 120 microg L-1, limit of detection (LOD) of 0.72 microg L-1 and the limit of quantification (LOQ) of 0.91 microg L-1 were achieved for determination of Cd (II). cd (ii) 198-205 L1 cell adhesion molecule Homo sapiens 57-60 28187386-4 2017 The total nitrogen (TN) removal efficiency was as high as 95.8% with influent NH4+-N of 63.58 mg L-1 and NO3--N of 69.24 mg L-1. nh4+-n 78-84 L1 cell adhesion molecule Homo sapiens 97-100 29965055-1 2017 Wastewater treatment plants treating industrial wastewater and municipal wastewater may suffer from unexpected shock loads of high ammonia concentrations,which can lead to inhibition of biological nitrification and failure to meet the wastewater discharge standards.In order to solve the problem of failure to meet the standards,the effects of high loadings of free ammonia (FA) on the nitrification process were investigated in this work using a sequencing batch reactor (SBR).For such purpose,maximum specific degradation rates of ammonia,maximum specific formation rates of nitrate,specific oxygen uptake rates and abundances of nitrifying bacteria were monitored.The results showed that FA promoted nitrification activities at low concentrations and inhibited the activities when the FA concentration exceeded a certain value.In addition,high loading concentrations of FA resulted in long recovery times.When the FA concentration increased from 3.6 mg L-1 to 8.1 mg L-1,the abundances of ammonia-oxidizing bacteria (AOB) and nitrite-oxidizing bacteria (NOB) increased slightly,as shown by the fluorescence in situ hybridization tests.However,there were apparent decreases in the abundances of AOB and NOB when the concentration of FA was higher than 8.1 mg L-1.The critical FA inhibitory concentrations for AOB and NOB were 8.1 mg L-1 and 6.6 mg L-1.It was found that the NOB flora were more sensitive than AOB to FA inhibition. Ammonia 131-138 L1 cell adhesion molecule Homo sapiens 1335-1346 28110016-7 2017 Median urinary BTEX levels were: 118 ng L-1, 124 ng L-1, 9 ng L-1, 29 ng L-1 and 28 ng L-1 for benzene, toluene, ethylbenzene, (p + m)-xylene and o-xylene, respectively. btex 15-19 L1 cell adhesion molecule Homo sapiens 73-90 28110016-7 2017 Median urinary BTEX levels were: 118 ng L-1, 124 ng L-1, 9 ng L-1, 29 ng L-1 and 28 ng L-1 for benzene, toluene, ethylbenzene, (p + m)-xylene and o-xylene, respectively. Benzene 95-102 L1 cell adhesion molecule Homo sapiens 73-90 29965586-2 2017 The removal efficiency of NH4+-N was found to be relatively stable during all experimental stages but effluent COD of the system during later period remained as high as 81.3 mg L-1. nh4+-n 26-32 L1 cell adhesion molecule Homo sapiens 177-180 28024204-3 2017 The maximum adsorption capacities of g-C3N4 towards Cd2+ and MB were 94.4 and 42.1 mg g-1, respectively, at 318.5 K when the initial concentrations of Cd2+ and MB were 200 and 20 mg L-1, respectively. g-c3n4 37-43 L1 cell adhesion molecule Homo sapiens 182-185 29965128-5 2017 Annual mean concentrations of NH4+-N and NO3--N in precipitation averaged 2.2 and 1.8 mg L-1, respectively. nh4+-n 30-36 L1 cell adhesion molecule Homo sapiens 89-92 28181084-2 2017 The maximal adsorption capacity for Pb, Cd, and TC in a single adsorptive system calculated from Langmuir equation was 12.80, 85.20, and 42.94 mg L-1, while for mixed substances, the adsorption amount was 2.99, 13.46, and 20.89 mg L-1, respectively. Lead 36-38 L1 cell adhesion molecule Homo sapiens 146-149 28181084-2 2017 The maximal adsorption capacity for Pb, Cd, and TC in a single adsorptive system calculated from Langmuir equation was 12.80, 85.20, and 42.94 mg L-1, while for mixed substances, the adsorption amount was 2.99, 13.46, and 20.89 mg L-1, respectively. Cadmium 40-42 L1 cell adhesion molecule Homo sapiens 146-149 28181084-2 2017 The maximal adsorption capacity for Pb, Cd, and TC in a single adsorptive system calculated from Langmuir equation was 12.80, 85.20, and 42.94 mg L-1, while for mixed substances, the adsorption amount was 2.99, 13.46, and 20.89 mg L-1, respectively. Tetracycline 48-50 L1 cell adhesion molecule Homo sapiens 146-149 28181084-2 2017 The maximal adsorption capacity for Pb, Cd, and TC in a single adsorptive system calculated from Langmuir equation was 12.80, 85.20, and 42.94 mg L-1, while for mixed substances, the adsorption amount was 2.99, 13.46, and 20.89 mg L-1, respectively. Tetracycline 48-50 L1 cell adhesion molecule Homo sapiens 231-234 27645453-8 2017 Fullerenol C60 O2-4 (OH)20-24 revealed higher antioxidant ability at concentrations 10-17 -10-5 g L-1 . fullerenol 0-10 L1 cell adhesion molecule Homo sapiens 98-101 29964517-11 2017 Under this condition, the adsorption rate was 99.9%, and the equilibrium concentration of Hg2+ was 0.034 mg L-1. Mercuric cation 90-94 L1 cell adhesion molecule Homo sapiens 108-111 29964518-2 2017 It was found that bromate concentration would exceed 10.00 mug L-1 as ozone doses were higher than 1.0 mg L-1 under different water qualities. Bromates 18-25 L1 cell adhesion molecule Homo sapiens 63-66 29964518-2 2017 It was found that bromate concentration would exceed 10.00 mug L-1 as ozone doses were higher than 1.0 mg L-1 under different water qualities. Bromates 18-25 L1 cell adhesion molecule Homo sapiens 106-109 29964518-4 2017 Bromate concentration could be controlled below 10.00 mug L-1 as ammonia dose was 0.10-0.30 mg L-1 or the m(H2O2)/m(O3) was 0.2-1.0. Bromates 0-7 L1 cell adhesion molecule Homo sapiens 58-61 29964518-4 2017 Bromate concentration could be controlled below 10.00 mug L-1 as ammonia dose was 0.10-0.30 mg L-1 or the m(H2O2)/m(O3) was 0.2-1.0. Bromates 0-7 L1 cell adhesion molecule Homo sapiens 95-98 27892634-2 2017 Single Cu2 O superstructure particle exhibits an outstanding surface-enhanced Raman spectroscopy performance with the limit of detection as low as 10-9 mol L-1 and metal comparable enhancement factor (8 x 105 ) due to the synergetic effect of vacancies defect-facilitated charge-transfer process and copper vacancies defect-induced electrostatic adsorption. cuprous oxide 7-12 L1 cell adhesion molecule Homo sapiens 156-208 27892634-2 2017 Single Cu2 O superstructure particle exhibits an outstanding surface-enhanced Raman spectroscopy performance with the limit of detection as low as 10-9 mol L-1 and metal comparable enhancement factor (8 x 105 ) due to the synergetic effect of vacancies defect-facilitated charge-transfer process and copper vacancies defect-induced electrostatic adsorption. Copper 300-306 L1 cell adhesion molecule Homo sapiens 156-208 27810529-6 2017 After 6 h of the Fenton reaction at pH 3, the addition of 1660 mg L-1 of H2O2 and 133 mg L-1 of iron showed a maximum O&G elimination of 57.6% and a phenol removal up to 80%. Iron 96-100 L1 cell adhesion molecule Homo sapiens 66-77 27810529-6 2017 After 6 h of the Fenton reaction at pH 3, the addition of 1660 mg L-1 of H2O2 and 133 mg L-1 of iron showed a maximum O&G elimination of 57.6% and a phenol removal up to 80%. o& 118-123 L1 cell adhesion molecule Homo sapiens 66-77 27810529-6 2017 After 6 h of the Fenton reaction at pH 3, the addition of 1660 mg L-1 of H2O2 and 133 mg L-1 of iron showed a maximum O&G elimination of 57.6% and a phenol removal up to 80%. Phenol 153-159 L1 cell adhesion molecule Homo sapiens 66-77 27810529-7 2017 Photo-Fenton process showed better results after 3 h, adding 600 mg L-1 of H2O2 and 300 mg L-1 of iron, at pH 3, with a higher fraction of elimination of the O&G content (73.7%) and phenol (95%) compared to the conventional Fenton process. o& 158-163 L1 cell adhesion molecule Homo sapiens 68-79 27810529-7 2017 Photo-Fenton process showed better results after 3 h, adding 600 mg L-1 of H2O2 and 300 mg L-1 of iron, at pH 3, with a higher fraction of elimination of the O&G content (73.7%) and phenol (95%) compared to the conventional Fenton process. Phenol 186-192 L1 cell adhesion molecule Homo sapiens 68-79 27916494-3 2017 The removal efficiency values for tetracycline (200 mg L-1) were 31.5% and 97.8%, respectively, by the biochar-Cu NP composite (0.5 g L-1) in the absence and presence of hydrogen peroxide (H2O2, 20 mM) within 6 h of reaction time. Tetracycline 34-46 L1 cell adhesion molecule Homo sapiens 55-58 27916494-3 2017 The removal efficiency values for tetracycline (200 mg L-1) were 31.5% and 97.8%, respectively, by the biochar-Cu NP composite (0.5 g L-1) in the absence and presence of hydrogen peroxide (H2O2, 20 mM) within 6 h of reaction time. Tetracycline 34-46 L1 cell adhesion molecule Homo sapiens 134-137 32263664-3 2017 0.57 mug L-1) and showed high selectivity towards arsenic ions over other metal ions. Arsenic 50-57 L1 cell adhesion molecule Homo sapiens 9-12 27535155-3 2017 The oxidation of PABA by photo-Fenton and oxalate-induced photo-Fenton (ferrioxalate) processes was investigated, and the effect of various operating variables has been assessed, i.e., Fe3+ (0.0035-0.014 g L-1), H2O2 (0.025-0.2 g L-1), T (280-323 K), and type of radiation (UV-A, visible). 4-Aminobenzoic Acid 17-21 L1 cell adhesion molecule Homo sapiens 206-209 27783247-5 2017 The optimal operating conditions for the degradation of 0.12 mM (74 mg L-1) dye concentration and mineralization of its aqueous solution were determined as GrF-ZnO-TiO2 thin film anode, 100 mA current intensity, and 0.1 mM Fe2+ (catalyst) concentration. Zinc Oxide 160-163 L1 cell adhesion molecule Homo sapiens 71-74 27783247-5 2017 The optimal operating conditions for the degradation of 0.12 mM (74 mg L-1) dye concentration and mineralization of its aqueous solution were determined as GrF-ZnO-TiO2 thin film anode, 100 mA current intensity, and 0.1 mM Fe2+ (catalyst) concentration. titanium dioxide 164-168 L1 cell adhesion molecule Homo sapiens 71-74 27783247-5 2017 The optimal operating conditions for the degradation of 0.12 mM (74 mg L-1) dye concentration and mineralization of its aqueous solution were determined as GrF-ZnO-TiO2 thin film anode, 100 mA current intensity, and 0.1 mM Fe2+ (catalyst) concentration. ammonium ferrous sulfate 223-227 L1 cell adhesion molecule Homo sapiens 71-74 27844316-8 2017 Furthermore, the maximum concentrations in raw water of WTPs was kept at 82.1 ng L-1 for 2-MIB, 5.6 ng L-1 for geosmin, and 66.1 ng L-1 for beta-ionone. Water 47-52 L1 cell adhesion molecule Homo sapiens 81-84 27844316-8 2017 Furthermore, the maximum concentrations in raw water of WTPs was kept at 82.1 ng L-1 for 2-MIB, 5.6 ng L-1 for geosmin, and 66.1 ng L-1 for beta-ionone. Water 47-52 L1 cell adhesion molecule Homo sapiens 103-106 27844316-8 2017 Furthermore, the maximum concentrations in raw water of WTPs was kept at 82.1 ng L-1 for 2-MIB, 5.6 ng L-1 for geosmin, and 66.1 ng L-1 for beta-ionone. Water 47-52 L1 cell adhesion molecule Homo sapiens 103-106 27535155-3 2017 The oxidation of PABA by photo-Fenton and oxalate-induced photo-Fenton (ferrioxalate) processes was investigated, and the effect of various operating variables has been assessed, i.e., Fe3+ (0.0035-0.014 g L-1), H2O2 (0.025-0.2 g L-1), T (280-323 K), and type of radiation (UV-A, visible). 4-Aminobenzoic Acid 17-21 L1 cell adhesion molecule Homo sapiens 230-233 28932618-5 2017 The detection limits for preconcentration time of 30 s were 6.7 x 10-10 mol L-1 and 8.8 x 10-10 mol L-1 for bismuth and lead, respectively. Bismuth 108-115 L1 cell adhesion molecule Homo sapiens 76-95 28067653-5 2017 Starting from 10 ppm dye solutions and 1 g L-1 of the synthesised AgCl nanoparticles, degradation efficiencies of 98.4% for MO, 98.6% for MB and 99.9% for RhB, were achieved in 1 h. The degradation mechanisms for the different dyes were studied. silver chloride 66-70 L1 cell adhesion molecule Homo sapiens 43-46 27380303-1 2016 The present paper reports the spectroscopic investigations on the complexation of Cu(II) with two macrocyclic ligands bonded to [60]Fullerene (L1 and L2) measured in N-methylpyrrolidone (NMP) as solvent. cu(ii) 82-88 L1 cell adhesion molecule Homo sapiens 143-152 27380303-1 2016 The present paper reports the spectroscopic investigations on the complexation of Cu(II) with two macrocyclic ligands bonded to [60]Fullerene (L1 and L2) measured in N-methylpyrrolidone (NMP) as solvent. Fullerenes 132-141 L1 cell adhesion molecule Homo sapiens 143-152 27380303-1 2016 The present paper reports the spectroscopic investigations on the complexation of Cu(II) with two macrocyclic ligands bonded to [60]Fullerene (L1 and L2) measured in N-methylpyrrolidone (NMP) as solvent. N-methylpyrrolidone 166-185 L1 cell adhesion molecule Homo sapiens 143-152 27380303-1 2016 The present paper reports the spectroscopic investigations on the complexation of Cu(II) with two macrocyclic ligands bonded to [60]Fullerene (L1 and L2) measured in N-methylpyrrolidone (NMP) as solvent. N-methylpyrrolidone 187-190 L1 cell adhesion molecule Homo sapiens 143-152 27380303-3 2016 DFT calculations suggested that superior HOMO distributions spread over the nitrogen-donor (as well as somehow oxygen- donor in L2) groups of L1 and L2 macrocycles were the key factor for the observed Kb value enhancement. Nitrogen 76-84 L1 cell adhesion molecule Homo sapiens 142-151 27380303-3 2016 DFT calculations suggested that superior HOMO distributions spread over the nitrogen-donor (as well as somehow oxygen- donor in L2) groups of L1 and L2 macrocycles were the key factor for the observed Kb value enhancement. Oxygen 111-117 L1 cell adhesion molecule Homo sapiens 142-151 27814528-3 2016 TiO2 NPs were spiked in 34 lake and 5 brackish water samples at an initial concentration of 10 mg L-1. titanium dioxide 0-4 L1 cell adhesion molecule Homo sapiens 98-101 27623370-7 2016 The addition of silicone oil at 20% (on a volume basis) stabilized system performance, leading to dissolved O2 concentrations of 7 mg L-1 and steady ECs of 320 g m-3 h-1 in the PB. Silicone Oils 16-28 L1 cell adhesion molecule Homo sapiens 134-137 27623370-7 2016 The addition of silicone oil at 20% (on a volume basis) stabilized system performance, leading to dissolved O2 concentrations of 7 mg L-1 and steady ECs of 320 g m-3 h-1 in the PB. Oxygen 108-110 L1 cell adhesion molecule Homo sapiens 134-137 27622544-13 2016 Dexamethasone reduced F1 + 2 (284 pmol L-1 , 95% CI 34-534) and TATc (9 mug L-1 , 95% CI 0.7-17) levels almost to those measured in BAL fluid from the saline-instilled segments in the placebo group. Dexamethasone 0-13 L1 cell adhesion molecule Homo sapiens 39-42 27833110-4 2016 On the contrary, in the eastern part, DeltaDIN varied from -63.66 mumol L-1 to -10.45 mumol L-1. deltadin 38-46 L1 cell adhesion molecule Homo sapiens 72-82 27562809-6 2016 In a system with 0.5 g L-1 of FeCo2O4/TiO2/GO and 10 mmol L-1 of H2O2, approximately 90 % of BPA (20 mg L-1) was degraded within 240 min of UV irradiation at pH 6.0. feco2o4 30-37 L1 cell adhesion molecule Homo sapiens 23-26 27562809-6 2016 In a system with 0.5 g L-1 of FeCo2O4/TiO2/GO and 10 mmol L-1 of H2O2, approximately 90 % of BPA (20 mg L-1) was degraded within 240 min of UV irradiation at pH 6.0. Hydrogen Peroxide 65-69 L1 cell adhesion molecule Homo sapiens 58-61 27562809-6 2016 In a system with 0.5 g L-1 of FeCo2O4/TiO2/GO and 10 mmol L-1 of H2O2, approximately 90 % of BPA (20 mg L-1) was degraded within 240 min of UV irradiation at pH 6.0. Hydrogen Peroxide 65-69 L1 cell adhesion molecule Homo sapiens 58-61 27562809-6 2016 In a system with 0.5 g L-1 of FeCo2O4/TiO2/GO and 10 mmol L-1 of H2O2, approximately 90 % of BPA (20 mg L-1) was degraded within 240 min of UV irradiation at pH 6.0. bisphenol A 93-96 L1 cell adhesion molecule Homo sapiens 23-26 27562809-6 2016 In a system with 0.5 g L-1 of FeCo2O4/TiO2/GO and 10 mmol L-1 of H2O2, approximately 90 % of BPA (20 mg L-1) was degraded within 240 min of UV irradiation at pH 6.0. bisphenol A 93-96 L1 cell adhesion molecule Homo sapiens 58-61 27562809-6 2016 In a system with 0.5 g L-1 of FeCo2O4/TiO2/GO and 10 mmol L-1 of H2O2, approximately 90 % of BPA (20 mg L-1) was degraded within 240 min of UV irradiation at pH 6.0. bisphenol A 93-96 L1 cell adhesion molecule Homo sapiens 58-61 27859307-5 2016 The optimum values of operating parameters were found at an initial pH value of 5.0, a H2 O2 dosage of 0.15 mmol L-1 and a Zn0.9 Fe0.1 S dosage of 0.08 g when the initial concentration of BPA was 10 mg L-1 . Hydrogen Peroxide 87-92 L1 cell adhesion molecule Homo sapiens 113-116 27842020-6 2016 To achieve maximum dye removal, optimum conditions were found at TiO2 concentration of 3 g L-1, initial pH of 7 and aeration flow rate of 1.50 L min-1. titanium dioxide 65-69 L1 cell adhesion molecule Homo sapiens 91-94 27735877-6 2016 About 94.1% of benzohydroxamic acid with the original concentration at 30 mg L-1 was removed after 120 min in a solution of pH 4.4 with an La/TiO2 amount of 0.5 g L-1. benzohydroxamic acid 15-35 L1 cell adhesion molecule Homo sapiens 77-80 27735877-6 2016 About 94.1% of benzohydroxamic acid with the original concentration at 30 mg L-1 was removed after 120 min in a solution of pH 4.4 with an La/TiO2 amount of 0.5 g L-1. benzohydroxamic acid 15-35 L1 cell adhesion molecule Homo sapiens 163-166 27735877-6 2016 About 94.1% of benzohydroxamic acid with the original concentration at 30 mg L-1 was removed after 120 min in a solution of pH 4.4 with an La/TiO2 amount of 0.5 g L-1. titanium dioxide 142-146 L1 cell adhesion molecule Homo sapiens 163-166 27432152-8 2016 Tumorsphere formation is one of the indicators of aggressiveness in malignant cancers, which was significantly inhibited in IMR-32 cells after L1-CAM KD or Sutent treatment, however, no synergistic effect was observed with dual treatments, rather L1-CAM KD alone showed a greater inhibition on tumorsphere formation compared to Sutent treatment alone. Sunitinib 328-334 L1 cell adhesion molecule Homo sapiens 143-149 27763346-6 2016 The process was fitted to the pseudo first order kinetic model with rate constants in the range of 6-22(x10-3) mg L-1 min-1 with respect to initial concentration of doxycycline under UV-C irradiation. Doxycycline 165-176 L1 cell adhesion molecule Homo sapiens 114-123 27164883-6 2017 Within the studied experimental ranges, the optimum conditions for maximum Cr(VI) removal efficiency (72.1 %) after 60 min of photocatalytic treatment were: catalyst concentration 55 mg L-1, Cr(VI) concentration 20 mg L-1, pH 4, and 5 % (v/v) methanol concentration. chromium hexavalent ion 75-81 L1 cell adhesion molecule Homo sapiens 186-189 27164883-6 2017 Within the studied experimental ranges, the optimum conditions for maximum Cr(VI) removal efficiency (72.1 %) after 60 min of photocatalytic treatment were: catalyst concentration 55 mg L-1, Cr(VI) concentration 20 mg L-1, pH 4, and 5 % (v/v) methanol concentration. chromium hexavalent ion 75-81 L1 cell adhesion molecule Homo sapiens 218-221 27578092-4 2016 Even after the biological and filtration treatments, the oil refinery wastewater still presented an appreciable amount of recalcitrant organic matter (TOC of 12-19 mgC L-1) and silt density index (SDI) higher than 4, which is considered high for subsequent reverse osmosis due to membrane fouling risks. Oils 57-60 L1 cell adhesion molecule Homo sapiens 168-171 27578092-6 2016 When the combined processes were applied, a considerable increase in the TOC removal was observed (max of 95 % for UV/O3 process, 55 W, 60 mgO3 L-1), likely due the presence of higher amounts of reactive species, specially hydroxyl radicals, confirming the important role of these species on the photochemical degradation of the wastewater compounds. mgo3 139-143 L1 cell adhesion molecule Homo sapiens 144-147 27578092-7 2016 A zero-order kinetic model was fitted to the experimental data and the rate constant values (k, mgC L-1 h-1) ranged from 4.8 < k UV/O3 < 11 ([O3]0 = 30-60 mg L-1), and 8.6 < k UV/H2O2 < 11 (C:H2O2 from 1:1 to 1:4). Hydrogen Peroxide 188-192 L1 cell adhesion molecule Homo sapiens 100-103 27578092-7 2016 A zero-order kinetic model was fitted to the experimental data and the rate constant values (k, mgC L-1 h-1) ranged from 4.8 < k UV/O3 < 11 ([O3]0 = 30-60 mg L-1), and 8.6 < k UV/H2O2 < 11 (C:H2O2 from 1:1 to 1:4). Hydrogen Peroxide 188-192 L1 cell adhesion molecule Homo sapiens 164-167 27578092-7 2016 A zero-order kinetic model was fitted to the experimental data and the rate constant values (k, mgC L-1 h-1) ranged from 4.8 < k UV/O3 < 11 ([O3]0 = 30-60 mg L-1), and 8.6 < k UV/H2O2 < 11 (C:H2O2 from 1:1 to 1:4). Hydrogen Peroxide 204-208 L1 cell adhesion molecule Homo sapiens 100-103 27578092-7 2016 A zero-order kinetic model was fitted to the experimental data and the rate constant values (k, mgC L-1 h-1) ranged from 4.8 < k UV/O3 < 11 ([O3]0 = 30-60 mg L-1), and 8.6 < k UV/H2O2 < 11 (C:H2O2 from 1:1 to 1:4). Hydrogen Peroxide 204-208 L1 cell adhesion molecule Homo sapiens 164-167 27573342-2 2016 The binding and fluorescence sensing properties toward Cu2+ , Zn2+ , Cd2+ , and Pb2+ of L1 and receptor L2, composed of two [9]aneN3 macrocycles bridged by a 6,6""-dimethylen-2,2":6",2""-terpyridine unit, have been studied by coupling potentiometric, UV/Vis absorption, and emission measurements in aqueous media. cupric ion 55-59 L1 cell adhesion molecule Homo sapiens 88-106 27573342-2 2016 The binding and fluorescence sensing properties toward Cu2+ , Zn2+ , Cd2+ , and Pb2+ of L1 and receptor L2, composed of two [9]aneN3 macrocycles bridged by a 6,6""-dimethylen-2,2":6",2""-terpyridine unit, have been studied by coupling potentiometric, UV/Vis absorption, and emission measurements in aqueous media. Zinc 62-66 L1 cell adhesion molecule Homo sapiens 88-106 27573342-2 2016 The binding and fluorescence sensing properties toward Cu2+ , Zn2+ , Cd2+ , and Pb2+ of L1 and receptor L2, composed of two [9]aneN3 macrocycles bridged by a 6,6""-dimethylen-2,2":6",2""-terpyridine unit, have been studied by coupling potentiometric, UV/Vis absorption, and emission measurements in aqueous media. 6,6""-dimethylen-2,2":6",2""-terpyridine 158-198 L1 cell adhesion molecule Homo sapiens 88-106 27488715-8 2016 (3) The average concentrations of total phosphorus (TP), NO3-N, and NH4-N in Miyun Reservior were 0.017 mg P L-1, 0.620 mg N L-1, and 0.143 mg N L-1, respectively. nh4-n 68-73 L1 cell adhesion molecule Homo sapiens 109-112 30246999-2 2016 The results showed that ammonia nitrogen concentration decreased from 45.3 to 2.7 mg L-1 after aerobic, and nitrite nitrogen concentration increased from 0.01 to 19.6 mg L-1, while nitrite nitrogen concentration decreased from 19.6 to 1.2 mg L-1 after anoxic, which means that rapid nitrification and denitrification are successfully achieved. Ammonia 24-31 L1 cell adhesion molecule Homo sapiens 85-88 30246999-2 2016 The results showed that ammonia nitrogen concentration decreased from 45.3 to 2.7 mg L-1 after aerobic, and nitrite nitrogen concentration increased from 0.01 to 19.6 mg L-1, while nitrite nitrogen concentration decreased from 19.6 to 1.2 mg L-1 after anoxic, which means that rapid nitrification and denitrification are successfully achieved. Nitrogen 32-40 L1 cell adhesion molecule Homo sapiens 85-88 30246999-2 2016 The results showed that ammonia nitrogen concentration decreased from 45.3 to 2.7 mg L-1 after aerobic, and nitrite nitrogen concentration increased from 0.01 to 19.6 mg L-1, while nitrite nitrogen concentration decreased from 19.6 to 1.2 mg L-1 after anoxic, which means that rapid nitrification and denitrification are successfully achieved. Nitrites 108-115 L1 cell adhesion molecule Homo sapiens 170-173 30246999-2 2016 The results showed that ammonia nitrogen concentration decreased from 45.3 to 2.7 mg L-1 after aerobic, and nitrite nitrogen concentration increased from 0.01 to 19.6 mg L-1, while nitrite nitrogen concentration decreased from 19.6 to 1.2 mg L-1 after anoxic, which means that rapid nitrification and denitrification are successfully achieved. Nitrites 108-115 L1 cell adhesion molecule Homo sapiens 170-173 30246999-2 2016 The results showed that ammonia nitrogen concentration decreased from 45.3 to 2.7 mg L-1 after aerobic, and nitrite nitrogen concentration increased from 0.01 to 19.6 mg L-1, while nitrite nitrogen concentration decreased from 19.6 to 1.2 mg L-1 after anoxic, which means that rapid nitrification and denitrification are successfully achieved. Nitrogen 116-124 L1 cell adhesion molecule Homo sapiens 170-173 30246999-2 2016 The results showed that ammonia nitrogen concentration decreased from 45.3 to 2.7 mg L-1 after aerobic, and nitrite nitrogen concentration increased from 0.01 to 19.6 mg L-1, while nitrite nitrogen concentration decreased from 19.6 to 1.2 mg L-1 after anoxic, which means that rapid nitrification and denitrification are successfully achieved. Nitrogen 116-124 L1 cell adhesion molecule Homo sapiens 170-173 30246999-2 2016 The results showed that ammonia nitrogen concentration decreased from 45.3 to 2.7 mg L-1 after aerobic, and nitrite nitrogen concentration increased from 0.01 to 19.6 mg L-1, while nitrite nitrogen concentration decreased from 19.6 to 1.2 mg L-1 after anoxic, which means that rapid nitrification and denitrification are successfully achieved. Nitrogen 116-124 L1 cell adhesion molecule Homo sapiens 170-173 30246999-2 2016 The results showed that ammonia nitrogen concentration decreased from 45.3 to 2.7 mg L-1 after aerobic, and nitrite nitrogen concentration increased from 0.01 to 19.6 mg L-1, while nitrite nitrogen concentration decreased from 19.6 to 1.2 mg L-1 after anoxic, which means that rapid nitrification and denitrification are successfully achieved. Nitrogen 116-124 L1 cell adhesion molecule Homo sapiens 170-173 28925164-2 2016 In this study, VSMC was induced by ox-LDL (50 mg L-1),the effect of ICA on the proliferation of VSMC was detected by MTT assay, Western blot and Real-time PCR. vsmc 15-19 L1 cell adhesion molecule Homo sapiens 49-52 27622544-13 2016 Dexamethasone reduced F1 + 2 (284 pmol L-1 , 95% CI 34-534) and TATc (9 mug L-1 , 95% CI 0.7-17) levels almost to those measured in BAL fluid from the saline-instilled segments in the placebo group. Dexamethasone 0-13 L1 cell adhesion molecule Homo sapiens 76-79 27622544-14 2016 Dexamethasone even profoundly reduced F1 + 2 levels (80%) in saline-instilled lung segments (50 pmol L-1 , 95% CI 12-87). Dexamethasone 0-13 L1 cell adhesion molecule Homo sapiens 101-104 27622544-14 2016 Dexamethasone even profoundly reduced F1 + 2 levels (80%) in saline-instilled lung segments (50 pmol L-1 , 95% CI 12-87). Sodium Chloride 61-67 L1 cell adhesion molecule Homo sapiens 101-104 29964789-4 2016 The photocatalytic degradation rate was the highest when the amount of catalyst (TiO2) was 3 g L-1. titanium dioxide 81-85 L1 cell adhesion molecule Homo sapiens 95-98 28773486-5 2016 Moreover, pH had little effect on the removal of tetracycline, and the electrocatalytic membrane could effectively remove tetracycline with initial concentration of 50 mg L-1 (pH, 3.8-9.6). Tetracycline 122-134 L1 cell adhesion molecule Homo sapiens 171-174 27454810-1 2016 Ligands L1 and L2, consisting of a tetrazine ring decorated with two morpholine pendants of different lengths, show peculiar anion-binding behaviors. 1,2,3,4-tetrazine 35-44 L1 cell adhesion molecule Homo sapiens 8-17 27454810-1 2016 Ligands L1 and L2, consisting of a tetrazine ring decorated with two morpholine pendants of different lengths, show peculiar anion-binding behaviors. morpholine 69-79 L1 cell adhesion molecule Homo sapiens 8-17 27454810-2 2016 In several cases, even the neutral ligands, in addition to their protonated HL(+) and H2L(2+) (L = L1 and L2) forms, bind anions such as F(-), NO3(-), PF6(-), ClO4(-), and SO4(2-) to form stable complexes in water. punky blue 143-146 L1 cell adhesion molecule Homo sapiens 99-108 27454810-2 2016 In several cases, even the neutral ligands, in addition to their protonated HL(+) and H2L(2+) (L = L1 and L2) forms, bind anions such as F(-), NO3(-), PF6(-), ClO4(-), and SO4(2-) to form stable complexes in water. perchlorate 159-163 L1 cell adhesion molecule Homo sapiens 99-108 27454810-2 2016 In several cases, even the neutral ligands, in addition to their protonated HL(+) and H2L(2+) (L = L1 and L2) forms, bind anions such as F(-), NO3(-), PF6(-), ClO4(-), and SO4(2-) to form stable complexes in water. sulfuric acid 172-175 L1 cell adhesion molecule Homo sapiens 99-108 27454810-2 2016 In several cases, even the neutral ligands, in addition to their protonated HL(+) and H2L(2+) (L = L1 and L2) forms, bind anions such as F(-), NO3(-), PF6(-), ClO4(-), and SO4(2-) to form stable complexes in water. Water 208-213 L1 cell adhesion molecule Homo sapiens 99-108 29964742-6 2016 For the test reactor (R2) in which DO was controlled at the levels of 2, 1, 0.5, 0.2, 0.1 mg L-1 during the aerobic stage, respectively, the phosphorus removal performance showed a slight fluctuation at the beginning of each stage but rapidly increased to a stable state. Phosphorus 141-151 L1 cell adhesion molecule Homo sapiens 93-96 29964742-9 2016 The specific phosphate uptake rate under DO=2 mg L-1 was found to be nearly the maximum, but it was greatly influenced by the low DO. Phosphates 13-22 L1 cell adhesion molecule Homo sapiens 49-52 29964457-4 2016 Sulfamethoxazole (SMX) and sulfonamide (SAM) presented the 100% detected frequency, and the maximum concentrations reached 107.0 ng L-1 and 43.1 ng L-1, respectively. Sulfamethoxazole 0-16 L1 cell adhesion molecule Homo sapiens 132-151 29964457-4 2016 Sulfamethoxazole (SMX) and sulfonamide (SAM) presented the 100% detected frequency, and the maximum concentrations reached 107.0 ng L-1 and 43.1 ng L-1, respectively. Sulfamethoxazole 18-21 L1 cell adhesion molecule Homo sapiens 132-151 29964457-4 2016 Sulfamethoxazole (SMX) and sulfonamide (SAM) presented the 100% detected frequency, and the maximum concentrations reached 107.0 ng L-1 and 43.1 ng L-1, respectively. Sulfonamides 27-38 L1 cell adhesion molecule Homo sapiens 132-151 29964457-4 2016 Sulfamethoxazole (SMX) and sulfonamide (SAM) presented the 100% detected frequency, and the maximum concentrations reached 107.0 ng L-1 and 43.1 ng L-1, respectively. Sulfonamides 40-43 L1 cell adhesion molecule Homo sapiens 132-151 28773486-6 2016 The 100% tetracycline and 87.8% COD removal rate could be achieved under the following operating conditions: tetracycline concentration of 50 mg L-1, current density of 1 mA cm-2, temperature of 25 C, and residence time of 4.4 min. Tetracycline 109-121 L1 cell adhesion molecule Homo sapiens 145-148 26841126-3 2016 X-ray analyses of complexes 3 and 6 revealed a neutral coordination mode of L1 and L3 to the tungsten in solid state, while the electron paramagnetic resonance (EPR) spectra of 3 and 4 clarified that a radical was predominantly located on the tungsten center supported by neutral L1 or L2, and the EPR spectra of complex 6 indicated that a radical was delocalized over both the tungsten center and the monoanionic redox-active ligand L3. Tungsten 93-101 L1 cell adhesion molecule Homo sapiens 76-85 28773654-4 2016 At these operating conditions, 92.3% of the butanol present in the feed solution was extracted, and a concentration of 787.5 g L-1 of butanol in the extract was obtained, starting from a feed solution of 20 g L-1. Butanols 134-141 L1 cell adhesion molecule Homo sapiens 127-130 28773654-4 2016 At these operating conditions, 92.3% of the butanol present in the feed solution was extracted, and a concentration of 787.5 g L-1 of butanol in the extract was obtained, starting from a feed solution of 20 g L-1. Butanols 134-141 L1 cell adhesion molecule Homo sapiens 209-212 26418512-4 2016 Augmented IL-8 secretion by Ca9-22 cells was blocked by the NF-kappaB inhibitor L-1-4"-tosylamino-phenylethyl-chloromethyl ketone (TPCK) and the nicotinic acetylcholine receptor (nAChR)-specific inhibitor alpha-bungarotoxin (alphaBtx). Tosylphenylalanyl Chloromethyl Ketone 131-135 L1 cell adhesion molecule Homo sapiens 80-83 27001749-8 2016 Thus, our results suggest that the clinical presentations of L1CAM mutations in human patients could be accounted for, at least in part, by cell-autonomous changes in the functional development of neurons, such that neurons are unable to develop normal axons and dendrites and to generate normal APs. Adenosine Phosphosulfate 296-299 L1 cell adhesion molecule Homo sapiens 61-66 26469730-1 2016 Two novel similar structural triphenylamine-based Schiff base fluorescent probes (L1/L2) were designed, prepared and characterized. triphenylamine-based schiff base 29-61 L1 cell adhesion molecule Homo sapiens 82-87 26964248-5 2015 The PSO-BP neural network can accurately measure the concentration of potassium sorbate in orange juice in the range of 0.1-2.0 g L-1. Sorbic Acid 70-87 L1 cell adhesion molecule Homo sapiens 132-135 28050563-7 2016 The results demonstrate that the DCA for L1-2 minimization outperforms the representative algorithms for L1, L2, L1/2, and L0 when the system matrix is highly coherent. dichloroacetylene 33-36 L1 cell adhesion molecule Homo sapiens 113-125 26488906-7 2015 This distortion causes the metal ion in complexes of L(1) to experience a significantly weaker ligand field than in the complexes of L(2), which are more regular. Metals 27-32 L1 cell adhesion molecule Homo sapiens 53-57 27066571-6 2015 CONCLUSIONS: This novel L1CAM mutation was located in the protein"s sixth immunoglobin domain and involved glycine-587, a key residue in the structure of L1CAM because of its interactions with lysine-606, which indicates that any mutation at this site would likely affect the secondary structure and function of the protein. Glycine 107-114 L1 cell adhesion molecule Homo sapiens 24-29 27066571-6 2015 CONCLUSIONS: This novel L1CAM mutation was located in the protein"s sixth immunoglobin domain and involved glycine-587, a key residue in the structure of L1CAM because of its interactions with lysine-606, which indicates that any mutation at this site would likely affect the secondary structure and function of the protein. Glycine 107-114 L1 cell adhesion molecule Homo sapiens 154-159 27066571-6 2015 CONCLUSIONS: This novel L1CAM mutation was located in the protein"s sixth immunoglobin domain and involved glycine-587, a key residue in the structure of L1CAM because of its interactions with lysine-606, which indicates that any mutation at this site would likely affect the secondary structure and function of the protein. Lysine 193-199 L1 cell adhesion molecule Homo sapiens 24-29 27066571-6 2015 CONCLUSIONS: This novel L1CAM mutation was located in the protein"s sixth immunoglobin domain and involved glycine-587, a key residue in the structure of L1CAM because of its interactions with lysine-606, which indicates that any mutation at this site would likely affect the secondary structure and function of the protein. Lysine 193-199 L1 cell adhesion molecule Homo sapiens 154-159 26192046-6 2015 Also, the Zn(2+)vs. Cd(2+) discrimination for L1 and L2 is proved. Zinc 10-12 L1 cell adhesion molecule Homo sapiens 46-55 26192046-8 2015 Further, a second colorimetric response channel upon addition of Fe(2+) was observed for L1 and L2. ammonium ferrous sulfate 65-71 L1 cell adhesion molecule Homo sapiens 89-98 26140525-4 2015 EXPERIMENTAL APPROACH: ESCC cell lines were treated with erlotinib or gefitinib (1 mumol L-1 ) and 4-MU (300 mumol L-1 ), and the cell count, cell cycle progression and migration were determined as compared to the single agents and the solvent-control. Gefitinib 70-79 L1 cell adhesion molecule Homo sapiens 89-92 26252971-1 2015 The ruthenium complex with (N,N,N-tris(benzimidazol-2yl-methyl)amine, L(1)) was prepared, and characterized. Ruthenium 4-13 L1 cell adhesion molecule Homo sapiens 70-74 26252971-10 2015 The adduct formation of phenol with [Ru(O)L(1)](2+) or [Ru(OH)L(1)](+) is theoretically analyzed to show that [Ru(OH)L(1)-OPh](+) could produce the phenol radical. Phenol 24-30 L1 cell adhesion molecule Homo sapiens 42-46 26252971-10 2015 The adduct formation of phenol with [Ru(O)L(1)](2+) or [Ru(OH)L(1)](+) is theoretically analyzed to show that [Ru(OH)L(1)-OPh](+) could produce the phenol radical. Phenol 24-30 L1 cell adhesion molecule Homo sapiens 62-66 26252971-10 2015 The adduct formation of phenol with [Ru(O)L(1)](2+) or [Ru(OH)L(1)](+) is theoretically analyzed to show that [Ru(OH)L(1)-OPh](+) could produce the phenol radical. Phenol 24-30 L1 cell adhesion molecule Homo sapiens 62-66 26252971-10 2015 The adduct formation of phenol with [Ru(O)L(1)](2+) or [Ru(OH)L(1)](+) is theoretically analyzed to show that [Ru(OH)L(1)-OPh](+) could produce the phenol radical. phenol radical 148-162 L1 cell adhesion molecule Homo sapiens 42-46 26252971-10 2015 The adduct formation of phenol with [Ru(O)L(1)](2+) or [Ru(OH)L(1)](+) is theoretically analyzed to show that [Ru(OH)L(1)-OPh](+) could produce the phenol radical. phenol radical 148-162 L1 cell adhesion molecule Homo sapiens 62-66 26252971-10 2015 The adduct formation of phenol with [Ru(O)L(1)](2+) or [Ru(OH)L(1)](+) is theoretically analyzed to show that [Ru(OH)L(1)-OPh](+) could produce the phenol radical. phenol radical 148-162 L1 cell adhesion molecule Homo sapiens 62-66 26146368-3 2015 A similar reaction of H(2)L(1) with Na(2)[PdCl(4)] in the presence of 1,2-bis(diphenylphosphino)ethane (dppe), in a 2 : 2 : 1 mole ratio, yields a dinuclear complex of type [{Pd(L(1))}(2)(dppe)]. h(2)l(1) 22-30 L1 cell adhesion molecule Homo sapiens 175-182 26261317-4 2015 We report robust and replicated associations of the amine compound SLC (solute-carrier) transporters gene set with the learning rate, of the collagen formation and transmembrane receptor protein tyrosine kinase activity gene sets with the modulation of memory strength by negative emotional arousal, and of the L1 cell adhesion molecule (L1CAM) interactions gene set with the repetition-based memory improvement. Amines 52-57 L1 cell adhesion molecule Homo sapiens 311-336 26261317-4 2015 We report robust and replicated associations of the amine compound SLC (solute-carrier) transporters gene set with the learning rate, of the collagen formation and transmembrane receptor protein tyrosine kinase activity gene sets with the modulation of memory strength by negative emotional arousal, and of the L1 cell adhesion molecule (L1CAM) interactions gene set with the repetition-based memory improvement. Amines 52-57 L1 cell adhesion molecule Homo sapiens 338-343 26146368-3 2015 A similar reaction of H(2)L(1) with Na(2)[PdCl(4)] in the presence of 1,2-bis(diphenylphosphino)ethane (dppe), in a 2 : 2 : 1 mole ratio, yields a dinuclear complex of type [{Pd(L(1))}(2)(dppe)]. bis(diphenylphosphine)ethane 104-108 L1 cell adhesion molecule Homo sapiens 175-182 26146368-4 2015 Reaction of H(2)L(1) with Na(2)[PdCl(4)] in the presence of 4-picoline (pic) yields [Pd(L(1))(pic)]. h(2)l 12-17 L1 cell adhesion molecule Homo sapiens 85-92 26146368-4 2015 Reaction of H(2)L(1) with Na(2)[PdCl(4)] in the presence of 4-picoline (pic) yields [Pd(L(1))(pic)]. sodium sulfide 26-31 L1 cell adhesion molecule Homo sapiens 85-92 26146368-4 2015 Reaction of H(2)L(1) with Na(2)[PdCl(4)] in the presence of 4-picoline (pic) yields [Pd(L(1))(pic)]. pdcl(4) 32-39 L1 cell adhesion molecule Homo sapiens 85-92 26146368-4 2015 Reaction of H(2)L(1) with Na(2)[PdCl(4)] in the presence of 4-picoline (pic) yields [Pd(L(1))(pic)]. 4-methylpyridine 60-70 L1 cell adhesion molecule Homo sapiens 85-92 27877796-7 2015 The respiration inhibition rate of the bacteria was increased, and the viability of the microbial population was reduced at the high concentration (50 mg L-1) of TiO2. titanium dioxide 162-166 L1 cell adhesion molecule Homo sapiens 154-157 27877796-8 2015 The decreasing number of protozoa in the presence of TiO2 nanoparticles during 20 days of treatment with 0.5 and 1.0 mg L-1 TiO2 is clearly demonstrated. titanium dioxide 53-57 L1 cell adhesion molecule Homo sapiens 120-123 27877796-8 2015 The decreasing number of protozoa in the presence of TiO2 nanoparticles during 20 days of treatment with 0.5 and 1.0 mg L-1 TiO2 is clearly demonstrated. titanium dioxide 124-128 L1 cell adhesion molecule Homo sapiens 120-123 27877796-11 2015 However, the SBR can effectively remove the TiO2 nanoparticles (up to 50 mg L-1) from the effluent. titanium dioxide 44-48 L1 cell adhesion molecule Homo sapiens 76-79 32262775-7 2015 Measurement of the X-ray absorption coefficient revealed that the attenuation of GNS-PEG-NH2 was about 3.6-fold higher than that of the commercial CT contrast agent iodixanol at the concentration of 25 mg L-1. gns-peg-nh2 81-92 L1 cell adhesion molecule Homo sapiens 205-208 25860483-0 2015 Slug-dependent upregulation of L1CAM is responsible for the increased invasion potential of pancreatic cancer cells following long-term 5-FU treatment. Fluorouracil 136-140 L1 cell adhesion molecule Homo sapiens 31-36 25764300-5 2015 It was demonstrated that in our test conditions, the protein complexation by uranium could be simulated by two specific sites (L1 and L2). Uranium 77-84 L1 cell adhesion molecule Homo sapiens 127-136 25793284-11 2015 Surprisingly, in comparison with the binding of Largazole, these analogues trigger alternative conformational changes in loops L1 and L2 flanking the active site. largazole 48-57 L1 cell adhesion molecule Homo sapiens 127-136 32261984-8 2015 Complete bacterial inactivation was achieved for specific amino- and ionic liquid-modifications at 0.125 g L-1, revealing the synergistic effect of ZnO and its modifications, exhibiting up to 2-fold improvement compared to unmodified ZnO. Zinc Oxide 148-151 L1 cell adhesion molecule Homo sapiens 107-110 25635520-3 2015 Neighboring molecules in L1H and 1 are linked into supramolecular chains through hydrogen bonds. Hydrogen 81-89 L1 cell adhesion molecule Homo sapiens 25-34 25461925-3 2014 The SAA was enhanced by 41.0% when the Cu2+ concentration was below 1 mg L-1, while it was improved by 63.5% at Ni2+ concentrations below 1.74 mg L-1. saa 4-7 L1 cell adhesion molecule Homo sapiens 73-76 25666715-1 2015 Two new rhodamine derivatives (L1 and L2) were synthesized, characterized and their ion recognition property has been investigated. Rhodamines 8-17 L1 cell adhesion molecule Homo sapiens 31-40 25830980-5 2015 The ground-state equilibrium geometries of the ligands L1 and L2 and their complexes with Pt(II) are optimized at the BLYP/CEP-31G theoretical level. pt(ii) 90-96 L1 cell adhesion molecule Homo sapiens 55-64 26143332-8 2015 Meanwhile, L1 and L2 showed potential application in bio-imaging after mixing with Cu(2+). cupric ion 83-89 L1 cell adhesion molecule Homo sapiens 11-20 25405529-4 2014 Owing to the metal chelating nature of L-DOPA, 1 was able to sense Fe(3+) and Cu(2+) among a pool of other metal ions by means of fluorescence switching off state, attributed to metal interaction driven assembly of 1 (State-IV). Metals 13-18 L1 cell adhesion molecule Homo sapiens 39-48 25405529-4 2014 Owing to the metal chelating nature of L-DOPA, 1 was able to sense Fe(3+) and Cu(2+) among a pool of other metal ions by means of fluorescence switching off state, attributed to metal interaction driven assembly of 1 (State-IV). ferric sulfate 67-73 L1 cell adhesion molecule Homo sapiens 39-48 25405529-4 2014 Owing to the metal chelating nature of L-DOPA, 1 was able to sense Fe(3+) and Cu(2+) among a pool of other metal ions by means of fluorescence switching off state, attributed to metal interaction driven assembly of 1 (State-IV). cupric ion 78-84 L1 cell adhesion molecule Homo sapiens 39-48 25405529-4 2014 Owing to the metal chelating nature of L-DOPA, 1 was able to sense Fe(3+) and Cu(2+) among a pool of other metal ions by means of fluorescence switching off state, attributed to metal interaction driven assembly of 1 (State-IV). Metals 107-112 L1 cell adhesion molecule Homo sapiens 39-48 25405529-4 2014 Owing to the metal chelating nature of L-DOPA, 1 was able to sense Fe(3+) and Cu(2+) among a pool of other metal ions by means of fluorescence switching off state, attributed to metal interaction driven assembly of 1 (State-IV). Metals 107-112 L1 cell adhesion molecule Homo sapiens 39-48 26116117-0 2014 Paclitaxel improved anti-L1CAM lutetium-177 radioimmunotherapy in an ovarian cancer xenograft model. Paclitaxel 0-10 L1 cell adhesion molecule Homo sapiens 25-30 26116117-0 2014 Paclitaxel improved anti-L1CAM lutetium-177 radioimmunotherapy in an ovarian cancer xenograft model. Lutetium 31-39 L1 cell adhesion molecule Homo sapiens 25-30 26116117-12 2014 CONCLUSIONS: Combination of anti-L1CAM (177)Lu-RIT with PTX is a more effective therapy resulting in a prolonged overall survival of human ovarian carcinoma-bearing nude mice compared with either monotherapy. lu-rit 44-50 L1 cell adhesion molecule Homo sapiens 33-38 25867699-1 2015 Lower rim amide linked 8-amino quinoline and 8-amino naphthalene moiety 1,3,5-triderivatives of calix[6]arene L1 and L2 have been synthesized and characterized. Amides 10-15 L1 cell adhesion molecule Homo sapiens 110-119 25867699-1 2015 Lower rim amide linked 8-amino quinoline and 8-amino naphthalene moiety 1,3,5-triderivatives of calix[6]arene L1 and L2 have been synthesized and characterized. 8-aminoquinoline 23-40 L1 cell adhesion molecule Homo sapiens 110-119 25867699-1 2015 Lower rim amide linked 8-amino quinoline and 8-amino naphthalene moiety 1,3,5-triderivatives of calix[6]arene L1 and L2 have been synthesized and characterized. 1-Naphthylamine 45-64 L1 cell adhesion molecule Homo sapiens 110-119 25867699-1 2015 Lower rim amide linked 8-amino quinoline and 8-amino naphthalene moiety 1,3,5-triderivatives of calix[6]arene L1 and L2 have been synthesized and characterized. 1,3,5-triderivatives 72-92 L1 cell adhesion molecule Homo sapiens 110-119 25867699-1 2015 Lower rim amide linked 8-amino quinoline and 8-amino naphthalene moiety 1,3,5-triderivatives of calix[6]arene L1 and L2 have been synthesized and characterized. arene 104-109 L1 cell adhesion molecule Homo sapiens 110-119 25657495-6 2015 RESULTS: Apart from sodium (2.40%, 3.83%), chloride (2.52% and 2.51%) for both L1 and L2 respectively, and glucose (4.82%), cholesterol (4.86%) for L2, CVs for all other parameters (both L1 and L2) were >5%. Sodium 20-26 L1 cell adhesion molecule Homo sapiens 79-88 25657495-6 2015 RESULTS: Apart from sodium (2.40%, 3.83%), chloride (2.52% and 2.51%) for both L1 and L2 respectively, and glucose (4.82%), cholesterol (4.86%) for L2, CVs for all other parameters (both L1 and L2) were >5%. Chlorides 43-51 L1 cell adhesion molecule Homo sapiens 79-88 25461925-3 2014 The SAA was enhanced by 41.0% when the Cu2+ concentration was below 1 mg L-1, while it was improved by 63.5% at Ni2+ concentrations below 1.74 mg L-1. saa 4-7 L1 cell adhesion molecule Homo sapiens 146-149 25461925-3 2014 The SAA was enhanced by 41.0% when the Cu2+ concentration was below 1 mg L-1, while it was improved by 63.5% at Ni2+ concentrations below 1.74 mg L-1. cupric ion 39-43 L1 cell adhesion molecule Homo sapiens 73-76 25461925-4 2014 An enhancement of 533.2% was obtained when 3.68 mg L-1 Fe3+ was supplied. ferric sulfate 55-59 L1 cell adhesion molecule Homo sapiens 51-54 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. Nickel(2+) 30-34 L1 cell adhesion molecule Homo sapiens 209-212 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. Nickel(2+) 30-34 L1 cell adhesion molecule Homo sapiens 227-230 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. Nickel(2+) 30-34 L1 cell adhesion molecule Homo sapiens 227-230 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. saa 42-45 L1 cell adhesion molecule Homo sapiens 209-212 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. saa 42-45 L1 cell adhesion molecule Homo sapiens 227-230 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. saa 42-45 L1 cell adhesion molecule Homo sapiens 227-230 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. cupric ion 166-170 L1 cell adhesion molecule Homo sapiens 209-212 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. cupric ion 166-170 L1 cell adhesion molecule Homo sapiens 227-230 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. cupric ion 166-170 L1 cell adhesion molecule Homo sapiens 227-230 25461925-5 2014 The effects of Fe3+, Cu2+ and Ni2+ on the SAA were analyzed and optimized by a response surface methodology, which demonstrated that the interaction between Fe3+ and Cu2+ was significant and that 6.61 mg Fe3+ L-1, 1.18 mg Cu2+ L-1 and 1.11 mg Ni2+ L-1 were the optimal values for metal dosing. ni2 30-33 L1 cell adhesion molecule Homo sapiens 209-212 25078493-1 2014 Two N^N Pt(II) bis(acetylide) complexes Pt-1 and Pt-2 with regioisomeric amino NI acetylide ligands (L-1 and L-2, L-1 = 5-amino-4-ethylnaphthaleneimide; L-2 = 3-amino-4-ethylnaphthaleneimide) were prepared. bis(acetylide) 15-29 L1 cell adhesion molecule Homo sapiens 101-104 25209556-7 2014 The solution-state anion binding properties of L1 and L2 have been investigated by qualitative and quantitative (1)H NMR titration experiments with halides and oxyanions in DMSO-d6. halides 148-155 L1 cell adhesion molecule Homo sapiens 47-56 25209556-7 2014 The solution-state anion binding properties of L1 and L2 have been investigated by qualitative and quantitative (1)H NMR titration experiments with halides and oxyanions in DMSO-d6. Dimethyl sulfoxide-d6 173-180 L1 cell adhesion molecule Homo sapiens 47-56 25333939-4 2014 The metal-binding properties of L1 and L2 were probed by pH spectrophotometric titrations to determine their pKa values and the corresponding metal complex stability constants, and the isolated metal complexes were structurally characterized. Metals 4-9 L1 cell adhesion molecule Homo sapiens 32-41 25333939-4 2014 The metal-binding properties of L1 and L2 were probed by pH spectrophotometric titrations to determine their pKa values and the corresponding metal complex stability constants, and the isolated metal complexes were structurally characterized. Metals 142-147 L1 cell adhesion molecule Homo sapiens 32-41 25333939-4 2014 The metal-binding properties of L1 and L2 were probed by pH spectrophotometric titrations to determine their pKa values and the corresponding metal complex stability constants, and the isolated metal complexes were structurally characterized. Metals 142-147 L1 cell adhesion molecule Homo sapiens 32-41 25333939-5 2014 The amyloid-fibril-binding properties of L1 and L2 were investigated by fluorescence titrations and ThT competition assays. thioflavin T 100-103 L1 cell adhesion molecule Homo sapiens 41-50 25333939-7 2014 In addition, L1 and L2 were able to reduce the cell toxicity of preformed Abeta42 oligomers and of the copper-stabilized Abeta42 oligomers. Copper 103-109 L1 cell adhesion molecule Homo sapiens 13-22 25337593-5 2014 L1CAM expression was evaluated by immunohistochemistry using fresh formalin-fixed paraffin-embedded tissue block of the patients. Formaldehyde 67-75 L1 cell adhesion molecule Homo sapiens 0-5 25337593-5 2014 L1CAM expression was evaluated by immunohistochemistry using fresh formalin-fixed paraffin-embedded tissue block of the patients. Paraffin 82-90 L1 cell adhesion molecule Homo sapiens 0-5 24859811-0 2014 Anti-L1CAM radioimmunotherapy is more effective with the radiolanthanide terbium-161 compared to lutetium-177 in an ovarian cancer model. radiolanthanide 57-72 L1 cell adhesion molecule Homo sapiens 5-10 24859811-0 2014 Anti-L1CAM radioimmunotherapy is more effective with the radiolanthanide terbium-161 compared to lutetium-177 in an ovarian cancer model. Terbium-161 73-84 L1 cell adhesion molecule Homo sapiens 5-10 24859811-0 2014 Anti-L1CAM radioimmunotherapy is more effective with the radiolanthanide terbium-161 compared to lutetium-177 in an ovarian cancer model. Lutetium-177 97-109 L1 cell adhesion molecule Homo sapiens 5-10 25078493-1 2014 Two N^N Pt(II) bis(acetylide) complexes Pt-1 and Pt-2 with regioisomeric amino NI acetylide ligands (L-1 and L-2, L-1 = 5-amino-4-ethylnaphthaleneimide; L-2 = 3-amino-4-ethylnaphthaleneimide) were prepared. bis(acetylide) 15-29 L1 cell adhesion molecule Homo sapiens 114-117 24057655-1 2014 A series of Schiff bases (L 1 , L 2 and L 3) were prepared by refluxing aromatic aldehydes with N-Aminopyrimidine derivatives in methanol and ethanol. Schiff Bases 12-24 L1 cell adhesion molecule Homo sapiens 26-43 24242293-0 2014 A standardized staining protocol for L1CAM on formalin-fixed, paraffin-embedded tissues using automated platforms. Formaldehyde 46-54 L1 cell adhesion molecule Homo sapiens 37-42 24558643-1 2014 The effect of substituents on FRET in two newly designed rhodamine-based Hg(2+) ion selective chemosensors (L1 and L2) has been explored by a systematic experimental and theoretical study. Rhodamines 57-66 L1 cell adhesion molecule Homo sapiens 108-117 24458564-5 2014 Batch culture of G. ajoucoccus A2(T) in a bioreactor containing 1 % (v/v) hexadecane or 1 % (v/v) commercial diesel yielded 25 mg L-1 and 2.6 mg L-1 of carotenoids, respectively. n-hexadecane 74-84 L1 cell adhesion molecule Homo sapiens 130-139 24517515-5 2014 By co-overexpressing AroF(Delta(1-11)) and PheA(fbr) , the production of l-Phe was increased from 2.36 +- 0.07 g L(-1) (co-overexpression of the wild-type AroF and PheA(fbr) ) to 4.29 +- 0.06 g L(-1) . poly(2-hydroxyethyl acrylate) 43-47 L1 cell adhesion molecule Homo sapiens 113-118 24517515-5 2014 By co-overexpressing AroF(Delta(1-11)) and PheA(fbr) , the production of l-Phe was increased from 2.36 +- 0.07 g L(-1) (co-overexpression of the wild-type AroF and PheA(fbr) ) to 4.29 +- 0.06 g L(-1) . poly(2-hydroxyethyl acrylate) 43-47 L1 cell adhesion molecule Homo sapiens 194-199 24517515-5 2014 By co-overexpressing AroF(Delta(1-11)) and PheA(fbr) , the production of l-Phe was increased from 2.36 +- 0.07 g L(-1) (co-overexpression of the wild-type AroF and PheA(fbr) ) to 4.29 +- 0.06 g L(-1) . Phenylalanine 73-78 L1 cell adhesion molecule Homo sapiens 113-118 24517515-5 2014 By co-overexpressing AroF(Delta(1-11)) and PheA(fbr) , the production of l-Phe was increased from 2.36 +- 0.07 g L(-1) (co-overexpression of the wild-type AroF and PheA(fbr) ) to 4.29 +- 0.06 g L(-1) . Phenylalanine 73-78 L1 cell adhesion molecule Homo sapiens 194-199 24057655-1 2014 A series of Schiff bases (L 1 , L 2 and L 3) were prepared by refluxing aromatic aldehydes with N-Aminopyrimidine derivatives in methanol and ethanol. aromatic aldehydes 72-90 L1 cell adhesion molecule Homo sapiens 26-43 24057655-1 2014 A series of Schiff bases (L 1 , L 2 and L 3) were prepared by refluxing aromatic aldehydes with N-Aminopyrimidine derivatives in methanol and ethanol. n-aminopyrimidine 96-113 L1 cell adhesion molecule Homo sapiens 26-43 24057655-1 2014 A series of Schiff bases (L 1 , L 2 and L 3) were prepared by refluxing aromatic aldehydes with N-Aminopyrimidine derivatives in methanol and ethanol. Methanol 129-137 L1 cell adhesion molecule Homo sapiens 26-43 24057655-1 2014 A series of Schiff bases (L 1 , L 2 and L 3) were prepared by refluxing aromatic aldehydes with N-Aminopyrimidine derivatives in methanol and ethanol. Ethanol 130-137 L1 cell adhesion molecule Homo sapiens 26-43 24407901-1 2013 This case report presents a 49 year-old female with type 1 diabetes admitted to the intensive care unit with acute respiratory failure and severe diabetic ketoacidosis with an initial measurement of blood glucose level of 1,200 mg L-1, pH 6.78, serum HCO3 - 3.2 mmoL L-1 and BE -31.2 mmoL L-1. Glucose 205-212 L1 cell adhesion molecule Homo sapiens 231-234 24225399-6 2014 Pathway analysis identified leukotriene and eoxin synthesis, platelet homeostasis, and L1CAM interactions as potential pathways associated with gemcitabine disposition. gemcitabine 144-155 L1 cell adhesion molecule Homo sapiens 87-92 31986655-6 2013 The coordination nitrogen atoms in two pairs of ortho-positioned nitrogen-containing chelating rings in L1 and L5 are directed toward opposite and the same directions, respectively. Nitrogen 17-25 L1 cell adhesion molecule Homo sapiens 104-113 31986655-6 2013 The coordination nitrogen atoms in two pairs of ortho-positioned nitrogen-containing chelating rings in L1 and L5 are directed toward opposite and the same directions, respectively. Nitrogen 65-73 L1 cell adhesion molecule Homo sapiens 104-113 23939620-6 2013 Thus, the RNA loading and tight coupling of NTPase activity with RNA translocation in 8 P4 is due to a remarkable C-terminal structure, which wraps right around the outside of the molecule to insert into the central hole where RNA binds to coupled L1 and L2 loops, whereas in 12 P4, a C-terminal residue, serine 282, forms a specific hydrogen bond to the N7 of purines ring to confer purine specificity for the 12 enzyme. Serine 305-311 L1 cell adhesion molecule Homo sapiens 248-257 23939620-6 2013 Thus, the RNA loading and tight coupling of NTPase activity with RNA translocation in 8 P4 is due to a remarkable C-terminal structure, which wraps right around the outside of the molecule to insert into the central hole where RNA binds to coupled L1 and L2 loops, whereas in 12 P4, a C-terminal residue, serine 282, forms a specific hydrogen bond to the N7 of purines ring to confer purine specificity for the 12 enzyme. Hydrogen 334-342 L1 cell adhesion molecule Homo sapiens 248-257 23939620-6 2013 Thus, the RNA loading and tight coupling of NTPase activity with RNA translocation in 8 P4 is due to a remarkable C-terminal structure, which wraps right around the outside of the molecule to insert into the central hole where RNA binds to coupled L1 and L2 loops, whereas in 12 P4, a C-terminal residue, serine 282, forms a specific hydrogen bond to the N7 of purines ring to confer purine specificity for the 12 enzyme. Purines 361-368 L1 cell adhesion molecule Homo sapiens 248-257 23939620-6 2013 Thus, the RNA loading and tight coupling of NTPase activity with RNA translocation in 8 P4 is due to a remarkable C-terminal structure, which wraps right around the outside of the molecule to insert into the central hole where RNA binds to coupled L1 and L2 loops, whereas in 12 P4, a C-terminal residue, serine 282, forms a specific hydrogen bond to the N7 of purines ring to confer purine specificity for the 12 enzyme. purine 361-367 L1 cell adhesion molecule Homo sapiens 248-257 24126818-0 2014 Chlorhexidine inhibits L1 cell adhesion molecule-mediated neurite outgrowth in vitro. Chlorhexidine 0-13 L1 cell adhesion molecule Homo sapiens 23-48 25098879-5 2014 At the end of stage III, the ammonium concentration was 6 mg L-1, which is lower than that established by Brazilian regulations for wastewater discharge (CONAMA 430/2011). Ammonium Compounds 29-37 L1 cell adhesion molecule Homo sapiens 61-64 23525160-1 2013 Reactions of the related ligands 2-(N,N-bis(2-pyridyl)amino)-4,6-bis(phenoxy)-(1,3,5)triazine (L1) and 2-(N,N-bis(2-pyridyl)amino)-4,6-bis(pentafluorophenoxy)-(1,3,5)triazine (L1(F)) with iron(II) thiocyanate produced two spin-crossover coordination compounds with distinct cooperative behaviours. 2-(n,n-bis(2-pyridyl)amino)-4,6-bis(phenoxy)-(1,3,5)triazine 33-93 L1 cell adhesion molecule Homo sapiens 95-97 23806079-11 2013 Moreover, the migration and invasion promoted by L1cam overexpression in gastric cancer cells could be abolished by either application of LY294002 (a phosphoinositide-3-kinase inhibitor) or knockdown of endogenous Akt by small interfering RNA. 2-(4-morpholinyl)-8-phenyl-4H-1-benzopyran-4-one 138-146 L1 cell adhesion molecule Homo sapiens 49-54 22922343-7 2012 In both control and short-term zolpidem treated groups, addition of GABA (1 nmol/L-1 mmol/L) enhanced [(3)H]flunitrazepam binding in a concentration-dependent manner. Zolpidem 31-39 L1 cell adhesion molecule Homo sapiens 81-84 23585728-1 2013 A triptycene-based bis(benzimidazole) ester ligand, L3, was designed to enhance the electron donating ability of the heterocyclic nitrogen atoms relative to those of the first generation bis(benzoxazole) analogs, L1 and L2. triptycene-based bis(benzimidazole) ester 2-43 L1 cell adhesion molecule Homo sapiens 213-222 22544341-0 2013 L1CAM from human melanoma carries a novel type of N-glycan with Galbeta1-4Galbeta1- motif. n-glycan 50-58 L1 cell adhesion molecule Homo sapiens 0-5 22544341-3 2013 We analysed the N-linked glycans of L1CAM from different stages of melanoma progression, using high-performance liquid chromatography combined with exoglycosidase sequencing, matrix-assisted laser desorption/ionisation time-of-flight mass spectrometry, and lectin probes. n-linked glycans 16-32 L1 cell adhesion molecule Homo sapiens 36-41 22544341-4 2013 L1CAM oligosaccharides are heavily sialylated, mainly digalactosylated, biantennary complex-type structures with galactose beta1-4/3-linked to GlcNAc and with or without fucose alpha1-3/6-linked to GlcNAc. Galactose 113-122 L1 cell adhesion molecule Homo sapiens 0-5 22544341-4 2013 L1CAM oligosaccharides are heavily sialylated, mainly digalactosylated, biantennary complex-type structures with galactose beta1-4/3-linked to GlcNAc and with or without fucose alpha1-3/6-linked to GlcNAc. 2-acetamido-2-deoxy-4-O-(beta-2-acetamid-2-deoxyglucopyranosyl)glucopyranose 143-149 L1 cell adhesion molecule Homo sapiens 0-5 22544341-4 2013 L1CAM oligosaccharides are heavily sialylated, mainly digalactosylated, biantennary complex-type structures with galactose beta1-4/3-linked to GlcNAc and with or without fucose alpha1-3/6-linked to GlcNAc. Fucose 170-176 L1 cell adhesion molecule Homo sapiens 0-5 22544341-4 2013 L1CAM oligosaccharides are heavily sialylated, mainly digalactosylated, biantennary complex-type structures with galactose beta1-4/3-linked to GlcNAc and with or without fucose alpha1-3/6-linked to GlcNAc. 2-acetamido-2-deoxy-4-O-(beta-2-acetamid-2-deoxyglucopyranosyl)glucopyranose 198-204 L1 cell adhesion molecule Homo sapiens 0-5 22544341-6 2013 We found that metastatic L1CAM possesses only alpha2-6-linked sialic acid and the loss of alpha2-3-linked sialic acid in L1CAM is a phenomenon observed during the transition of melanoma cells from VGP to a metastatic stage. N-Acetylneuraminic Acid 62-73 L1 cell adhesion molecule Homo sapiens 25-30 22544341-6 2013 We found that metastatic L1CAM possesses only alpha2-6-linked sialic acid and the loss of alpha2-3-linked sialic acid in L1CAM is a phenomenon observed during the transition of melanoma cells from VGP to a metastatic stage. N-Acetylneuraminic Acid 106-117 L1 cell adhesion molecule Homo sapiens 121-126 22544341-12 2013 Complex-type oligosaccharides in L1CAM enhance the invasiveness of metastatic melanoma cells. Oligosaccharides 13-29 L1 cell adhesion molecule Homo sapiens 33-38 23311731-4 2013 This Gal-4 reduction, as inhibition of sulfatide synthesis does, lowers the presence and clustered organization of axon growth-promoting molecule NCAM L1 at the axon membrane. Sulfoglycosphingolipids 39-48 L1 cell adhesion molecule Homo sapiens 146-153 23530769-20 2013 Although genes localized on Xq28 are often re-expressed by human tumors, L1CAM and CT-X antigens show distinct regulation in response to HADC inhibitors and 5-AzaC. Azacitidine 157-163 L1 cell adhesion molecule Homo sapiens 73-78 23755493-9 2013 L-1 and CaCl2 <10 mmol L-1) , the adsorption amount of DNA on the red soil colloids increased significantly with the increase of electrolyte concentration. Calcium Chloride 8-13 L1 cell adhesion molecule Homo sapiens 26-29 23111172-3 2013 Most of this copper is organically complexed by a strong ligand (L(1)) with a concentration that varies between 19 and 55 nM and a log K" between 14.14 and 15.75. Copper 13-19 L1 cell adhesion molecule Homo sapiens 65-69 23565233-2 2013 In the present study, we have investigated the influence of different numbers of 1,4,7,10-tetraazacyclododecane-N-N"-N""-N"""-tetraacetic acid (DOTA) chelats coupled to a decalysine backbone on the in vivo behavior of the chimeric monoclonal anti-L1CAM antibody chCE7agl. 1,4,7,10-tetraazacyclododecane- 1,4,7,10-tetraacetic acid 81-142 L1 cell adhesion molecule Homo sapiens 247-252 23530769-12 2013 RESULTS: We demonstrate that the treatment of L1CAM low/negative expressing EC cell lines with 5"-Azacytidine (5-AzaC) or knock-down of DNMT1 (DNA methyltransferase 1) as well as the HDAC (histone deacetylase) inhibitor Trichostatin A (TSA) up-regulated L1CAM at the mRNA and protein level. Azacitidine 95-109 L1 cell adhesion molecule Homo sapiens 46-51 23530769-12 2013 RESULTS: We demonstrate that the treatment of L1CAM low/negative expressing EC cell lines with 5"-Azacytidine (5-AzaC) or knock-down of DNMT1 (DNA methyltransferase 1) as well as the HDAC (histone deacetylase) inhibitor Trichostatin A (TSA) up-regulated L1CAM at the mRNA and protein level. Azacitidine 111-117 L1 cell adhesion molecule Homo sapiens 46-51 23530769-12 2013 RESULTS: We demonstrate that the treatment of L1CAM low/negative expressing EC cell lines with 5"-Azacytidine (5-AzaC) or knock-down of DNMT1 (DNA methyltransferase 1) as well as the HDAC (histone deacetylase) inhibitor Trichostatin A (TSA) up-regulated L1CAM at the mRNA and protein level. trichostatin A 220-234 L1 cell adhesion molecule Homo sapiens 46-51 23530769-12 2013 RESULTS: We demonstrate that the treatment of L1CAM low/negative expressing EC cell lines with 5"-Azacytidine (5-AzaC) or knock-down of DNMT1 (DNA methyltransferase 1) as well as the HDAC (histone deacetylase) inhibitor Trichostatin A (TSA) up-regulated L1CAM at the mRNA and protein level. trichostatin A 236-239 L1 cell adhesion molecule Homo sapiens 46-51 23530769-14 2013 We observed that the expression of L1CAM correlated with hypermethylation in promoter 1 and 5-AzaC treatment affected the DNA-methylation pattern in this region. 3,5-di-t-butyl-4-methylphenyl N-methylcarbamate 94-98 L1 cell adhesion molecule Homo sapiens 35-40 22922343-7 2012 In both control and short-term zolpidem treated groups, addition of GABA (1 nmol/L-1 mmol/L) enhanced [(3)H]flunitrazepam binding in a concentration-dependent manner. gamma-Aminobutyric Acid 68-72 L1 cell adhesion molecule Homo sapiens 81-84 22922343-7 2012 In both control and short-term zolpidem treated groups, addition of GABA (1 nmol/L-1 mmol/L) enhanced [(3)H]flunitrazepam binding in a concentration-dependent manner. Flunitrazepam 108-121 L1 cell adhesion molecule Homo sapiens 81-84 23093480-1 2012 The coordination properties of Pt(II) with 5-amino-1,3,4-thiadiazole-2-thiol [CAS 2349-67-9] (L 1 ) and its novel violurate adduct (L 2 ), both in solution and in solid state, are studied by means of conventional IR-spectroscopy, single crystal X-ray diffraction and thermal methods. pt(ii) 31-37 L1 cell adhesion molecule Homo sapiens 94-98 23093480-1 2012 The coordination properties of Pt(II) with 5-amino-1,3,4-thiadiazole-2-thiol [CAS 2349-67-9] (L 1 ) and its novel violurate adduct (L 2 ), both in solution and in solid state, are studied by means of conventional IR-spectroscopy, single crystal X-ray diffraction and thermal methods. 2-amino-5-mercapto-1,3,4-thiadiazole 43-76 L1 cell adhesion molecule Homo sapiens 94-98 23093480-1 2012 The coordination properties of Pt(II) with 5-amino-1,3,4-thiadiazole-2-thiol [CAS 2349-67-9] (L 1 ) and its novel violurate adduct (L 2 ), both in solution and in solid state, are studied by means of conventional IR-spectroscopy, single crystal X-ray diffraction and thermal methods. Calcium 78-81 L1 cell adhesion molecule Homo sapiens 94-98 23093480-2 2012 The complex compounds of L 1 and L 2 , with general formulas [Pt(C2H2N3S2)2] and [Pt(C6H4N6S2O3)(Cl)]Cl respectively, are obtained. cl)]cl 100-106 L1 cell adhesion molecule Homo sapiens 25-29 22589065-3 2012 Underlying polymer substrates were modified with varying combinations of protein A and poly-D-lysine to modulate the immobilization and presentation of the Fc fusion fragment of the extracellular domain of L1 (L1-Fc). Polymers 11-18 L1 cell adhesion molecule Homo sapiens 206-208 22589065-3 2012 Underlying polymer substrates were modified with varying combinations of protein A and poly-D-lysine to modulate the immobilization and presentation of the Fc fusion fragment of the extracellular domain of L1 (L1-Fc). Polymers 11-18 L1 cell adhesion molecule Homo sapiens 210-215 22589065-3 2012 Underlying polymer substrates were modified with varying combinations of protein A and poly-D-lysine to modulate the immobilization and presentation of the Fc fusion fragment of the extracellular domain of L1 (L1-Fc). D-Lysine 87-100 L1 cell adhesion molecule Homo sapiens 206-208 22589065-3 2012 Underlying polymer substrates were modified with varying combinations of protein A and poly-D-lysine to modulate the immobilization and presentation of the Fc fusion fragment of the extracellular domain of L1 (L1-Fc). D-Lysine 87-100 L1 cell adhesion molecule Homo sapiens 210-215 22589065-4 2012 When presented as an oriented and multimeric configuration from protein A-pretreated polymers, L1-Fc significantly increased neurite outgrowth of rodent spinal cord neurons and cerebellar neurons as early as 24 h compared to the traditional presentation via adsorption onto surfaces treated with poly-D-lysine. Polymers 85-93 L1 cell adhesion molecule Homo sapiens 95-100 22589065-4 2012 When presented as an oriented and multimeric configuration from protein A-pretreated polymers, L1-Fc significantly increased neurite outgrowth of rodent spinal cord neurons and cerebellar neurons as early as 24 h compared to the traditional presentation via adsorption onto surfaces treated with poly-D-lysine. D-Lysine 296-309 L1 cell adhesion molecule Homo sapiens 95-100 22824155-6 2012 Fe(II) complexes of L1, L2, and L3 show 25-28% cleavage of supercoiled plasmid DNA in the presence of peroxide and ascorbate over 2h at 37 C while [Fe(L4)](2+) shows 6% cleavage. ammonium ferrous sulfate 0-6 L1 cell adhesion molecule Homo sapiens 20-34 22824155-6 2012 Fe(II) complexes of L1, L2, and L3 show 25-28% cleavage of supercoiled plasmid DNA in the presence of peroxide and ascorbate over 2h at 37 C while [Fe(L4)](2+) shows 6% cleavage. Peroxides 102-110 L1 cell adhesion molecule Homo sapiens 20-34 22824155-6 2012 Fe(II) complexes of L1, L2, and L3 show 25-28% cleavage of supercoiled plasmid DNA in the presence of peroxide and ascorbate over 2h at 37 C while [Fe(L4)](2+) shows 6% cleavage. Ascorbic Acid 115-124 L1 cell adhesion molecule Homo sapiens 20-34 22824155-6 2012 Fe(II) complexes of L1, L2, and L3 show 25-28% cleavage of supercoiled plasmid DNA in the presence of peroxide and ascorbate over 2h at 37 C while [Fe(L4)](2+) shows 6% cleavage. fe(l4) 149-155 L1 cell adhesion molecule Homo sapiens 20-34 22948185-7 2012 L1CAM expressing GBM cells and differentiated glioma stem-like cells showed a reduced apoptotic response after treatment with the chemotherapeutic drug temozolomide. Temozolomide 152-164 L1 cell adhesion molecule Homo sapiens 0-5 23048039-8 2012 Previously, we reported the interaction of Rabex-5, a UBP and guanine nucleotide exchange factor (GEF) for Rab5, with ubiquitinated neural cell adhesion molecule L1, via its motif interacting with Ub (MIU) domain. N-{(1S)-1-{[4-(3-AMINOPROPYL)PIPERAZIN-1-YL]CARBONYL}-4-[(DIAMINOMETHYLENE)AMINO]BUTYL}-3-(TRIFLUOROMETHYL)BENZENESULFONAMIDE 201-204 L1 cell adhesion molecule Homo sapiens 132-164 22633866-10 2012 Several compounds have been detected, but perfluorooctanoic acid (PFOA) (171 ng L-1 and 148 ng L-1 by UHPLC-MS/MS and CLC-MS, respectively) showed the highest concentration. perfluorooctanoic acid 42-64 L1 cell adhesion molecule Homo sapiens 80-98 22714056-1 2012 A polypyrrolic macrocycle with naphthalenyl linkers between the N(4)-donor compartments (L(2)) was designed theoretically according to its experimentally-known analogues with phenylenyl (L(1)) and anthracenyl (L(3)) linkers. naphthalenyl 31-43 L1 cell adhesion molecule Homo sapiens 187-191 22714056-7 2012 Regarding the bis(uranyl) L(1), L(2) and L(3) complexes, the phenylenyl-hinge L(1) complexes adopt a butterfly-like and a T-shaped isomer in the oxidation state of U(vi), but only a butterfly-like one in the U(v), which differs from that of the naphthalenyl-hinge L(2) complexes as well as the lateral twisted structure of the anthracenyl-hinge L(3) complexes. (uranyl 17-24 L1 cell adhesion molecule Homo sapiens 78-82 22784808-4 2012 In the system with 0.125 g L-1 of Fe2.02Ti0.98O4 and 10 mmol L-1) of H2O2, almost complete degradation of TBBPA (20 mg L-1) was accomplished within 240 min UV irradiation at pH 6.5. Hydrogen Peroxide 69-73 L1 cell adhesion molecule Homo sapiens 27-30 22784808-4 2012 In the system with 0.125 g L-1 of Fe2.02Ti0.98O4 and 10 mmol L-1) of H2O2, almost complete degradation of TBBPA (20 mg L-1) was accomplished within 240 min UV irradiation at pH 6.5. Hydrogen Peroxide 69-73 L1 cell adhesion molecule Homo sapiens 61-64 22784808-4 2012 In the system with 0.125 g L-1 of Fe2.02Ti0.98O4 and 10 mmol L-1) of H2O2, almost complete degradation of TBBPA (20 mg L-1) was accomplished within 240 min UV irradiation at pH 6.5. Hydrogen Peroxide 69-73 L1 cell adhesion molecule Homo sapiens 61-64 22784808-4 2012 In the system with 0.125 g L-1 of Fe2.02Ti0.98O4 and 10 mmol L-1) of H2O2, almost complete degradation of TBBPA (20 mg L-1) was accomplished within 240 min UV irradiation at pH 6.5. tetrabromobisphenol A 106-111 L1 cell adhesion molecule Homo sapiens 27-30 22784808-4 2012 In the system with 0.125 g L-1 of Fe2.02Ti0.98O4 and 10 mmol L-1) of H2O2, almost complete degradation of TBBPA (20 mg L-1) was accomplished within 240 min UV irradiation at pH 6.5. tetrabromobisphenol A 106-111 L1 cell adhesion molecule Homo sapiens 61-64 22784808-4 2012 In the system with 0.125 g L-1 of Fe2.02Ti0.98O4 and 10 mmol L-1) of H2O2, almost complete degradation of TBBPA (20 mg L-1) was accomplished within 240 min UV irradiation at pH 6.5. tetrabromobisphenol A 106-111 L1 cell adhesion molecule Homo sapiens 61-64 22633866-10 2012 Several compounds have been detected, but perfluorooctanoic acid (PFOA) (171 ng L-1 and 148 ng L-1 by UHPLC-MS/MS and CLC-MS, respectively) showed the highest concentration. perfluorooctanoic acid 66-70 L1 cell adhesion molecule Homo sapiens 80-98 31832074-2 2012 PEG-PVA-Ad polymer forms micelles via self-assembly at concentrations as low as 26 mg L-1. ethylene-vinyl alcohol copolymer 4-7 L1 cell adhesion molecule Homo sapiens 86-89 31832074-2 2012 PEG-PVA-Ad polymer forms micelles via self-assembly at concentrations as low as 26 mg L-1. Adamantane 8-10 L1 cell adhesion molecule Homo sapiens 86-89 22143433-3 2012 Photophysical measurements demonstrate that in [Cu(2)(L(1))(2)](2+), [CdL(1)](2+) and [Cu(2)(L(2))(2)](2+) the emission spectra are dominated by monomeric emission but in the cadmium complex of L(2) (where the pyrene units are in close proximity) a quenching of the luminescence coupled with weak emission at 540 nm is indicative of excimer formation. Copper 48-50 L1 cell adhesion molecule Homo sapiens 54-58 22472175-10 2012 Suppression of L1CAM expression in ATC cell lines increased chemosensitivity to gemcitabine or paclitaxel. gemcitabine 80-91 L1 cell adhesion molecule Homo sapiens 15-20 22472175-10 2012 Suppression of L1CAM expression in ATC cell lines increased chemosensitivity to gemcitabine or paclitaxel. Paclitaxel 95-105 L1 cell adhesion molecule Homo sapiens 15-20 21796623-13 2012 We conclude that a single dose of (177)Lu-DOTA-chCE7agl is as effective as repeated administration of nonradioactive chCE7 for treatment of small intraperitoneal tumors expressing L1-CAM. lu-dota 39-46 L1 cell adhesion molecule Homo sapiens 180-186 22513652-2 2012 This multifunctional use of the sulfide source has been achieved through a fine tuning of ((Cu2+)(a)(Zn2+)(b)(Sn4+)(c)(Tu)(d)(OH-)(e))(t+), Tu = thiourea) oligomers, leading after temperature polycondensation and S2- exchange to highly concentrated (c > 100 g l-1), stable, ethanolic CZTS dispersions. Sulfides 32-39 L1 cell adhesion molecule Homo sapiens 263-266 21860410-3 2012 In this study we demonstrate that inhibition of hypoxia-inducible factor (HIF) activity in BrCa cells by RNA interference or digoxin treatment inhibits primary tumor growth and also inhibits the metastasis of BrCa cells to the lungs by blocking the expression of angiopoietin-like 4 (ANGPTL4) and L1 cell adhesion molecule (L1CAM). Digoxin 125-132 L1 cell adhesion molecule Homo sapiens 297-322 21860410-3 2012 In this study we demonstrate that inhibition of hypoxia-inducible factor (HIF) activity in BrCa cells by RNA interference or digoxin treatment inhibits primary tumor growth and also inhibits the metastasis of BrCa cells to the lungs by blocking the expression of angiopoietin-like 4 (ANGPTL4) and L1 cell adhesion molecule (L1CAM). Digoxin 125-132 L1 cell adhesion molecule Homo sapiens 324-329 22088438-0 2012 L1 cell adhesion molecule and epidermal growth factor receptor activation confer cisplatin resistance in intrahepatic cholangiocarcinoma cells. Cisplatin 81-90 L1 cell adhesion molecule Homo sapiens 0-25 22088438-3 2012 Here, we report that epidermal growth factor receptor (EGFR) signaling and L1 cell adhesion molecule (L1CAM) conferred cisplatin resistance in SCK(R) cells in an additive fashion. Cisplatin 119-128 L1 cell adhesion molecule Homo sapiens 75-100 22088438-3 2012 Here, we report that epidermal growth factor receptor (EGFR) signaling and L1 cell adhesion molecule (L1CAM) conferred cisplatin resistance in SCK(R) cells in an additive fashion. Cisplatin 119-128 L1 cell adhesion molecule Homo sapiens 102-107 22519733-0 2012 Imino-phenolic-pyridyl conjugates of calix[4]arene (L1 and L2) as primary fluorescence switch-on sensors for Zn2+ in solution and in HeLa cells and the recognition of pyrophosphate and ATP by [ZnL2]. phenolic 6-14 L1 cell adhesion molecule Homo sapiens 52-61 22519733-0 2012 Imino-phenolic-pyridyl conjugates of calix[4]arene (L1 and L2) as primary fluorescence switch-on sensors for Zn2+ in solution and in HeLa cells and the recognition of pyrophosphate and ATP by [ZnL2]. calix(4)arene 37-50 L1 cell adhesion molecule Homo sapiens 52-61 22519733-0 2012 Imino-phenolic-pyridyl conjugates of calix[4]arene (L1 and L2) as primary fluorescence switch-on sensors for Zn2+ in solution and in HeLa cells and the recognition of pyrophosphate and ATP by [ZnL2]. Zinc 109-113 L1 cell adhesion molecule Homo sapiens 52-61 22519733-0 2012 Imino-phenolic-pyridyl conjugates of calix[4]arene (L1 and L2) as primary fluorescence switch-on sensors for Zn2+ in solution and in HeLa cells and the recognition of pyrophosphate and ATP by [ZnL2]. diphosphoric acid 167-180 L1 cell adhesion molecule Homo sapiens 52-61 22519733-0 2012 Imino-phenolic-pyridyl conjugates of calix[4]arene (L1 and L2) as primary fluorescence switch-on sensors for Zn2+ in solution and in HeLa cells and the recognition of pyrophosphate and ATP by [ZnL2]. Adenosine Triphosphate 185-188 L1 cell adhesion molecule Homo sapiens 52-61 22143433-3 2012 Photophysical measurements demonstrate that in [Cu(2)(L(1))(2)](2+), [CdL(1)](2+) and [Cu(2)(L(2))(2)](2+) the emission spectra are dominated by monomeric emission but in the cadmium complex of L(2) (where the pyrene units are in close proximity) a quenching of the luminescence coupled with weak emission at 540 nm is indicative of excimer formation. cu(2) 48-53 L1 cell adhesion molecule Homo sapiens 54-58 22680631-4 2012 Complete synthetic and structural studies of Au(I) and Ag(I) complexes of 2-(1-methylimidazolium) pyrimidinechloride (L-1), 2,6-bis(1-methylimidazol)pyrazinechloride (L-2) and 2,6-bis(1-methyl imidazol) pyrazinehexa-fluorophosphate (L-3) are reported herein. Gold 45-47 L1 cell adhesion molecule Homo sapiens 118-121 22680631-4 2012 Complete synthetic and structural studies of Au(I) and Ag(I) complexes of 2-(1-methylimidazolium) pyrimidinechloride (L-1), 2,6-bis(1-methylimidazol)pyrazinechloride (L-2) and 2,6-bis(1-methyl imidazol) pyrazinehexa-fluorophosphate (L-3) are reported herein. 2-(1-methylimidazolium) pyrimidinechloride 74-116 L1 cell adhesion molecule Homo sapiens 118-121 21359603-12 2011 A good outcome, matrix microspheres (coded as MIC5) containing PRD-HPbetaCD complex, showed sustained release of drug (95.81%) over a period of 24 h. hpbetacd 67-75 L1 cell adhesion molecule Homo sapiens 46-50 22160459-6 2011 Our results indicate that hydrogen peroxide treatment induces an increase in the retrotransposition of transiently transfected L1(RP) and an increase in the expression of endogenous L1 transcripts. Hydrogen Peroxide 26-43 L1 cell adhesion molecule Homo sapiens 127-133 21943715-1 2011 Three N,N"-dipyridoxyl Schiff bases (L1, L2 and L3) have been newly synthesized and characterized by IR, (1)H NMR, mass spectrometry and elemental analysis. n,n"-dipyridoxyl schiff bases 6-35 L1 cell adhesion molecule Homo sapiens 37-50 21848292-2 2011 Two new bioinspired coumarin probes (L1 and L2) were synthesized and fully characterized by elemental analysis, infrared, (1)H NMR, (13)C NMR, UV-vis absorption and emission spectroscopy, matrix-assisted laser desorption-ionization time-of-flight mass spectrometry (MALDI-TOF-MS), lifetime measurements, and X-ray crystal diffraction. coumarin 20-28 L1 cell adhesion molecule Homo sapiens 37-46 21097529-5 2011 We further present evidence that L1-CAM was involved in the resistance against therapeutic reagents like rapamycin, sunitinib and cisplatin. Sirolimus 105-114 L1 cell adhesion molecule Homo sapiens 33-39 21097529-5 2011 We further present evidence that L1-CAM was involved in the resistance against therapeutic reagents like rapamycin, sunitinib and cisplatin. Sunitinib 116-125 L1 cell adhesion molecule Homo sapiens 33-39 21097529-5 2011 We further present evidence that L1-CAM was involved in the resistance against therapeutic reagents like rapamycin, sunitinib and cisplatin. Cisplatin 130-139 L1 cell adhesion molecule Homo sapiens 33-39 22023352-7 2011 We use MAPS to illustrate in silico the propagation of a local perturbation over medium- to long-range distances across a disulfide bridge linking loops L1 and L2, which constitute the binding interface of BPTI. Disulfides 122-131 L1 cell adhesion molecule Homo sapiens 153-162 21395909-8 2011 CONCLUSIONS & INFERENCES: We have identified the X-linked gene, L1cam, as the first modifier gene for members of the endothelin signalling pathway during development of the enteric nervous system. Adenosine Monophosphate 13-16 L1 cell adhesion molecule Homo sapiens 68-73 21811711-2 2011 The outstanding UV-Vis absorption properties of the 1-aminoanthraquinone chromophore allowed the efficient visual detection and quantification of copper(II) ions by chelators L(1)-L(3) in buffered aqueous solution. 1-aminoanthraquinone 52-72 L1 cell adhesion molecule Homo sapiens 175-179 21811711-2 2011 The outstanding UV-Vis absorption properties of the 1-aminoanthraquinone chromophore allowed the efficient visual detection and quantification of copper(II) ions by chelators L(1)-L(3) in buffered aqueous solution. cupric ion 146-156 L1 cell adhesion molecule Homo sapiens 175-179 21545744-4 2011 We tested the effect of different reverse transcriptase inhibitors on L1 RT and found that all four tested nucleoside inhibitors efficiently inhibited L1 RT activity competitively. Nucleosides 107-117 L1 cell adhesion molecule Homo sapiens 70-72 21545744-4 2011 We tested the effect of different reverse transcriptase inhibitors on L1 RT and found that all four tested nucleoside inhibitors efficiently inhibited L1 RT activity competitively. Nucleosides 107-117 L1 cell adhesion molecule Homo sapiens 151-153 21545744-6 2011 L1 RT was less sensitive to non-nucleoside reverse transcriptase inhibitors, among these nevirapine had no effect, even at concentrations up to 500 muM. Nevirapine 89-99 L1 cell adhesion molecule Homo sapiens 0-2 21335065-0 2011 L1 cell adhesion molecule promotes resistance to alcohol-induced silencing of growth cone responses to guidance cues. Alcohols 49-56 L1 cell adhesion molecule Homo sapiens 0-25 21335065-5 2011 However, this effect is highly dependent on substrate; axonal growth cones extending on an L1 cell adhesion molecule (L1CAM) substrate retain responsiveness to cues following exposure to ethanol, while those growing on poly-L-lysine or N-cadherin do not. Ethanol 187-194 L1 cell adhesion molecule Homo sapiens 91-116 21335065-5 2011 However, this effect is highly dependent on substrate; axonal growth cones extending on an L1 cell adhesion molecule (L1CAM) substrate retain responsiveness to cues following exposure to ethanol, while those growing on poly-L-lysine or N-cadherin do not. Ethanol 187-194 L1 cell adhesion molecule Homo sapiens 118-123 21335065-7 2011 Quantitative assessments of the effects of ethanol on the surface distribution of L1CAM in growth cones suggest that L1CAM homophilic interactions may be particularly relevant for retaining growth cone responsiveness following ethanol exposure. Ethanol 43-50 L1 cell adhesion molecule Homo sapiens 82-87 21335065-7 2011 Quantitative assessments of the effects of ethanol on the surface distribution of L1CAM in growth cones suggest that L1CAM homophilic interactions may be particularly relevant for retaining growth cone responsiveness following ethanol exposure. Ethanol 43-50 L1 cell adhesion molecule Homo sapiens 117-122 21335065-7 2011 Quantitative assessments of the effects of ethanol on the surface distribution of L1CAM in growth cones suggest that L1CAM homophilic interactions may be particularly relevant for retaining growth cone responsiveness following ethanol exposure. Ethanol 227-234 L1 cell adhesion molecule Homo sapiens 82-87 21335065-7 2011 Quantitative assessments of the effects of ethanol on the surface distribution of L1CAM in growth cones suggest that L1CAM homophilic interactions may be particularly relevant for retaining growth cone responsiveness following ethanol exposure. Ethanol 227-234 L1 cell adhesion molecule Homo sapiens 117-122 21391575-7 2011 In the case of L1 and L2, this gives rise to complexes with silver at low concentration, enhancing the signals observed, while for the tricarbonylbromorhenium complexes of these ligands, the presence of the disulfide tether allows an enhancement in the limits of detection of these surface-borne species of 20 times in the case of [ReL2(CO)(3)Br] over [Re(bipy)(CO)(3)Br]. Silver 60-66 L1 cell adhesion molecule Homo sapiens 15-24 21391575-7 2011 In the case of L1 and L2, this gives rise to complexes with silver at low concentration, enhancing the signals observed, while for the tricarbonylbromorhenium complexes of these ligands, the presence of the disulfide tether allows an enhancement in the limits of detection of these surface-borne species of 20 times in the case of [ReL2(CO)(3)Br] over [Re(bipy)(CO)(3)Br]. tricarbonylbromorhenium 135-158 L1 cell adhesion molecule Homo sapiens 15-24 21391575-7 2011 In the case of L1 and L2, this gives rise to complexes with silver at low concentration, enhancing the signals observed, while for the tricarbonylbromorhenium complexes of these ligands, the presence of the disulfide tether allows an enhancement in the limits of detection of these surface-borne species of 20 times in the case of [ReL2(CO)(3)Br] over [Re(bipy)(CO)(3)Br]. Disulfides 207-216 L1 cell adhesion molecule Homo sapiens 15-24 21391575-7 2011 In the case of L1 and L2, this gives rise to complexes with silver at low concentration, enhancing the signals observed, while for the tricarbonylbromorhenium complexes of these ligands, the presence of the disulfide tether allows an enhancement in the limits of detection of these surface-borne species of 20 times in the case of [ReL2(CO)(3)Br] over [Re(bipy)(CO)(3)Br]. rel2(co)(3)br 332-345 L1 cell adhesion molecule Homo sapiens 15-24 21391575-7 2011 In the case of L1 and L2, this gives rise to complexes with silver at low concentration, enhancing the signals observed, while for the tricarbonylbromorhenium complexes of these ligands, the presence of the disulfide tether allows an enhancement in the limits of detection of these surface-borne species of 20 times in the case of [ReL2(CO)(3)Br] over [Re(bipy)(CO)(3)Br]. (bipy) 355-361 L1 cell adhesion molecule Homo sapiens 15-24 21391575-7 2011 In the case of L1 and L2, this gives rise to complexes with silver at low concentration, enhancing the signals observed, while for the tricarbonylbromorhenium complexes of these ligands, the presence of the disulfide tether allows an enhancement in the limits of detection of these surface-borne species of 20 times in the case of [ReL2(CO)(3)Br] over [Re(bipy)(CO)(3)Br]. co)(3)br 337-345 L1 cell adhesion molecule Homo sapiens 15-24 21130460-8 2011 Cashmeran, Pantolide and Tonalide were also detected in all the matrices with values up to 94 ng L-1, 26 ng L-1 and 88 ng L-1, respectively. pantolide 11-20 L1 cell adhesion molecule Homo sapiens 108-125 21130460-8 2011 Cashmeran, Pantolide and Tonalide were also detected in all the matrices with values up to 94 ng L-1, 26 ng L-1 and 88 ng L-1, respectively. acetyl methyl tetramethyl tetralin 25-33 L1 cell adhesion molecule Homo sapiens 108-125 20617848-3 2010 The engineered hybrid (GlnRS S1/L1/L2) synthesizes Glu-tRNA(Gln) more than 10(4)-fold more efficiently than GlnRS. glu-trna 51-59 L1 cell adhesion molecule Homo sapiens 32-37 21077627-2 2010 The triureas (L(1), L(2)) show stronger binding of sulfate than tetraureas (L(3), L(4)) in DMSO because of their better conformational complementarity with sulfate, while the tetraureas display better "water tolerance" benefiting from the chelate effect and hydrophobic effect. Sulfates 51-58 L1 cell adhesion molecule Homo sapiens 14-18 21077627-2 2010 The triureas (L(1), L(2)) show stronger binding of sulfate than tetraureas (L(3), L(4)) in DMSO because of their better conformational complementarity with sulfate, while the tetraureas display better "water tolerance" benefiting from the chelate effect and hydrophobic effect. Dimethyl Sulfoxide 91-95 L1 cell adhesion molecule Homo sapiens 14-18 21077627-2 2010 The triureas (L(1), L(2)) show stronger binding of sulfate than tetraureas (L(3), L(4)) in DMSO because of their better conformational complementarity with sulfate, while the tetraureas display better "water tolerance" benefiting from the chelate effect and hydrophobic effect. Sulfates 156-163 L1 cell adhesion molecule Homo sapiens 14-18 21077627-2 2010 The triureas (L(1), L(2)) show stronger binding of sulfate than tetraureas (L(3), L(4)) in DMSO because of their better conformational complementarity with sulfate, while the tetraureas display better "water tolerance" benefiting from the chelate effect and hydrophobic effect. Water 202-207 L1 cell adhesion molecule Homo sapiens 14-18 20377232-2 2010 Single crystal X-ray structures of [(L(1))Re(CO)(3)Cl] and [(L(4))Re(CO)(3)Cl] show the bipyridyl component of the cyclotriphosphazene substituted ligands is bound to the Re(I) giving a distorted octahedral "N(2)C(3)Cl" coordination sphere in both cases. co)(3)cl 45-53 L1 cell adhesion molecule Homo sapiens 37-41 20377232-2 2010 Single crystal X-ray structures of [(L(1))Re(CO)(3)Cl] and [(L(4))Re(CO)(3)Cl] show the bipyridyl component of the cyclotriphosphazene substituted ligands is bound to the Re(I) giving a distorted octahedral "N(2)C(3)Cl" coordination sphere in both cases. cyclotriphosphazene ester 115-134 L1 cell adhesion molecule Homo sapiens 37-41 20377232-2 2010 Single crystal X-ray structures of [(L(1))Re(CO)(3)Cl] and [(L(4))Re(CO)(3)Cl] show the bipyridyl component of the cyclotriphosphazene substituted ligands is bound to the Re(I) giving a distorted octahedral "N(2)C(3)Cl" coordination sphere in both cases. (3)cl 48-53 L1 cell adhesion molecule Homo sapiens 37-41 21072342-2 2010 Both H(3)L1 and H(3)L2 were used to prepare indium(III) complexes aiming at their evaluation as radioactive probes for in vivo targeting of EGFR-TK. indium(iii) 44-55 L1 cell adhesion molecule Homo sapiens 9-22 20617848-3 2010 The engineered hybrid (GlnRS S1/L1/L2) synthesizes Glu-tRNA(Gln) more than 10(4)-fold more efficiently than GlnRS. Glutamine 23-26 L1 cell adhesion molecule Homo sapiens 32-37 20617848-4 2010 Detailed comparison of kinetic parameters between GlnRS S1/L1/L2 and the naturally occurring Methanothermobacter thermautotrophicus GluRS(ND), which is also capable of Glu-tRNA(Gln) synthesis, now shows that both k(cat) and K(m) for glutamate are recapitulated in the engineered enzyme, but that K(m) for tRNA is 200-fold higher. Glutamic Acid 233-242 L1 cell adhesion molecule Homo sapiens 59-64 19685344-4 2010 Sequencing of the L1CAM gene showed a novel missense mutation in exon 14: transition of a guanine to cytosine at position 1777 (c.1777G>C), which led to an amino acid change of alanine to proline at position 593 (Ala593Pro) in the sixth immunoglobulin domain of the L1 protein. Guanine 90-97 L1 cell adhesion molecule Homo sapiens 18-23 19685344-4 2010 Sequencing of the L1CAM gene showed a novel missense mutation in exon 14: transition of a guanine to cytosine at position 1777 (c.1777G>C), which led to an amino acid change of alanine to proline at position 593 (Ala593Pro) in the sixth immunoglobulin domain of the L1 protein. Cytosine 101-109 L1 cell adhesion molecule Homo sapiens 18-23 20131803-2 2010 The acyclic tetraoxime ligand H(4)L(1) having two terminal allyl groups was synthesized. tetraoxime 12-22 L1 cell adhesion molecule Homo sapiens 34-38 20131803-3 2010 The olefin metathesis of H(4)L(1) selectively produced trans-H(4)L(2) while the reaction of [L(1)Zn(2)Ca] exclusively afforded cis-H(4)L(2). Alkenes 4-10 L1 cell adhesion molecule Homo sapiens 29-33 20131803-5 2010 The complexation of the ligands H(4)L (L = L(1), trans-L(2), cis-L(2), L(3)) with zinc(II) acetate (3 equiv) yielded the trinuclear complexes [LZn(3)] with a similar trinuclear core bridged by acetato ligands. Zinc Acetate 82-98 L1 cell adhesion molecule Homo sapiens 43-47 20131803-7 2010 The trinuclear complexes [LZn(3)] (L = L(1), trans-L(2), cis-L(2), L(3)) can recognize alkaline earth metal ions via site-selective metal exchange. Metals 102-107 L1 cell adhesion molecule Homo sapiens 39-43 20131803-7 2010 The trinuclear complexes [LZn(3)] (L = L(1), trans-L(2), cis-L(2), L(3)) can recognize alkaline earth metal ions via site-selective metal exchange. Metals 132-137 L1 cell adhesion molecule Homo sapiens 39-43 20131803-9 2010 The metal exchange of [LZn(3)] (L = L(1), trans-L(2), cis-L(2), L(3)) with La(3+) efficiently occurred to give [LZn(2)La], but the trans-olefin linker of the [trans-L(2)Zn(2)La] significantly deforms the structure in such a way that one of the salicylaldoxime moieties does not participate in the coordination. Metals 4-9 L1 cell adhesion molecule Homo sapiens 36-40 20131803-9 2010 The metal exchange of [LZn(3)] (L = L(1), trans-L(2), cis-L(2), L(3)) with La(3+) efficiently occurred to give [LZn(2)La], but the trans-olefin linker of the [trans-L(2)Zn(2)La] significantly deforms the structure in such a way that one of the salicylaldoxime moieties does not participate in the coordination. lzn 23-26 L1 cell adhesion molecule Homo sapiens 36-40 20124415-3 2010 pGal-3 interacts with neural cell adhesion molecule L1, and enhances L1 association with Thy-1-rich membrane microdomains. pgal-3 0-6 L1 cell adhesion molecule Homo sapiens 22-54 19865098-8 2010 It is important that knockdown of cellular L1-CAM reduced the migration of melanoma cells and abrogated the chemoresistance against cisplatin. Cisplatin 132-141 L1 cell adhesion molecule Homo sapiens 43-49 19780566-2 2009 The crystal structure determinations of 1 and 2 reveal in both cases discrete iron(II) monomeric structures in which the two functionalized tetraazamacrocycles (L1 and L2) act as hexadentate ligands; the iron(II) ions are coordinated with six nitrogen atoms: four from the macrocycle and two from two pyridine groups occupying two cis positions around the metal ion. ammonium ferrous sulfate 78-86 L1 cell adhesion molecule Homo sapiens 161-170 19780566-2 2009 The crystal structure determinations of 1 and 2 reveal in both cases discrete iron(II) monomeric structures in which the two functionalized tetraazamacrocycles (L1 and L2) act as hexadentate ligands; the iron(II) ions are coordinated with six nitrogen atoms: four from the macrocycle and two from two pyridine groups occupying two cis positions around the metal ion. tetraazamacrocycles 140-159 L1 cell adhesion molecule Homo sapiens 161-170 19780566-2 2009 The crystal structure determinations of 1 and 2 reveal in both cases discrete iron(II) monomeric structures in which the two functionalized tetraazamacrocycles (L1 and L2) act as hexadentate ligands; the iron(II) ions are coordinated with six nitrogen atoms: four from the macrocycle and two from two pyridine groups occupying two cis positions around the metal ion. ammonium ferrous sulfate 204-212 L1 cell adhesion molecule Homo sapiens 161-170 19780566-2 2009 The crystal structure determinations of 1 and 2 reveal in both cases discrete iron(II) monomeric structures in which the two functionalized tetraazamacrocycles (L1 and L2) act as hexadentate ligands; the iron(II) ions are coordinated with six nitrogen atoms: four from the macrocycle and two from two pyridine groups occupying two cis positions around the metal ion. Nitrogen 243-251 L1 cell adhesion molecule Homo sapiens 161-170 19780566-2 2009 The crystal structure determinations of 1 and 2 reveal in both cases discrete iron(II) monomeric structures in which the two functionalized tetraazamacrocycles (L1 and L2) act as hexadentate ligands; the iron(II) ions are coordinated with six nitrogen atoms: four from the macrocycle and two from two pyridine groups occupying two cis positions around the metal ion. pyridine 301-309 L1 cell adhesion molecule Homo sapiens 161-170 19780566-2 2009 The crystal structure determinations of 1 and 2 reveal in both cases discrete iron(II) monomeric structures in which the two functionalized tetraazamacrocycles (L1 and L2) act as hexadentate ligands; the iron(II) ions are coordinated with six nitrogen atoms: four from the macrocycle and two from two pyridine groups occupying two cis positions around the metal ion. Metals 356-361 L1 cell adhesion molecule Homo sapiens 161-170 18926887-1 2008 Humans exposed prenatally to ethanol can exhibit brain abnormalities and cognitive impairment similar to those seen in patients expressing mutant forms of the L1 cell adhesion molecule (L1CAM). Ethanol 29-36 L1 cell adhesion molecule Homo sapiens 159-184 19812847-3 2009 The hydrocarbons CH3, CH4, C2H2, C2H4, and C2H6 were observed as prominent pyrolysis products in all three systems, and amongst the weaker features are bands arising from the methylsilanes Me2SiH2 (for L1 and L2) and Me3SiH (for L3). methylsilanes me2sih2 175-196 L1 cell adhesion molecule Homo sapiens 202-211 19743804-2 2009 The protonation features of L1 and of receptor 2,6,10,14,18,22-hexaaza[23]-24,37-phenanthrolinophane (L2) have been studied by means of potentiometric, (1)H NMR, and spectrofluorimetric measurements; this study points out that the fluorescent emission of both receptors depends on the protonation state of the polyamine chain. hexaaza 63-70 L1 cell adhesion molecule Homo sapiens 28-48 19743804-2 2009 The protonation features of L1 and of receptor 2,6,10,14,18,22-hexaaza[23]-24,37-phenanthrolinophane (L2) have been studied by means of potentiometric, (1)H NMR, and spectrofluorimetric measurements; this study points out that the fluorescent emission of both receptors depends on the protonation state of the polyamine chain. phenanthrolinophane 81-100 L1 cell adhesion molecule Homo sapiens 28-48 19743804-2 2009 The protonation features of L1 and of receptor 2,6,10,14,18,22-hexaaza[23]-24,37-phenanthrolinophane (L2) have been studied by means of potentiometric, (1)H NMR, and spectrofluorimetric measurements; this study points out that the fluorescent emission of both receptors depends on the protonation state of the polyamine chain. Threonine 102-104 L1 cell adhesion molecule Homo sapiens 28-48 19743804-2 2009 The protonation features of L1 and of receptor 2,6,10,14,18,22-hexaaza[23]-24,37-phenanthrolinophane (L2) have been studied by means of potentiometric, (1)H NMR, and spectrofluorimetric measurements; this study points out that the fluorescent emission of both receptors depends on the protonation state of the polyamine chain. Polyamines 310-319 L1 cell adhesion molecule Homo sapiens 28-48 19639167-5 2009 Bisulfite-modified genome sequencing suggested that DNA methylation status at core promoter and putative TCF-binding sites within the L1CAM promoter was correlated with L1CAM mRNA/protein expression in 4 CRC cell lines. hydrogen sulfite 0-9 L1 cell adhesion molecule Homo sapiens 134-139 19639167-5 2009 Bisulfite-modified genome sequencing suggested that DNA methylation status at core promoter and putative TCF-binding sites within the L1CAM promoter was correlated with L1CAM mRNA/protein expression in 4 CRC cell lines. hydrogen sulfite 0-9 L1 cell adhesion molecule Homo sapiens 169-174 19565090-3 2009 L(1) is the Schiff-base derived from the condensation of alpha,alpha"-diamino-m-xylene and pyridine-2-carboxaldehyde and L(4) that resulting from the reaction of 2-(4-aminophenyl)ethylamine with 6-methyl-pyridine-2-carboxaldehyde, while L(2) and L(5) are the reduced N-methyl derivatives. Schiff Bases 12-23 L1 cell adhesion molecule Homo sapiens 0-4 19565090-3 2009 L(1) is the Schiff-base derived from the condensation of alpha,alpha"-diamino-m-xylene and pyridine-2-carboxaldehyde and L(4) that resulting from the reaction of 2-(4-aminophenyl)ethylamine with 6-methyl-pyridine-2-carboxaldehyde, while L(2) and L(5) are the reduced N-methyl derivatives. 1,3-xylenediamine 57-86 L1 cell adhesion molecule Homo sapiens 0-4 19565090-3 2009 L(1) is the Schiff-base derived from the condensation of alpha,alpha"-diamino-m-xylene and pyridine-2-carboxaldehyde and L(4) that resulting from the reaction of 2-(4-aminophenyl)ethylamine with 6-methyl-pyridine-2-carboxaldehyde, while L(2) and L(5) are the reduced N-methyl derivatives. pyridine-2-carboxaldehyde 91-116 L1 cell adhesion molecule Homo sapiens 0-4 19565090-3 2009 L(1) is the Schiff-base derived from the condensation of alpha,alpha"-diamino-m-xylene and pyridine-2-carboxaldehyde and L(4) that resulting from the reaction of 2-(4-aminophenyl)ethylamine with 6-methyl-pyridine-2-carboxaldehyde, while L(2) and L(5) are the reduced N-methyl derivatives. 2-(4-aminophenyl)ethylamine 162-189 L1 cell adhesion molecule Homo sapiens 0-4 19236035-1 2009 Azo-coupled macrocyclic chromoionophores incorporating benzene (L(1)) and pyridine (L(2)) subunits were synthesized, respectively. Benzene 55-62 L1 cell adhesion molecule Homo sapiens 64-68 19236035-3 2009 However, L(1) gave a larger cation-induced hypsochromic shift than L(2), suggesting that the presence of the pyridine unit in L(2) may inhibit the Hg...N-azo interaction. pyridine 109-117 L1 cell adhesion molecule Homo sapiens 9-13 19236035-3 2009 However, L(1) gave a larger cation-induced hypsochromic shift than L(2), suggesting that the presence of the pyridine unit in L(2) may inhibit the Hg...N-azo interaction. n-azo 152-157 L1 cell adhesion molecule Homo sapiens 9-13 19565090-3 2009 L(1) is the Schiff-base derived from the condensation of alpha,alpha"-diamino-m-xylene and pyridine-2-carboxaldehyde and L(4) that resulting from the reaction of 2-(4-aminophenyl)ethylamine with 6-methyl-pyridine-2-carboxaldehyde, while L(2) and L(5) are the reduced N-methyl derivatives. 6-methylpyridine-2-carboxaldehyde 195-229 L1 cell adhesion molecule Homo sapiens 0-4 19343000-6 2009 Estrogen regulated genes GDF15 and L1CAM became regulated by toremifene in the later passage number of toremifene-resistant cells, which might be an indication of the developed estrogen-agonistic activity of toremifene in these cells. Toremifene 61-71 L1 cell adhesion molecule Homo sapiens 35-40 19343000-6 2009 Estrogen regulated genes GDF15 and L1CAM became regulated by toremifene in the later passage number of toremifene-resistant cells, which might be an indication of the developed estrogen-agonistic activity of toremifene in these cells. Toremifene 103-113 L1 cell adhesion molecule Homo sapiens 35-40 19343000-6 2009 Estrogen regulated genes GDF15 and L1CAM became regulated by toremifene in the later passage number of toremifene-resistant cells, which might be an indication of the developed estrogen-agonistic activity of toremifene in these cells. Toremifene 103-113 L1 cell adhesion molecule Homo sapiens 35-40 18534903-6 2008 The ligands (L1", L2" and L3") formed by tribochemical reactions are quite similar to these of L1, L2 and L3, except that the ionizable chloride ions in case of L1, L2 and L3 are substituted by iodide ions in (L1", L2" and L3"). Chlorides 136-144 L1 cell adhesion molecule Homo sapiens 95-108 18534903-6 2008 The ligands (L1", L2" and L3") formed by tribochemical reactions are quite similar to these of L1, L2 and L3, except that the ionizable chloride ions in case of L1, L2 and L3 are substituted by iodide ions in (L1", L2" and L3"). Chlorides 136-144 L1 cell adhesion molecule Homo sapiens 161-174 18534903-6 2008 The ligands (L1", L2" and L3") formed by tribochemical reactions are quite similar to these of L1, L2 and L3, except that the ionizable chloride ions in case of L1, L2 and L3 are substituted by iodide ions in (L1", L2" and L3"). Iodides 194-200 L1 cell adhesion molecule Homo sapiens 95-108 18534903-6 2008 The ligands (L1", L2" and L3") formed by tribochemical reactions are quite similar to these of L1, L2 and L3, except that the ionizable chloride ions in case of L1, L2 and L3 are substituted by iodide ions in (L1", L2" and L3"). Iodides 194-200 L1 cell adhesion molecule Homo sapiens 161-174 18926887-1 2008 Humans exposed prenatally to ethanol can exhibit brain abnormalities and cognitive impairment similar to those seen in patients expressing mutant forms of the L1 cell adhesion molecule (L1CAM). Ethanol 29-36 L1 cell adhesion molecule Homo sapiens 186-191 18688420-2 2008 In the "4 + 1" approach the technetium(iii) is stabilized by a monodentate isocyanide bearing a quinazoline fragment (L1,L2 ) and by the tetradentate tripodal ligand tris(2-mercaptoethyl)-amine (NS3). Cyanides 75-85 L1 cell adhesion molecule Homo sapiens 118-123 18537202-4 2008 Testing these agents against a variety of human cancer cell lines revealed that L(1) and [PtL(1)Cl2] were at least as active as cisplatin against several of the cell lines (including a cisplatin-resistant cell line). Cisplatin 185-194 L1 cell adhesion molecule Homo sapiens 80-84 18688420-2 2008 In the "4 + 1" approach the technetium(iii) is stabilized by a monodentate isocyanide bearing a quinazoline fragment (L1,L2 ) and by the tetradentate tripodal ligand tris(2-mercaptoethyl)-amine (NS3). Quinazolines 96-107 L1 cell adhesion molecule Homo sapiens 118-123 18206198-7 2008 Furthermore, strains L1 and L2, which did not show AZT-DNA incorporation at 24 h, did have measurable incorporation by 48 and 72 h. These data suggest that variability in AZT-DNA incorporation may be modulated by inter-individual differences in the rate of induction of TK1 in response to AZT exposure. Zidovudine 51-54 L1 cell adhesion molecule Homo sapiens 21-30 18206198-7 2008 Furthermore, strains L1 and L2, which did not show AZT-DNA incorporation at 24 h, did have measurable incorporation by 48 and 72 h. These data suggest that variability in AZT-DNA incorporation may be modulated by inter-individual differences in the rate of induction of TK1 in response to AZT exposure. Zidovudine 171-174 L1 cell adhesion molecule Homo sapiens 21-30 18206198-7 2008 Furthermore, strains L1 and L2, which did not show AZT-DNA incorporation at 24 h, did have measurable incorporation by 48 and 72 h. These data suggest that variability in AZT-DNA incorporation may be modulated by inter-individual differences in the rate of induction of TK1 in response to AZT exposure. Zidovudine 171-174 L1 cell adhesion molecule Homo sapiens 21-30 18165316-0 2008 An alcohol binding site on the neural cell adhesion molecule L1. Alcohols 3-10 L1 cell adhesion molecule Homo sapiens 31-63 18165316-1 2008 Prenatal ethanol exposure causes fetal alcohol spectrum disorders (FASD) in part by disrupting the neural cell adhesion molecule L1. Ethanol 9-16 L1 cell adhesion molecule Homo sapiens 99-131 18165316-1 2008 Prenatal ethanol exposure causes fetal alcohol spectrum disorders (FASD) in part by disrupting the neural cell adhesion molecule L1. Alcohols 39-46 L1 cell adhesion molecule Homo sapiens 99-131 18165316-3 2008 Ethanol and 1-butanol inhibit L1-mediated cell-cell adhesion (L1 adhesion), whereas 1-octanol antagonizes this action. Ethanol 0-7 L1 cell adhesion molecule Homo sapiens 30-32 18165316-3 2008 Ethanol and 1-butanol inhibit L1-mediated cell-cell adhesion (L1 adhesion), whereas 1-octanol antagonizes this action. Ethanol 0-7 L1 cell adhesion molecule Homo sapiens 62-64 18165316-3 2008 Ethanol and 1-butanol inhibit L1-mediated cell-cell adhesion (L1 adhesion), whereas 1-octanol antagonizes this action. 1-Butanol 12-21 L1 cell adhesion molecule Homo sapiens 30-32 18165316-3 2008 Ethanol and 1-butanol inhibit L1-mediated cell-cell adhesion (L1 adhesion), whereas 1-octanol antagonizes this action. 1-Butanol 12-21 L1 cell adhesion molecule Homo sapiens 62-64 18165316-4 2008 To test the hypothesis that there are alcohol binding sites on L1, we used 3-azibutanol and 3-azioctanol, the photoactivatable analogs of 1-butanol and 1-octanol, to photolabel the purified Ig1-4 domain of human L1 (hL1 Ig1-4). Alcohols 38-45 L1 cell adhesion molecule Homo sapiens 63-65 18165316-4 2008 To test the hypothesis that there are alcohol binding sites on L1, we used 3-azibutanol and 3-azioctanol, the photoactivatable analogs of 1-butanol and 1-octanol, to photolabel the purified Ig1-4 domain of human L1 (hL1 Ig1-4). 3-azibutanol 75-87 L1 cell adhesion molecule Homo sapiens 63-65 18165316-4 2008 To test the hypothesis that there are alcohol binding sites on L1, we used 3-azibutanol and 3-azioctanol, the photoactivatable analogs of 1-butanol and 1-octanol, to photolabel the purified Ig1-4 domain of human L1 (hL1 Ig1-4). 3-azioctanol 92-104 L1 cell adhesion molecule Homo sapiens 63-65 18165316-5 2008 3-Azibutanol (11 mM), like ethanol, inhibited L1 adhesion in NIH/3T3 cells stably transfected with hL1, whereas subanesthetic concentrations of 3-azioctanol (14 microM) antagonized ethanol inhibition of L1 adhesion. 3-azibutanol 0-12 L1 cell adhesion molecule Homo sapiens 46-48 18165316-5 2008 3-Azibutanol (11 mM), like ethanol, inhibited L1 adhesion in NIH/3T3 cells stably transfected with hL1, whereas subanesthetic concentrations of 3-azioctanol (14 microM) antagonized ethanol inhibition of L1 adhesion. 3-azibutanol 0-12 L1 cell adhesion molecule Homo sapiens 99-102 18165316-5 2008 3-Azibutanol (11 mM), like ethanol, inhibited L1 adhesion in NIH/3T3 cells stably transfected with hL1, whereas subanesthetic concentrations of 3-azioctanol (14 microM) antagonized ethanol inhibition of L1 adhesion. 3-azibutanol 0-12 L1 cell adhesion molecule Homo sapiens 100-102 18165316-5 2008 3-Azibutanol (11 mM), like ethanol, inhibited L1 adhesion in NIH/3T3 cells stably transfected with hL1, whereas subanesthetic concentrations of 3-azioctanol (14 microM) antagonized ethanol inhibition of L1 adhesion. Ethanol 27-34 L1 cell adhesion molecule Homo sapiens 46-48 18165316-7 2008 A homology model of hL1 Ig1-4 (residues 33-422), based on the structure of the Ig1-4 domains of axonin-1, suggests that Glu-33 and Tyr-418 hydrogen-bond at the interface of Ig1 and Ig4 to stabilize a horseshoe conformation of L1 that favors homophilic binding. Glutamic Acid 120-123 L1 cell adhesion molecule Homo sapiens 20-23 18165316-7 2008 A homology model of hL1 Ig1-4 (residues 33-422), based on the structure of the Ig1-4 domains of axonin-1, suggests that Glu-33 and Tyr-418 hydrogen-bond at the interface of Ig1 and Ig4 to stabilize a horseshoe conformation of L1 that favors homophilic binding. Glutamic Acid 120-123 L1 cell adhesion molecule Homo sapiens 21-23 18165316-7 2008 A homology model of hL1 Ig1-4 (residues 33-422), based on the structure of the Ig1-4 domains of axonin-1, suggests that Glu-33 and Tyr-418 hydrogen-bond at the interface of Ig1 and Ig4 to stabilize a horseshoe conformation of L1 that favors homophilic binding. Tyrosine 131-134 L1 cell adhesion molecule Homo sapiens 20-23 18165316-7 2008 A homology model of hL1 Ig1-4 (residues 33-422), based on the structure of the Ig1-4 domains of axonin-1, suggests that Glu-33 and Tyr-418 hydrogen-bond at the interface of Ig1 and Ig4 to stabilize a horseshoe conformation of L1 that favors homophilic binding. Tyrosine 131-134 L1 cell adhesion molecule Homo sapiens 21-23 18165316-7 2008 A homology model of hL1 Ig1-4 (residues 33-422), based on the structure of the Ig1-4 domains of axonin-1, suggests that Glu-33 and Tyr-418 hydrogen-bond at the interface of Ig1 and Ig4 to stabilize a horseshoe conformation of L1 that favors homophilic binding. Hydrogen 139-147 L1 cell adhesion molecule Homo sapiens 20-23 18165316-7 2008 A homology model of hL1 Ig1-4 (residues 33-422), based on the structure of the Ig1-4 domains of axonin-1, suggests that Glu-33 and Tyr-418 hydrogen-bond at the interface of Ig1 and Ig4 to stabilize a horseshoe conformation of L1 that favors homophilic binding. Hydrogen 139-147 L1 cell adhesion molecule Homo sapiens 21-23 18165316-10 2008 Characterization of alcohol agonist and antagonist binding sites on L1 will aid in understanding the molecular basis for FASD and might accelerate the development of ethanol antagonists. Alcohols 20-27 L1 cell adhesion molecule Homo sapiens 68-70 18165316-10 2008 Characterization of alcohol agonist and antagonist binding sites on L1 will aid in understanding the molecular basis for FASD and might accelerate the development of ethanol antagonists. Ethanol 166-173 L1 cell adhesion molecule Homo sapiens 68-70 17988081-3 2008 For proof of concept, different IgG1s (commercial bovine IgG1, and L1CAM targeting chCE7 and chCE7 aglycosylated) were enzymatically functionalization with different fluorescent TGase substrates based on the CY3 analogue Dy547. cy3 208-211 L1 cell adhesion molecule Homo sapiens 67-72 17324612-1 2007 N,N"-Bis(4-ferrocenyl)-p-phenylene/octamethylene-diimines (L1/L2) and a representative Ru(II) complex [Ru(DMSO)2Cl2L1].2H2O were prepared and characterized which showed many fold enhancement in their luminescence in alkaline dimethylsulfoxide (DMSO) solution. n,n"-bis(4-ferrocenyl)-p-phenylene/octamethylene-diimines 0-57 L1 cell adhesion molecule Homo sapiens 59-64 28903292-2 2007 Here we report on a sensorarray that extends the concept of an "electronic tongue" to detect small amounts ofbromoform, bromodichloromethane and dibromochloromethane, with detection limits aslow as 0.02 mg L-1. bromodichloromethane 120-140 L1 cell adhesion molecule Homo sapiens 206-209 28903292-2 2007 Here we report on a sensorarray that extends the concept of an "electronic tongue" to detect small amounts ofbromoform, bromodichloromethane and dibromochloromethane, with detection limits aslow as 0.02 mg L-1. chlorodibromomethane 145-165 L1 cell adhesion molecule Homo sapiens 206-209 17900183-2 2007 Complexes [EuL(1-3)] incorporate N10-CH2CONH-BP linkers (BP = benzophenone), which allow formation of a five-membered chelate ring containing the metal ion upon chelation of the amide oxygen; these three isomeric complexes differ from one another in the substitution position of the BP unit, namely para, meta, and ortho for L1, L2, and L3 respectively. n10-ch2conh 33-44 L1 cell adhesion molecule Homo sapiens 325-339 17900183-2 2007 Complexes [EuL(1-3)] incorporate N10-CH2CONH-BP linkers (BP = benzophenone), which allow formation of a five-membered chelate ring containing the metal ion upon chelation of the amide oxygen; these three isomeric complexes differ from one another in the substitution position of the BP unit, namely para, meta, and ortho for L1, L2, and L3 respectively. Benzo(a)pyrene 45-47 L1 cell adhesion molecule Homo sapiens 325-339 17900183-2 2007 Complexes [EuL(1-3)] incorporate N10-CH2CONH-BP linkers (BP = benzophenone), which allow formation of a five-membered chelate ring containing the metal ion upon chelation of the amide oxygen; these three isomeric complexes differ from one another in the substitution position of the BP unit, namely para, meta, and ortho for L1, L2, and L3 respectively. Metals 146-151 L1 cell adhesion molecule Homo sapiens 325-339 17325775-2 2007 Ligand L(1) (p-phenylene spacer) forms complexes with a 2:3 M:L ratio according to the proportions used in the reaction mixture; the Ln(2)(L(1))(3) complexes contain two 9-coordinate Ln(III) centres with all three bridging ligands spanning both metal ions, and have a cylindrical (non-helical) "mesocate" architecture. Metals 245-250 L1 cell adhesion molecule Homo sapiens 7-11 17086212-5 2007 PT45-P1res cells subjected to short interfering RNA (siRNA)-mediated L1CAM knock-down exhibited reduced inducible nitric oxide synthase expression and NO secretion, as well as a significant increase of anti-cancer drug-induced caspase activation, an effect reversed by the NO donor S-nitroso-N-acetyl-D,L-penicillamine. snap 282-318 L1 cell adhesion molecule Homo sapiens 69-74 17372647-1 2007 New dioxadiaza- and trioxadiaza-macrocycles containing one rigid dibenzofuran unit (DBF) and N-(2-aminoethyl) pendant arms were synthesized, N,N"-bis(2-aminoethyl)-[17](DBF)N(2)O(2) (L(1)) and N,N"-bis(2-aminoethyl)-[22](DBF)N(2)O(3) (L(2)), respectively. dioxadiaza- and trioxadiaza-macrocycles 4-43 L1 cell adhesion molecule Homo sapiens 183-187 17372647-6 2007 On the other hand, the binding affinities of Cd(2+) and Pb(2+) for L(1) are very high, when compared to those of Co(2+), Ni(2+) and Zn(2+). Cadmium 45-47 L1 cell adhesion molecule Homo sapiens 67-71 17372647-6 2007 On the other hand, the binding affinities of Cd(2+) and Pb(2+) for L(1) are very high, when compared to those of Co(2+), Ni(2+) and Zn(2+). Lead 56-58 L1 cell adhesion molecule Homo sapiens 67-71 17372647-6 2007 On the other hand, the binding affinities of Cd(2+) and Pb(2+) for L(1) are very high, when compared to those of Co(2+), Ni(2+) and Zn(2+). Cobalt(2+) 113-119 L1 cell adhesion molecule Homo sapiens 67-71 17372647-10 2007 The crystal structure of the copper complex of L(1) was also determined. Copper 29-35 L1 cell adhesion molecule Homo sapiens 47-51 17325775-2 2007 Ligand L(1) (p-phenylene spacer) forms complexes with a 2:3 M:L ratio according to the proportions used in the reaction mixture; the Ln(2)(L(1))(3) complexes contain two 9-coordinate Ln(III) centres with all three bridging ligands spanning both metal ions, and have a cylindrical (non-helical) "mesocate" architecture. mesocate 295-303 L1 cell adhesion molecule Homo sapiens 7-11 17009386-1 2007 A series of six new ligands (L(1)-L(6)) suitable for the formation of luminescent lanthanide complexes in water is described. Lanthanoid Series Elements 82-92 L1 cell adhesion molecule Homo sapiens 29-33 17205268-18 2007 Me197Hg production from 197Hg2+ spiked in freshwater samples ranged from 0.1 to 0.3% over a period of three days with mercury additions of 10 ng L-1. me197hg 0-7 L1 cell adhesion molecule Homo sapiens 145-148 17215239-7 2007 After only 3 d incubation, the concentrations of SO4-S in aqueous leachates were 77, 122, 170, 220, and 229 mg L-1 for initial soil pH values of 7.8, 6.5, 5.5, 5.1, and 4.0, respectively. so4-s 49-54 L1 cell adhesion molecule Homo sapiens 111-114 17009386-2 2007 Ligands L(1)-L(4) are constructed from two 6"-carboxy-6-methylene-2,2"-bipyridine chromophoric arms bonded to the amino function of a 2-aminomethylene-6-carboxy-pyridine (L(1)), an N,N-diacetate-ethylene diamine (L(2)), a serine (L(3)), or an aminomalonic acid (L(4)). Serine 222-228 L1 cell adhesion molecule Homo sapiens 8-12 17009386-2 2007 Ligands L(1)-L(4) are constructed from two 6"-carboxy-6-methylene-2,2"-bipyridine chromophoric arms bonded to the amino function of a 2-aminomethylene-6-carboxy-pyridine (L(1)), an N,N-diacetate-ethylene diamine (L(2)), a serine (L(3)), or an aminomalonic acid (L(4)). aminomalonic acid 243-260 L1 cell adhesion molecule Homo sapiens 8-12 17009386-1 2007 A series of six new ligands (L(1)-L(6)) suitable for the formation of luminescent lanthanide complexes in water is described. Water 106-111 L1 cell adhesion molecule Homo sapiens 29-33 17009386-2 2007 Ligands L(1)-L(4) are constructed from two 6"-carboxy-6-methylene-2,2"-bipyridine chromophoric arms bonded to the amino function of a 2-aminomethylene-6-carboxy-pyridine (L(1)), an N,N-diacetate-ethylene diamine (L(2)), a serine (L(3)), or an aminomalonic acid (L(4)). 6'-carboxy-6-methylene-2,2'-bipyridine 43-81 L1 cell adhesion molecule Homo sapiens 8-12 17009386-2 2007 Ligands L(1)-L(4) are constructed from two 6"-carboxy-6-methylene-2,2"-bipyridine chromophoric arms bonded to the amino function of a 2-aminomethylene-6-carboxy-pyridine (L(1)), an N,N-diacetate-ethylene diamine (L(2)), a serine (L(3)), or an aminomalonic acid (L(4)). 2-aminomethylene-6-carboxy-pyridine 134-169 L1 cell adhesion molecule Homo sapiens 8-12 17009386-2 2007 Ligands L(1)-L(4) are constructed from two 6"-carboxy-6-methylene-2,2"-bipyridine chromophoric arms bonded to the amino function of a 2-aminomethylene-6-carboxy-pyridine (L(1)), an N,N-diacetate-ethylene diamine (L(2)), a serine (L(3)), or an aminomalonic acid (L(4)). 2-aminomethylene-6-carboxy-pyridine 134-169 L1 cell adhesion molecule Homo sapiens 171-175 17009386-2 2007 Ligands L(1)-L(4) are constructed from two 6"-carboxy-6-methylene-2,2"-bipyridine chromophoric arms bonded to the amino function of a 2-aminomethylene-6-carboxy-pyridine (L(1)), an N,N-diacetate-ethylene diamine (L(2)), a serine (L(3)), or an aminomalonic acid (L(4)). n,n-diacetate-ethylene diamine 181-211 L1 cell adhesion molecule Homo sapiens 8-12 16924290-2 2006 The protonation constants of L1 and L2 and the stability constants of their complexes with Ni2+, Cu2+, Zn2+ and Cd2+ metal ions were determined in aqueous solutions by potentiometry, at 298.2 K and ionic strength 0.10 mol dm(-3) in KNO3. Nickel(2+) 91-95 L1 cell adhesion molecule Homo sapiens 29-38 16924290-2 2006 The protonation constants of L1 and L2 and the stability constants of their complexes with Ni2+, Cu2+, Zn2+ and Cd2+ metal ions were determined in aqueous solutions by potentiometry, at 298.2 K and ionic strength 0.10 mol dm(-3) in KNO3. cupric ion 97-101 L1 cell adhesion molecule Homo sapiens 29-38 16924290-2 2006 The protonation constants of L1 and L2 and the stability constants of their complexes with Ni2+, Cu2+, Zn2+ and Cd2+ metal ions were determined in aqueous solutions by potentiometry, at 298.2 K and ionic strength 0.10 mol dm(-3) in KNO3. Zinc 103-107 L1 cell adhesion molecule Homo sapiens 29-38 16924290-2 2006 The protonation constants of L1 and L2 and the stability constants of their complexes with Ni2+, Cu2+, Zn2+ and Cd2+ metal ions were determined in aqueous solutions by potentiometry, at 298.2 K and ionic strength 0.10 mol dm(-3) in KNO3. Metals 117-122 L1 cell adhesion molecule Homo sapiens 29-38 16924290-2 2006 The protonation constants of L1 and L2 and the stability constants of their complexes with Ni2+, Cu2+, Zn2+ and Cd2+ metal ions were determined in aqueous solutions by potentiometry, at 298.2 K and ionic strength 0.10 mol dm(-3) in KNO3. dm 222-224 L1 cell adhesion molecule Homo sapiens 29-38 16924290-2 2006 The protonation constants of L1 and L2 and the stability constants of their complexes with Ni2+, Cu2+, Zn2+ and Cd2+ metal ions were determined in aqueous solutions by potentiometry, at 298.2 K and ionic strength 0.10 mol dm(-3) in KNO3. potassium nitrate 232-236 L1 cell adhesion molecule Homo sapiens 29-38 16293615-4 2006 Disruption of the L1-CAM-ankyrin B complex with the calcium channel mimics transmitter-induced trafficking of the channels, reduces calcium influx, and decreases exocytosis. Calcium 52-59 L1 cell adhesion molecule Homo sapiens 18-24 16574474-6 2006 The thermal behaviour of these chelates shows that the hydrated complexes losses water molecules of hydration in the first step followed immediately by decomposition of the coordinated water, anions and ligands (L1 and L2) in the subsequent steps. Water 81-86 L1 cell adhesion molecule Homo sapiens 212-221 16574474-6 2006 The thermal behaviour of these chelates shows that the hydrated complexes losses water molecules of hydration in the first step followed immediately by decomposition of the coordinated water, anions and ligands (L1 and L2) in the subsequent steps. Water 185-190 L1 cell adhesion molecule Homo sapiens 212-221 16471974-2 2006 The reactions between CuCl2, Cu(OAc)2, and CuSO4 and the two bipyridylurea ligands L1 and L2 [L1 = 1,3-bis(pyridin-4-ylmethyl)urea; L2 = 1,3-bis(pyridin-3-ylmethyl)urea; see Scheme 1 in paper] have been carried out and the crystal structure of five of the resulting metal-organic assemblies determined. cupric chloride 22-27 L1 cell adhesion molecule Homo sapiens 83-92 16471974-2 2006 The reactions between CuCl2, Cu(OAc)2, and CuSO4 and the two bipyridylurea ligands L1 and L2 [L1 = 1,3-bis(pyridin-4-ylmethyl)urea; L2 = 1,3-bis(pyridin-3-ylmethyl)urea; see Scheme 1 in paper] have been carried out and the crystal structure of five of the resulting metal-organic assemblies determined. cupric acetate 29-37 L1 cell adhesion molecule Homo sapiens 83-92 16471974-2 2006 The reactions between CuCl2, Cu(OAc)2, and CuSO4 and the two bipyridylurea ligands L1 and L2 [L1 = 1,3-bis(pyridin-4-ylmethyl)urea; L2 = 1,3-bis(pyridin-3-ylmethyl)urea; see Scheme 1 in paper] have been carried out and the crystal structure of five of the resulting metal-organic assemblies determined. Copper Sulfate 43-48 L1 cell adhesion molecule Homo sapiens 83-92 16471974-2 2006 The reactions between CuCl2, Cu(OAc)2, and CuSO4 and the two bipyridylurea ligands L1 and L2 [L1 = 1,3-bis(pyridin-4-ylmethyl)urea; L2 = 1,3-bis(pyridin-3-ylmethyl)urea; see Scheme 1 in paper] have been carried out and the crystal structure of five of the resulting metal-organic assemblies determined. bipyridylurea 61-74 L1 cell adhesion molecule Homo sapiens 83-92 16471974-2 2006 The reactions between CuCl2, Cu(OAc)2, and CuSO4 and the two bipyridylurea ligands L1 and L2 [L1 = 1,3-bis(pyridin-4-ylmethyl)urea; L2 = 1,3-bis(pyridin-3-ylmethyl)urea; see Scheme 1 in paper] have been carried out and the crystal structure of five of the resulting metal-organic assemblies determined. 1,3-bis(pyridin-4-ylmethyl)urea 99-130 L1 cell adhesion molecule Homo sapiens 83-92 16471974-2 2006 The reactions between CuCl2, Cu(OAc)2, and CuSO4 and the two bipyridylurea ligands L1 and L2 [L1 = 1,3-bis(pyridin-4-ylmethyl)urea; L2 = 1,3-bis(pyridin-3-ylmethyl)urea; see Scheme 1 in paper] have been carried out and the crystal structure of five of the resulting metal-organic assemblies determined. N,N'-Bis(3-pyridinylmethyl)urea 137-168 L1 cell adhesion molecule Homo sapiens 83-92 16471974-2 2006 The reactions between CuCl2, Cu(OAc)2, and CuSO4 and the two bipyridylurea ligands L1 and L2 [L1 = 1,3-bis(pyridin-4-ylmethyl)urea; L2 = 1,3-bis(pyridin-3-ylmethyl)urea; see Scheme 1 in paper] have been carried out and the crystal structure of five of the resulting metal-organic assemblies determined. Metals 266-271 L1 cell adhesion molecule Homo sapiens 83-92 16471974-4 2006 Particularly interesting, because of their potential as nanoporous materials, are the assemblies obtained from the reaction between each of the two ligands (L1 and L2) and CuCl2, which yield noninterpenetrating 2D metal-organic layers made of squares of ca. cupric chloride 172-177 L1 cell adhesion molecule Homo sapiens 157-166 16229685-5 2006 By analysing L1 (CD171) and CD44 in ovarian carcinoma cells, we show in the present paper that the cleavage induced by ionomycin, APMA (4-aminophenylmercuric acetate) or MCD (methyl-beta-cyclodextrin) is initiated in an endosomal compartment that is subsequently released in the form of exosomes. Ionomycin 119-128 L1 cell adhesion molecule Homo sapiens 17-22 16229685-5 2006 By analysing L1 (CD171) and CD44 in ovarian carcinoma cells, we show in the present paper that the cleavage induced by ionomycin, APMA (4-aminophenylmercuric acetate) or MCD (methyl-beta-cyclodextrin) is initiated in an endosomal compartment that is subsequently released in the form of exosomes. 4-aminophenylmercuriacetate 130-134 L1 cell adhesion molecule Homo sapiens 17-22 16229685-5 2006 By analysing L1 (CD171) and CD44 in ovarian carcinoma cells, we show in the present paper that the cleavage induced by ionomycin, APMA (4-aminophenylmercuric acetate) or MCD (methyl-beta-cyclodextrin) is initiated in an endosomal compartment that is subsequently released in the form of exosomes. 4-aminophenylmercuriacetate 136-165 L1 cell adhesion molecule Homo sapiens 17-22 16229685-5 2006 By analysing L1 (CD171) and CD44 in ovarian carcinoma cells, we show in the present paper that the cleavage induced by ionomycin, APMA (4-aminophenylmercuric acetate) or MCD (methyl-beta-cyclodextrin) is initiated in an endosomal compartment that is subsequently released in the form of exosomes. methyl-beta-cyclodextrin 170-173 L1 cell adhesion molecule Homo sapiens 17-22 16229685-5 2006 By analysing L1 (CD171) and CD44 in ovarian carcinoma cells, we show in the present paper that the cleavage induced by ionomycin, APMA (4-aminophenylmercuric acetate) or MCD (methyl-beta-cyclodextrin) is initiated in an endosomal compartment that is subsequently released in the form of exosomes. methyl-beta-cyclodextrin 175-199 L1 cell adhesion molecule Homo sapiens 17-22 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. glycosylamine 15-28 L1 cell adhesion molecule Homo sapiens 139-145 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. cu(ii) 37-43 L1 cell adhesion molecule Homo sapiens 139-145 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. ethylamine 57-67 L1 cell adhesion molecule Homo sapiens 139-145 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. trinuclear 119-129 L1 cell adhesion molecule Homo sapiens 139-145 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. meoh)2 156-162 L1 cell adhesion molecule Homo sapiens 139-145 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. (2x2meohxchcl3 176-190 L1 cell adhesion molecule Homo sapiens 139-145 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. cu(hl1) 239-246 L1 cell adhesion molecule Homo sapiens 139-145 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. etnh2) 148-154 L1 cell adhesion molecule Homo sapiens 139-145 16333500-1 2005 Treatment of a glycosylamine derived Cu(II) complex with ethylamine resulted in crystal-to-crystal transformation from trinuclear complex [Cu3(L1)2(EtNH2)2(MeOH)2]x2MeOHxCHCl3 (2x2MeOHxCHCl3) to a dimeric structure of mononuclear complex [Cu(HL1)(EtNH2)] (3) through proton transfer reaction and rearrangement of hydrogen bonding networks. Hydrogen 313-321 L1 cell adhesion molecule Homo sapiens 139-145 16248622-5 2005 The rate constant in CD3CN at 100 degrees C is 3/2k = 7.2 +/- 0.6 x 10-5 L1/2 mol-1/2 s-1; 3/2k represents the composite (kinit/kterm)1/2 kprop. Acetonitrile-d3 21-26 L1 cell adhesion molecule Homo sapiens 73-83 16097829-5 2005 With ligands L1 and L2 and precursor 1 the tridentately coordinated complexes [Re(L1)(CO)3] (7) and [Re(L2)(CO)3]2- (8) were formed. co)3 86-90 L1 cell adhesion molecule Homo sapiens 13-22 16241161-5 2005 The addition of these metal ions to dichloromethane solutions of L1, L2, and L3 produce strong changes in the absorption and emission spectra of these ligands. Metals 22-27 L1 cell adhesion molecule Homo sapiens 65-79 16241161-5 2005 The addition of these metal ions to dichloromethane solutions of L1, L2, and L3 produce strong changes in the absorption and emission spectra of these ligands. Methylene Chloride 36-51 L1 cell adhesion molecule Homo sapiens 65-79 15956769-3 2005 The current evidence suggests that alcohol produces many of its damaging effects by exerting specific actions on molecules that regulate key developmental processes (e.g., L1 cell adhesion molecule, alcohol dehydrogenase, catalase), interfering with the early development of midline serotonergic neurons and disrupting their regulatory-signaling function for other target brain structures, interfering with trophic factors that regulate neurogenesis and cell survival, or inducing excessive cell death via oxidative stress or activation of caspase-3 proteases. Alcohols 35-42 L1 cell adhesion molecule Homo sapiens 172-197 16133201-1 2005 Copper(II) complexes supported by bulky tridentate ligands L1(H) (N,N-bis(2-quinolylmethyl)-2-phenylethylamine) and L1(Ph) (N,N-bis(2-quinolylmethyl)-2,2-diphenylethylamine) have been prepared and their crystal structures as well as some physicochemical properties have been explored. cupric ion 0-10 L1 cell adhesion molecule Homo sapiens 116-122 16180444-7 2005 Final water turbidity was < 1.0 NTU, COD < 20 mg L(-1) O2 and 71 mNm(-1), the liquid/air interfacial tension. Water 6-11 L1 cell adhesion molecule Homo sapiens 55-70 15672197-3 2005 Ligands L1 and L2 can bind Group 1 and 2 metal cations in their crown-ether cavities; L3 contains two H-bond (amide) donors and is suitable for anion-binding. Metals 41-46 L1 cell adhesion molecule Homo sapiens 8-17 15672197-3 2005 Ligands L1 and L2 can bind Group 1 and 2 metal cations in their crown-ether cavities; L3 contains two H-bond (amide) donors and is suitable for anion-binding. Amides 110-115 L1 cell adhesion molecule Homo sapiens 8-17 15679404-2 2005 L1 and L2 form mononuclear Cu(II) complexes [Cu(L)(Cl)](ClO4) [L = L1 (1) and L2 (2)], respectively. cu(ii) 27-33 L1 cell adhesion molecule Homo sapiens 0-9 15679404-2 2005 L1 and L2 form mononuclear Cu(II) complexes [Cu(L)(Cl)](ClO4) [L = L1 (1) and L2 (2)], respectively. cu(l)(cl) 45-54 L1 cell adhesion molecule Homo sapiens 0-9 15679404-2 2005 L1 and L2 form mononuclear Cu(II) complexes [Cu(L)(Cl)](ClO4) [L = L1 (1) and L2 (2)], respectively. perchlorate 56-60 L1 cell adhesion molecule Homo sapiens 0-9 15679404-7 2005 Each Cu ion in 1 and 2 adopts a square pyramidal geometry with one Cl ion and two pendant groups (L1 and L2) binding in a bis-bidentate chelate mode. Copper 5-7 L1 cell adhesion molecule Homo sapiens 98-107 15736932-7 2005 We compared the binding affinities of L1 and L2, vis-a-vis their parent compound, benzenesulfonamide, for recombinant human carbonic anhydrase I (hCA-I) by performing the fluorescence titration and steady-state kinetic experiments. benzenesulfonamide 82-100 L1 cell adhesion molecule Homo sapiens 38-47 14657231-6 2003 Ligation of the L1-CAM ectodomain by an immobile substrate induces L1CD-ankyrinB binding and the formation of stationary ankyrinB clusters. l1cd-ankyrinb 67-80 L1 cell adhesion molecule Homo sapiens 16-22 15257602-2 2004 L1 and L3 have been prepared by an aroylation reaction of cyclohexyl-substituted cyclopentadienyl anions. cyclohexyl-substituted cyclopentadienyl anions 58-104 L1 cell adhesion molecule Homo sapiens 0-9 15211499-1 2004 Schizophyllan (SPG) with a molecular weight of 2.6x10(6), designated SPG-1, is denatured and then renatured at a concentration of 1.8 wt % by alkalization-neutralization. Sizofiran 0-13 L1 cell adhesion molecule Homo sapiens 69-74 15211499-1 2004 Schizophyllan (SPG) with a molecular weight of 2.6x10(6), designated SPG-1, is denatured and then renatured at a concentration of 1.8 wt % by alkalization-neutralization. spirogermanium 15-18 L1 cell adhesion molecule Homo sapiens 69-74 15609076-9 2004 Furthermore, L1Ig6 stimulated HUVECs showed increased tyrosine phosphorylation of alpha(v)beta3 and phosphorylation of MAP kinases (ERK1 and ERK2) but not AKT indicating specific activation of alpha(v) and alpha(v)beta3 followed by activation of downstream kinases. Tyrosine 54-62 L1 cell adhesion molecule Homo sapiens 13-18 14584818-6 2003 L1-Fc micropatterned on a background of poly-L-lysine resulted in selective growth of the axons on the micropattern, whereas the somata and dendrites were unresponsive. Lysine 40-53 L1 cell adhesion molecule Homo sapiens 0-2 10898389-5 2000 Cadmium determination by Inductively Coupled Plasma Spectrometry and Graphite Furnace Flame Atomic Absorption Spectrometry were subject to interference at arsenic concentrations greater than 50 microg l-1 and 10 mg l-1, respectively. Cadmium 0-7 L1 cell adhesion molecule Homo sapiens 201-211 12720449-9 2003 Such a luminescence is assigned to CT states at room temperature and to phenanthroline-centered pi-pi triplet levels at 77 K. The room-temperature luminescence of L1 and L2 is totally quenched by acid or zinc acetate. Phenanthrolines 72-86 L1 cell adhesion molecule Homo sapiens 163-172 12720449-9 2003 Such a luminescence is assigned to CT states at room temperature and to phenanthroline-centered pi-pi triplet levels at 77 K. The room-temperature luminescence of L1 and L2 is totally quenched by acid or zinc acetate. acid or zinc acetate 196-216 L1 cell adhesion molecule Homo sapiens 163-172 11839747-5 2002 A prominent V-shaped groove formed by a surface loop, L1, connecting beta 1- and beta 2-strands and the lipoyl lysine beta-hairpin constitutes the functional pocket. Lysine 111-117 L1 cell adhesion molecule Homo sapiens 54-87 11839747-5 2002 A prominent V-shaped groove formed by a surface loop, L1, connecting beta 1- and beta 2-strands and the lipoyl lysine beta-hairpin constitutes the functional pocket. -hairpin 122-130 L1 cell adhesion molecule Homo sapiens 54-87 11468348-2 2001 In the structure, four out of the six hypervariable loops of the Fab (complementarity determining regions [CDRs] L1, H1, H2, and H3) are involved in peptide association through hydrogen bonding, salt bridge formation, and hydrophobic interactions. Hydrogen 177-185 L1 cell adhesion molecule Homo sapiens 113-131 11168937-11 2001 L1-CAM was expressed in only the CD system, and sorting of all L1-CAM-positive cells allowed> 95% purification of CD system cells (connecting tubule/cortical CD). Cadmium 33-35 L1 cell adhesion molecule Homo sapiens 0-6 11168937-11 2001 L1-CAM was expressed in only the CD system, and sorting of all L1-CAM-positive cells allowed> 95% purification of CD system cells (connecting tubule/cortical CD). Cadmium 117-119 L1 cell adhesion molecule Homo sapiens 63-69 11168937-11 2001 L1-CAM was expressed in only the CD system, and sorting of all L1-CAM-positive cells allowed> 95% purification of CD system cells (connecting tubule/cortical CD). Cadmium 117-119 L1 cell adhesion molecule Homo sapiens 63-69 11085868-3 2000 Under normal growth conditions, the L1 adhesion molecule has now been shown to induce local rather than global changes in calcium in growth cones, and this suggests that cell adhesion molecules (CAMs) use localized calcium transients to stimulate axonal growth and guidance. Calcium 122-129 L1 cell adhesion molecule Homo sapiens 36-56 11085868-3 2000 Under normal growth conditions, the L1 adhesion molecule has now been shown to induce local rather than global changes in calcium in growth cones, and this suggests that cell adhesion molecules (CAMs) use localized calcium transients to stimulate axonal growth and guidance. Calcium 215-222 L1 cell adhesion molecule Homo sapiens 36-56 12953467-4 2000 The calibration curve of Fe(III) is linear between 0.0-40.0 micrograms.L-1, and the determination limit is 4.68 ng.L-1. ferric sulfate 25-32 L1 cell adhesion molecule Homo sapiens 71-74 12953467-4 2000 The calibration curve of Fe(III) is linear between 0.0-40.0 micrograms.L-1, and the determination limit is 4.68 ng.L-1. ferric sulfate 25-32 L1 cell adhesion molecule Homo sapiens 115-118 10660503-5 2000 Mean aqueous humour levels of cefpirome in patients receiving a dosage of 1 g were 1.33 mg/L (1 h), 1.67 mg/L (2 h) and 1.29 mg/L (6 h after application), respectively. cefpirome 30-39 L1 cell adhesion molecule Homo sapiens 108-121 12800133-5 2003 The 12 amino acid residues in the enzymes serving as the copper ligands are housed within these four identified conserved regions, of which L2 and L4 conform to the earlier reported copper signature sequences of multi-copper oxidases while L1 and L3 are distinctive to the laccases. Copper 57-63 L1 cell adhesion molecule Homo sapiens 240-249 12800133-5 2003 The 12 amino acid residues in the enzymes serving as the copper ligands are housed within these four identified conserved regions, of which L2 and L4 conform to the earlier reported copper signature sequences of multi-copper oxidases while L1 and L3 are distinctive to the laccases. Copper 182-188 L1 cell adhesion molecule Homo sapiens 240-249 12800133-5 2003 The 12 amino acid residues in the enzymes serving as the copper ligands are housed within these four identified conserved regions, of which L2 and L4 conform to the earlier reported copper signature sequences of multi-copper oxidases while L1 and L3 are distinctive to the laccases. Copper 182-188 L1 cell adhesion molecule Homo sapiens 240-249 12833291-1 2003 The binding properties of two alpha-cyclodextrins, each containing two C(5)-linked "CH(2)PPh(2)" units, L 1 (A,D-substituted) and L 2 (A,C-substituted), have been investigated. alpha-Cyclodextrins 30-49 L1 cell adhesion molecule Homo sapiens 104-107 12833291-5 2003 Together with four methoxy groups anchored onto the primary face, the two P(III) centres of L 1 form a circularly arranged P(2)O(4) 12-electron donor set able to complex an Ag(+) ion in a dynamic way, each of the four oxygen atoms coordinating successively to the silver ion. Oxygen 218-224 L1 cell adhesion molecule Homo sapiens 92-95 12833291-6 2003 Furthermore, the particular structures of L 1 and L 2, characterised by the presence of P(III) units lying close to the cavity entrance, lead upon complexation to complexes whereby the first coordination sphere is partly entrapped in the cyclodextrin. Cyclodextrins 238-250 L1 cell adhesion molecule Homo sapiens 42-53 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 47-59 L1 cell adhesion molecule Homo sapiens 24-27 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 47-59 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 47-59 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 126-138 L1 cell adhesion molecule Homo sapiens 24-27 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 126-138 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 126-138 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 126-138 L1 cell adhesion molecule Homo sapiens 24-27 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 126-138 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. acetonitrile 126-138 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. Nitriles 206-214 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. Nitriles 206-214 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. Cyclodextrins 230-242 L1 cell adhesion molecule Homo sapiens 140-143 12833291-8 2003 The chelate complex [Ag(L 1)]BF(4) reacts with acetonitrile in excess to afford a mixture of two equilibrating complexes, [Ag(acetonitrile)(L 1)]BF(4) and [Ag(acetonitrile)(2)(L 1)]BF(4), whose coordinated nitriles lie inside the cyclodextrin cavity. Cyclodextrins 230-242 L1 cell adhesion molecule Homo sapiens 140-143 12834484-4 2003 Immunohistochemical staining of CD171 and CD24 was performed by the streptavidin-biotin-peroxidase-complex technique and a nickel-enhanced diaminobenzidine (DAB) reaction using the monoclonal antibodies UJ 127.11 and ML-5, respectively. Nickel 123-129 L1 cell adhesion molecule Homo sapiens 32-37 12834484-4 2003 Immunohistochemical staining of CD171 and CD24 was performed by the streptavidin-biotin-peroxidase-complex technique and a nickel-enhanced diaminobenzidine (DAB) reaction using the monoclonal antibodies UJ 127.11 and ML-5, respectively. 4,4'-Dihydrazino-biphenyl 139-155 L1 cell adhesion molecule Homo sapiens 32-37 14599989-6 2003 The TSB level of the 21 patients was reduced from 410.53+/-98.13 micromol/L to 270.23+/-115.64 micromol/L and 105.43+/-97.85 micromol/L 1 and 2 weeks after operation, respectively. Tri S Bond 4-7 L1 cell adhesion molecule Homo sapiens 134-143 12639118-2 2003 Addition of aqueous H(2)O(2) to methanol solutions of the Mn(II) complexes of L(1) and L(2) produced green solutions in a fast reaction from which subsequently precipitated brown solids of the dioxo-bridged dinuclear complexes 1 and 2, respectively, which have the general formula [LMn(III)(mu-O)(2)Mn(III)L](ClO(4))(2). Water 20-25 L1 cell adhesion molecule Homo sapiens 78-82 12639118-2 2003 Addition of aqueous H(2)O(2) to methanol solutions of the Mn(II) complexes of L(1) and L(2) produced green solutions in a fast reaction from which subsequently precipitated brown solids of the dioxo-bridged dinuclear complexes 1 and 2, respectively, which have the general formula [LMn(III)(mu-O)(2)Mn(III)L](ClO(4))(2). Methanol 32-40 L1 cell adhesion molecule Homo sapiens 78-82 12639118-2 2003 Addition of aqueous H(2)O(2) to methanol solutions of the Mn(II) complexes of L(1) and L(2) produced green solutions in a fast reaction from which subsequently precipitated brown solids of the dioxo-bridged dinuclear complexes 1 and 2, respectively, which have the general formula [LMn(III)(mu-O)(2)Mn(III)L](ClO(4))(2). Manganese(2+) 58-64 L1 cell adhesion molecule Homo sapiens 78-82 12639118-2 2003 Addition of aqueous H(2)O(2) to methanol solutions of the Mn(II) complexes of L(1) and L(2) produced green solutions in a fast reaction from which subsequently precipitated brown solids of the dioxo-bridged dinuclear complexes 1 and 2, respectively, which have the general formula [LMn(III)(mu-O)(2)Mn(III)L](ClO(4))(2). dioxo 193-198 L1 cell adhesion molecule Homo sapiens 78-82 12639118-2 2003 Addition of aqueous H(2)O(2) to methanol solutions of the Mn(II) complexes of L(1) and L(2) produced green solutions in a fast reaction from which subsequently precipitated brown solids of the dioxo-bridged dinuclear complexes 1 and 2, respectively, which have the general formula [LMn(III)(mu-O)(2)Mn(III)L](ClO(4))(2). clo 309-312 L1 cell adhesion molecule Homo sapiens 78-82 11315605-1 2001 Iodine-131 labelled anti L1-CAM antibody mAb chCE7 was compared with the effective neuroblastoma-seeking agent 131I-labelled metaiodobenzylguanidine (MIBG) with regard to (a) its therapeutic efficacy in treating nude mice with neuroblastoma xenografts and (b) its tumour targeting ability in neuroblastoma patients. Iodine-131 0-10 L1 cell adhesion molecule Homo sapiens 25-31 10748134-7 2000 PDK3 activity was stimulated upon reductive acetylation of L1 and L2 when full activation of PDK3 by E2 was avoided (e.g. using free lipoyl domains or ADP-inhibited E2-activated PDK3). Adenosine Diphosphate 151-154 L1 cell adhesion molecule Homo sapiens 59-68 10632712-2 2000 The flash-oxidized primary donor P+ of the reaction center (RC) is rapidly re-reduced by heme H1 (Em,7 = 290 mV), heme H2 (Em,7 = 240 mV) or low-potential hemes L1/L2 (Em,7 = 90 mV) of the RC-bound tetraheme, depending on their redox state before photoexcitation. Heme 155-160 L1 cell adhesion molecule Homo sapiens 161-166 10632712-2 2000 The flash-oxidized primary donor P+ of the reaction center (RC) is rapidly re-reduced by heme H1 (Em,7 = 290 mV), heme H2 (Em,7 = 240 mV) or low-potential hemes L1/L2 (Em,7 = 90 mV) of the RC-bound tetraheme, depending on their redox state before photoexcitation. tetraheme 198-207 L1 cell adhesion molecule Homo sapiens 161-166 12058176-4 2000 The cDNAs of L1, L2 and L1-(Ala)(10)-L2(designed ten-alanine-connected L1 and L2)were cloned, respectively, into an expression plasmid pET-3a, and E.coli BL21(DE3)transformants with such plasmids were successfully induced to express the goal proteins. Alanine 28-31 L1 cell adhesion molecule Homo sapiens 71-80 12058176-4 2000 The cDNAs of L1, L2 and L1-(Ala)(10)-L2(designed ten-alanine-connected L1 and L2)were cloned, respectively, into an expression plasmid pET-3a, and E.coli BL21(DE3)transformants with such plasmids were successfully induced to express the goal proteins. Alanine 53-60 L1 cell adhesion molecule Homo sapiens 71-80 10576103-8 1999 At input concentrations of 4-NA up to 4.5 mM and a hydraulic retention time of 3.5 hours a high degradation rate of 1.1 mmol 4-NA L-1 h-1 and 90 ... 95% DOC removal were achieved. 4-nitroaniline 27-31 L1 cell adhesion molecule Homo sapiens 130-133 10576103-8 1999 At input concentrations of 4-NA up to 4.5 mM and a hydraulic retention time of 3.5 hours a high degradation rate of 1.1 mmol 4-NA L-1 h-1 and 90 ... 95% DOC removal were achieved. 4-nitroaniline 125-129 L1 cell adhesion molecule Homo sapiens 130-133 10576103-8 1999 At input concentrations of 4-NA up to 4.5 mM and a hydraulic retention time of 3.5 hours a high degradation rate of 1.1 mmol 4-NA L-1 h-1 and 90 ... 95% DOC removal were achieved. Desoxycorticosterone 153-156 L1 cell adhesion molecule Homo sapiens 130-133