PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
32409033-6	2020	The prepared sensor showed good performance for H2O2 detection from 6.85 nM to 7 muM with the detection limit of 2.06 nM (S/N = 3), and pH test from 3.0 to 9.0.	Hydrogen Peroxide	48-52	latexin	Homo sapiens	81-84	
1249070-3	1976	In addition, such oxidants as vitamin K5 (50 muM), hydrogen peroxide (4mM), methylene blue (50 muM), and diamide (20 mM) also maximally activated 3-O-methylglucose transport and their effects were not additive to those of maximal concentrations of insulin.	Hydrogen Peroxide	51-68	latexin	Homo sapiens	95-98	
803813-3	1975	The method is capable of assaying hydrogen peroxide concentrations as low as 7 muM.	Hydrogen Peroxide	34-51	latexin	Homo sapiens	79-82	
32456920-2	2020	In this work, porous regular hexagonal-shaped FeS2 nanosheets (NSs) with a side length of about 1 mum are employed as a peroxidase mimic to detect H2O2.	Hydrogen Peroxide	147-151	latexin	Homo sapiens	98-101	
32456920-4	2020	The FeS2 NSs exhibit high sensitivity in linear range of 0.02-4.00 muM of H2O2 with a limit of detection (LOD) of 7.60 nM (S/N = 3).	Hydrogen Peroxide	74-78	latexin	Homo sapiens	67-70	
31967629-10	2020	At lower concentrations (<100 muM), consistent with the enzyme-like activities detected in solution, all three NPs significantly decreased H2O2-induced cytotoxicity in Caco-2 cells.	Hydrogen Peroxide	139-143	latexin	Homo sapiens	30-33	
32607608-7	2020	As a result, the determination of H2O2 without the aid of complicated instruments is achieved in the range 2.0 muM to 0.2 mM with a detection limit of 1.02 muM.	Hydrogen Peroxide	34-38	latexin	Homo sapiens	111-114	
32607608-7	2020	As a result, the determination of H2O2 without the aid of complicated instruments is achieved in the range 2.0 muM to 0.2 mM with a detection limit of 1.02 muM.	Hydrogen Peroxide	34-38	latexin	Homo sapiens	156-159	
32252908-4	2020	A highly efficient, rapid, sensitive, and selective determination of H2O2 and glucose have been achieved with very low detection limits of 22 nM, and 27.6 nM over 0-8 muM and 0-1000 muM linear ranges, respectively.	Hydrogen Peroxide	69-73	latexin	Homo sapiens	167-170	
32252908-4	2020	A highly efficient, rapid, sensitive, and selective determination of H2O2 and glucose have been achieved with very low detection limits of 22 nM, and 27.6 nM over 0-8 muM and 0-1000 muM linear ranges, respectively.	Hydrogen Peroxide	69-73	latexin	Homo sapiens	182-185	
31690112-3	2019	Cell proliferation was increased in low doses of H2O2 (10-4 to 10-2 muM), whereas sublethal concentrations of H2O2 (>200 muM) induced apoptosis.	Hydrogen Peroxide	49-53	latexin	Homo sapiens	68-71	
31845299-7	2019	The fluorescent probe, best operated at excitation/emission wavelengths of 554/577 nm, allows hydrogen peroxide to be determined in concentrations as low as 94 pM with a linear range spanning from 1 nM to 1 muM.	Hydrogen Peroxide	94-111	latexin	Homo sapiens	207-210	
31690112-3	2019	Cell proliferation was increased in low doses of H2O2 (10-4 to 10-2 muM), whereas sublethal concentrations of H2O2 (>200 muM) induced apoptosis.	Hydrogen Peroxide	110-114	latexin	Homo sapiens	121-124	
31147043-4	2019	The obtained biosensor exhibited wide linear ranges (glucose: 0.005-10.95 mM; H2O2: 1-510 muM) and a low detection limits (glucose: 0.39 muM; H2O2: 0.136 muM) in alkaline solution (S/N = 3).	Hydrogen Peroxide	78-82	latexin	Homo sapiens	90-93	
31601055-7	2019	Notably, the most active compound 8 displayed the highest protective effect (50% effective concentration (EC50) = 4.31 muM) against tert-butyl, hydroperoxide-induced, SH-SY5Y neurotoxicity cells, which was much better than the baicalein (EC50 = 24.77 muM) and edaravin (EC50 = 5.62 muM).	Hydrogen Peroxide	144-157	latexin	Homo sapiens	119-122	
31601055-7	2019	Notably, the most active compound 8 displayed the highest protective effect (50% effective concentration (EC50) = 4.31 muM) against tert-butyl, hydroperoxide-induced, SH-SY5Y neurotoxicity cells, which was much better than the baicalein (EC50 = 24.77 muM) and edaravin (EC50 = 5.62 muM).	Hydrogen Peroxide	144-157	latexin	Homo sapiens	251-254	
31601055-7	2019	Notably, the most active compound 8 displayed the highest protective effect (50% effective concentration (EC50) = 4.31 muM) against tert-butyl, hydroperoxide-induced, SH-SY5Y neurotoxicity cells, which was much better than the baicalein (EC50 = 24.77 muM) and edaravin (EC50 = 5.62 muM).	Hydrogen Peroxide	144-157	latexin	Homo sapiens	251-254	
31039858-4	2019	Using the modified electrode for the linear sweep voltammetry (LSV) detection of H2O2, the detection limit and sensitivity were determined to be 4.8 muM (S/N   3) and 0.0262 muA muM-1, respectively.	Hydrogen Peroxide	81-85	latexin	Homo sapiens	149-152	
31368448-3	2019	The resulting flexible sensors exhibit capability in detecting ascorbic acid (AA), hydrogen peroxide (H2O2) and L-Histidine (L-His) with detection limits of 2.94, 4.1 and 5.3 muM, respectively.	Hydrogen Peroxide	83-100	latexin	Homo sapiens	175-178	
31147043-4	2019	The obtained biosensor exhibited wide linear ranges (glucose: 0.005-10.95 mM; H2O2: 1-510 muM) and a low detection limits (glucose: 0.39 muM; H2O2: 0.136 muM) in alkaline solution (S/N = 3).	Hydrogen Peroxide	78-82	latexin	Homo sapiens	137-140	
31147043-4	2019	The obtained biosensor exhibited wide linear ranges (glucose: 0.005-10.95 mM; H2O2: 1-510 muM) and a low detection limits (glucose: 0.39 muM; H2O2: 0.136 muM) in alkaline solution (S/N = 3).	Hydrogen Peroxide	78-82	latexin	Homo sapiens	137-140	
31073567-5	2019	Probe 1 has satisfactory sensitivity to hydrogen peroxide with a low detection limit of 0.14 muM (S/N = 3), attributed to a responding mechanism that leads to the oxidation of phenylboronic acid pinacol ester and thereby releases fluorophore 2.	Hydrogen Peroxide	40-57	latexin	Homo sapiens	93-96	
31422477-5	2019	Figures of merit for detection H2O2 assay include (a) a working voltage of 0.7 V (vs. the reversible hydrogen electrode); (b) a wide linear response range (from 0.01 to 1.7 mM), and (c) a low detection limit (0.1 muM).	Hydrogen Peroxide	31-35	latexin	Homo sapiens	213-216	
31214778-8	2019	The limit of electrochemical detection of H2O2 (at a potential as low as 50 mV) is 1.1 muM which is comparable or better than most analogous methods.	Hydrogen Peroxide	42-46	latexin	Homo sapiens	87-90	
31385065-4	2019	A colorimetric method was developed for the determination of H2O2 that has a 1.75 muM detection limit and a linear response in the 10-5 to 10-4 M concentration range.	Hydrogen Peroxide	61-65	latexin	Homo sapiens	82-85	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	115-119	latexin	Homo sapiens	200-203	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	115-119	latexin	Homo sapiens	228-231	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	115-119	latexin	Homo sapiens	228-231	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	115-119	latexin	Homo sapiens	228-231	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	209-213	latexin	Homo sapiens	200-203	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	209-213	latexin	Homo sapiens	228-231	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	209-213	latexin	Homo sapiens	228-231	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	209-213	latexin	Homo sapiens	228-231	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	209-213	latexin	Homo sapiens	200-203	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	209-213	latexin	Homo sapiens	228-231	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	209-213	latexin	Homo sapiens	228-231	
30852265-9	2019	Based on the excellent catalytic activity of FePPOPs-SO3H, two visual colorimetric sensors for ultrafast detecting H2O2 and glucose, respectively, were constructed with a wide linear range of 50-1800 muM (for H2O2) and 200-1500 muM (for glucose), as well as a relative lower limit of detection (LOD) [26.70 muM (for H2O2) and 16.38 muM (for glucose)].	Hydrogen Peroxide	209-213	latexin	Homo sapiens	228-231	
31165952-4	2019	The calibration curves obtained are linear for the current versus AA and H2O2 concentration over the range 50-500 muM and 10-140 muM, respectively.	Hydrogen Peroxide	73-77	latexin	Homo sapiens	114-117	
30976770-4	2019	Moreover, the AgFKZSiW12@PPy-based colorimetric biosensing platform towards H2O2 and ascorbic acid (AA) exhibits limits of detection (LOD) as low as 0.12 muM and 2.7 muM, respectively.	Hydrogen Peroxide	76-80	latexin	Homo sapiens	154-157	
30976770-4	2019	Moreover, the AgFKZSiW12@PPy-based colorimetric biosensing platform towards H2O2 and ascorbic acid (AA) exhibits limits of detection (LOD) as low as 0.12 muM and 2.7 muM, respectively.	Hydrogen Peroxide	76-80	latexin	Homo sapiens	166-169	
30816608-6	2019	Also, co-administration of quercetin (especially at 40 and 80 muM) with hydrogen peroxide restored the toxic effects of hydrogen peroxide on rooster semen parameters such as primary and secondary lipid peroxidative indicators and other evaluated variables.	Hydrogen Peroxide	72-89	latexin	Homo sapiens	62-65	
31165952-4	2019	The calibration curves obtained are linear for the current versus AA and H2O2 concentration over the range 50-500 muM and 10-140 muM, respectively.	Hydrogen Peroxide	73-77	latexin	Homo sapiens	129-132	
31165952-5	2019	And the detection limits for AA and H2O2 are 4.2 muM and 1.9 muM, respectively.	Hydrogen Peroxide	36-40	latexin	Homo sapiens	49-52	
31165952-5	2019	And the detection limits for AA and H2O2 are 4.2 muM and 1.9 muM, respectively.	Hydrogen Peroxide	36-40	latexin	Homo sapiens	61-64	
30820500-6	2019	H2O2 was detected with a detection limit of 0.7 muM over two wide linear ranges (from 3 muM to 1 mM and from 1 mM to 0.1 M) and with high sensitivities (757.4 muA mM-1 cm-2 and 315.4 muA mM-1 cm-2), respectively.	Hydrogen Peroxide	0-4	latexin	Homo sapiens	48-51	
30865189-5	2019	Under the most favorable conditions, the linear range for H2O2 detection was 40 muM to 800 muM and the detection limit was 18.9 muM.	Hydrogen Peroxide	58-62	latexin	Homo sapiens	80-83	
30865189-5	2019	Under the most favorable conditions, the linear range for H2O2 detection was 40 muM to 800 muM and the detection limit was 18.9 muM.	Hydrogen Peroxide	58-62	latexin	Homo sapiens	91-94	
30865189-5	2019	Under the most favorable conditions, the linear range for H2O2 detection was 40 muM to 800 muM and the detection limit was 18.9 muM.	Hydrogen Peroxide	58-62	latexin	Homo sapiens	91-94	
31191867-9	2019	At cellular level compound 4 (1 muM) showed significant protective effects in neuroblastoma SH-SY5Y cell line when treated with hydrogen peroxide (400 muM).	Hydrogen Peroxide	128-145	latexin	Homo sapiens	32-35	
31191867-9	2019	At cellular level compound 4 (1 muM) showed significant protective effects in neuroblastoma SH-SY5Y cell line when treated with hydrogen peroxide (400 muM).	Hydrogen Peroxide	128-145	latexin	Homo sapiens	151-154	
30820500-6	2019	H2O2 was detected with a detection limit of 0.7 muM over two wide linear ranges (from 3 muM to 1 mM and from 1 mM to 0.1 M) and with high sensitivities (757.4 muA mM-1 cm-2 and 315.4 muA mM-1 cm-2), respectively.	Hydrogen Peroxide	0-4	latexin	Homo sapiens	88-91	
30886671-4	2019	We have found that H2O2 in concentration range 10-100 muM increases the rise of [Ca2+]i induced by 5-hydroxytryptamine (5-HT) and carbachol and does not affect the calcium signals of ATP, agonist of type 1 protease-activated receptor SFLLRN, histamine and bradykinin.	Hydrogen Peroxide	19-23	latexin	Homo sapiens	54-57	
30336241-5	2019	The electrocatalytic response of the biosensor was proportional to the hydrogen peroxide concentration in the range of 1 muM to 2.2 mM with a limit of detection and sensitivity of 290 nM and 0.024 muA/muM, respectively.	Hydrogen Peroxide	71-88	latexin	Homo sapiens	121-124	
30336241-5	2019	The electrocatalytic response of the biosensor was proportional to the hydrogen peroxide concentration in the range of 1 muM to 2.2 mM with a limit of detection and sensitivity of 290 nM and 0.024 muA/muM, respectively.	Hydrogen Peroxide	71-88	latexin	Homo sapiens	201-204	
30366526-6	2019	Under optimized conditions, the hemin/RGO-CMF composite exhibit a linear response to H2O2 in the concentration range from 0.06 to 540.6 muM with the lower detection limit of 16 nM.	Hydrogen Peroxide	85-89	latexin	Homo sapiens	136-139	
30721353-6	2019	The detection limits are 8 muM for Fe(III) and 0.6 muM for H2O2.	Hydrogen Peroxide	59-63	latexin	Homo sapiens	51-54	
29458613-5	2018	The sensor based on pompon-like Co9S8 displayed a wide linear response ranged from 1.50 muM to 8.51 mM, a favorable sensitivity of 20.80 muA mM-1 cm-2 and a detection limit of 0.45 muM (signal to noise ratio of 3) for hydrogen peroxide.	Hydrogen Peroxide	218-235	latexin	Homo sapiens	88-91	
30357214-2	2018	These nanostructures demonstrated an enhanced release after exposure to an alternating magnetic field, and a complete release of the encapsulated drug after the synergic effect of low pH (4.5), increased concentration of hydrogen peroxide (50 muM), and increased temperature due to the applied magnetic field.	Hydrogen Peroxide	221-238	latexin	Homo sapiens	243-246	
29982029-7	2018	The Bi2S3@N-G/GC electrode demonstrated a wide concentration range for H2O2, from 10 to 42,960 muM, with a sensitivity of 0.1535 muA muM-1 and an obtained limit of detection of 1.9 muM.	Hydrogen Peroxide	71-75	latexin	Homo sapiens	95-98	
29982029-7	2018	The Bi2S3@N-G/GC electrode demonstrated a wide concentration range for H2O2, from 10 to 42,960 muM, with a sensitivity of 0.1535 muA muM-1 and an obtained limit of detection of 1.9 muM.	Hydrogen Peroxide	71-75	latexin	Homo sapiens	133-136	
30186615-9	2018	Results: Pretreatment with low-dose (1 and 5 muM) CAM for 72 h inhibited H2O2-induced reductions of GPx-1, GR, SOD, CAT and HO-1 activities, and mRNA expressions of GPx-1 and HO-1, and improved the GSH/GSSG ratio.	Hydrogen Peroxide	73-77	latexin	Homo sapiens	45-48	
29987346-4	2018	The response current of the sensor showed a good linear relationship with the concentration of H2O2 in the range of 10-1000 muM (R2 = 0.9916).	Hydrogen Peroxide	95-99	latexin	Homo sapiens	124-127	
30516364-6	2019	The captured sweat droplets present strong electrochemical signals using graphene films as the working electrode and metal pins as the counter electrode arrays assembled on 3D printed holders, at the detection limit of 6 muM for H2O2 sensing.	Hydrogen Peroxide	229-233	latexin	Homo sapiens	221-224	
30442395-4	2018	Moreover, copper microelectrode doped with cobalt has demonstrated good reproducibility and long-run stability as well as sensitivity and selectivity towards determination of hydrogen peroxide (limit of detection-0.2 muM) and d-glucose (limit of detection-2.2 muM).	Hydrogen Peroxide	175-192	latexin	Homo sapiens	217-220	
30442395-4	2018	Moreover, copper microelectrode doped with cobalt has demonstrated good reproducibility and long-run stability as well as sensitivity and selectivity towards determination of hydrogen peroxide (limit of detection-0.2 muM) and d-glucose (limit of detection-2.2 muM).	Hydrogen Peroxide	175-192	latexin	Homo sapiens	260-263	
30140810-4	2018	Using dual-enzyme inorganic hybrid nanoflowers in the muPAD as nanobiocatalysts, which preserve the activity and enhance the stability of the enzymes, based on the H2O2-mediated catalytic oxidizing chromogenic reaction produced by glucose/uric acid, the developed multiplex paper-based nanobiocatalytic system is demonstrated to enable simultaneous and sensitive detection of glucose and uric acid with a detection limit of 60 and 25 muM, respectively.	Hydrogen Peroxide	164-168	latexin	Homo sapiens	434-437	
29458613-5	2018	The sensor based on pompon-like Co9S8 displayed a wide linear response ranged from 1.50 muM to 8.51 mM, a favorable sensitivity of 20.80 muA mM-1 cm-2 and a detection limit of 0.45 muM (signal to noise ratio of 3) for hydrogen peroxide.	Hydrogen Peroxide	218-235	latexin	Homo sapiens	181-184	
32254180-8	2018	The sensitivity of the sensor towards H2O2 was 0.557 muA mM-1, with a limit of detection (LOD) at 56.89 muM.	Hydrogen Peroxide	38-42	latexin	Homo sapiens	104-107	
28527631-7	2018	A single treatment of cells with 100 muM hydrogen peroxide 24 h before analysis had no effect on wildtype cells, but normalized the otherwise increased respiration of knockout cells and significantly increased respiration in C684A cells.	Hydrogen Peroxide	41-58	latexin	Homo sapiens	37-40	
29796900-4	2018	Electrochemical investigation demonstrates that the as-prepared modified microelectrode showed a quasi-reversible process toward the reduction of H2O2, which exhibited a linear range from 0.51 to 10.6 muM, with a limit of detection of 0.23 muM.	Hydrogen Peroxide	146-150	latexin	Homo sapiens	201-204	
29796900-4	2018	Electrochemical investigation demonstrates that the as-prepared modified microelectrode showed a quasi-reversible process toward the reduction of H2O2, which exhibited a linear range from 0.51 to 10.6 muM, with a limit of detection of 0.23 muM.	Hydrogen Peroxide	146-150	latexin	Homo sapiens	240-243	
29414085-4	2018	And the nanosheets exhibited excellent H2O2 detection property with a high sensitivity of about 320.3 uA mM-1 cm-2 and a low detection limit of 0.17 microM in a wide linear range of 5-6000 muM, and a fast response time (less than 2 s).	Hydrogen Peroxide	39-43	latexin	Homo sapiens	189-192	
29567236-5	2018	The lowest H2O2 concentration could be measured by the as-prepared strip was 10 muM.	Hydrogen Peroxide	11-15	latexin	Homo sapiens	80-83	
29397683-8	2018	The electrochemical response toward H2O2 exhibits a linear dependence on hydrogen peroxide concentration ranging between 10 muM and 700 muM.	Hydrogen Peroxide	36-40	latexin	Homo sapiens	124-127	
29397683-8	2018	The electrochemical response toward H2O2 exhibits a linear dependence on hydrogen peroxide concentration ranging between 10 muM and 700 muM.	Hydrogen Peroxide	36-40	latexin	Homo sapiens	136-139	
29397683-8	2018	The electrochemical response toward H2O2 exhibits a linear dependence on hydrogen peroxide concentration ranging between 10 muM and 700 muM.	Hydrogen Peroxide	73-90	latexin	Homo sapiens	124-127	
29397683-8	2018	The electrochemical response toward H2O2 exhibits a linear dependence on hydrogen peroxide concentration ranging between 10 muM and 700 muM.	Hydrogen Peroxide	73-90	latexin	Homo sapiens	136-139	
29035776-5	2018	Screening results indicated that compounds 4, 5, 12, 13 showed moderate neuroprotective effects on H2O2-induced cellular damage in human neuroblastoma SH-SY5Y cells (10 muM).	Hydrogen Peroxide	99-103	latexin	Homo sapiens	169-172	
29594683-4	2018	The color change can be observed visually if the concentration of H2O2 is 2 muM or higher.	Hydrogen Peroxide	66-70	latexin	Homo sapiens	76-79	
29411011-12	2018	CsA (10 muM) significantly inhibited the H2O2-induced expression of NFATc3 in normal and glaucoma LC cells.	Hydrogen Peroxide	41-45	latexin	Homo sapiens	8-11	
30023768-7	2018	The linear range toward H2O2 sensing is from 0.3 to 2338 muM, and the limit of detection (LOD) is 0.1 muM.	Hydrogen Peroxide	24-28	latexin	Homo sapiens	57-60	
30023768-7	2018	The linear range toward H2O2 sensing is from 0.3 to 2338 muM, and the limit of detection (LOD) is 0.1 muM.	Hydrogen Peroxide	24-28	latexin	Homo sapiens	102-105	
28211035-5	2017	Our results showed that low H2O2 concentrations (20 muM) can promote FLS growth and that Res significantly inhibited FLS activity.	Hydrogen Peroxide	28-32	latexin	Homo sapiens	52-55	
29207575-3	2017	By further evaluating their cytoprotective activity against H2O2 induced injury in EA.hy926 cells, 14 target bromophenols showed moderate-to-potent activity with EC50 values in the range of 0.9-6.3 muM, which were stronger than that of quercetin (EC50: 18.0 muM), a positive reference compound.	Hydrogen Peroxide	60-64	latexin	Homo sapiens	198-201	
29207575-3	2017	By further evaluating their cytoprotective activity against H2O2 induced injury in EA.hy926 cells, 14 target bromophenols showed moderate-to-potent activity with EC50 values in the range of 0.9-6.3 muM, which were stronger than that of quercetin (EC50: 18.0 muM), a positive reference compound.	Hydrogen Peroxide	60-64	latexin	Homo sapiens	258-261	
28882760-5	2017	Using an oxygen sensor, the oxygen concentration was found to increase with a rate up to 0.4muM/min, which was dependent upon the concentrations of hydrogen peroxide and the Mn-protein.	Hydrogen Peroxide	148-165	latexin	Homo sapiens	92-95	
28689095-6	2017	Results showed a strong efficacy of the tested compounds, even at the lower doses, in counteracting the induced oxidative stress (50 muM of H2O2) and in preventing ROS formation.	Hydrogen Peroxide	140-144	latexin	Homo sapiens	133-136	
28474898-5	2017	The amino-functionalized AIS QDs show high sensitivity and specificity for H2O2 and glucose with detection limits of 0.42 and 0.90 muM, respectively.	Hydrogen Peroxide	75-79	latexin	Homo sapiens	131-134	
28773209-9	2017	The measured catalysis currents increase linearly with the H2O2 concentration in a wide range of 25-350 muM with a correlation coefficient 0.99.	Hydrogen Peroxide	59-63	latexin	Homo sapiens	104-107	
28773209-12	2017	On the other hand, the magnetoelastic measurements show a small linear mass increase versus the H2O2 concentration with a slope of 152 ng/muM, which is probably due to H2O2 adsorption in ZnO during the electrochemical reaction.	Hydrogen Peroxide	96-100	latexin	Homo sapiens	138-141	
28773209-12	2017	On the other hand, the magnetoelastic measurements show a small linear mass increase versus the H2O2 concentration with a slope of 152 ng/muM, which is probably due to H2O2 adsorption in ZnO during the electrochemical reaction.	Hydrogen Peroxide	168-172	latexin	Homo sapiens	138-141	
29088826-5	2017	Our experiments demonstrated that, first, exposure to 100muM hydrogen peroxide decreased cell viability, DNA synthesis, mitochondrial respiration and antioxidant function, and increased apoptosis.	Hydrogen Peroxide	61-78	latexin	Homo sapiens	57-60	
28639653-4	2017	Under optimal conditions, it showed a speed of 420 mum s-1 in 2% H2O2 and even 51 mum s-1 in 0.25% H2O2.	Hydrogen Peroxide	65-69	latexin	Homo sapiens	51-54	
28639653-4	2017	Under optimal conditions, it showed a speed of 420 mum s-1 in 2% H2O2 and even 51 mum s-1 in 0.25% H2O2.	Hydrogen Peroxide	99-103	latexin	Homo sapiens	51-54	
28639653-4	2017	Under optimal conditions, it showed a speed of 420 mum s-1 in 2% H2O2 and even 51 mum s-1 in 0.25% H2O2.	Hydrogen Peroxide	99-103	latexin	Homo sapiens	82-85	
28474898-6	2017	A linear correlation was established between PL intensity and concentration of H2O2 in the ranges of 0.5-10 muM and 10-300 muM, while the linear ranges were 1-10 muM and 10-1000 muM for detection of glucose.	Hydrogen Peroxide	79-83	latexin	Homo sapiens	108-111	
28474898-6	2017	A linear correlation was established between PL intensity and concentration of H2O2 in the ranges of 0.5-10 muM and 10-300 muM, while the linear ranges were 1-10 muM and 10-1000 muM for detection of glucose.	Hydrogen Peroxide	79-83	latexin	Homo sapiens	123-126	
28474898-6	2017	A linear correlation was established between PL intensity and concentration of H2O2 in the ranges of 0.5-10 muM and 10-300 muM, while the linear ranges were 1-10 muM and 10-1000 muM for detection of glucose.	Hydrogen Peroxide	79-83	latexin	Homo sapiens	123-126	
28474898-6	2017	A linear correlation was established between PL intensity and concentration of H2O2 in the ranges of 0.5-10 muM and 10-300 muM, while the linear ranges were 1-10 muM and 10-1000 muM for detection of glucose.	Hydrogen Peroxide	79-83	latexin	Homo sapiens	123-126	
28160681-2	2017	The results show that the soluble iron in the investigated water samples was sufficiently effective for reaction with H2O2 in the simulated rainwater-affected stagnant water to produce OH (Fenton reaction), which inactivated coliform bacteria even at a H2O2 dose as low as 5 muM within just 1 min of contact time.	Hydrogen Peroxide	118-122	latexin	Homo sapiens	275-278	
28160681-5	2017	In the presence of H2O2 at a dose of 20 muM, Fenton-driven chemical oxidation appeared to outplay the impediment of biodegradation caused by inhibited microbial activities in terms of removing total polycyclic aromatic hydrocarbons from the water column.	Hydrogen Peroxide	19-23	latexin	Homo sapiens	40-43	
28503967-4	2017	Interestingly, pre-treatment of SH-SY5Y cells with 100 muM TD prevented cell death and suppressed intracellular ROS generation evoked by the addition of hydrogen peroxide (H2O2).	Hydrogen Peroxide	153-170	latexin	Homo sapiens	55-58	
28503967-4	2017	Interestingly, pre-treatment of SH-SY5Y cells with 100 muM TD prevented cell death and suppressed intracellular ROS generation evoked by the addition of hydrogen peroxide (H2O2).	Hydrogen Peroxide	172-176	latexin	Homo sapiens	55-58	
28248102-4	2017	Compounds 1-3, 6-8, 12, and 13 displayed significant effects against hydrogen peroxide-induced neurotoxicity in SH-SY5Y cells at 10 muM.	Hydrogen Peroxide	69-86	latexin	Homo sapiens	132-135	
28490955-2	2017	MTT assay showed that hydrogen peroxide treatment at a concentration of 100 muM caused a significant (p &lt; 0.005) reduction in the viability of MG63 cells.	Hydrogen Peroxide	22-39	latexin	Homo sapiens	76-79	
28490955-3	2017	However, reduction in cell viability caused by 100 muM concentration of hydrogen peroxide was completely prevented on incubation with 30 muM dose of dihydromyricetin.	Hydrogen Peroxide	72-89	latexin	Homo sapiens	51-54	
28490955-3	2017	However, reduction in cell viability caused by 100 muM concentration of hydrogen peroxide was completely prevented on incubation with 30 muM dose of dihydromyricetin.	Hydrogen Peroxide	72-89	latexin	Homo sapiens	137-140	
28490955-4	2017	Treatment with 100 muM concentration of hydrogen peroxide for 24 h led to condensation of chromatin material, rounding of cell shape and detachment of cells.	Hydrogen Peroxide	40-57	latexin	Homo sapiens	19-22	
28490955-5	2017	The results from flow cytometry using annexin V-FITC and PI double staining showed apoptosis induction in 47.84 +- 5.21% cells on treatment with 100 muM concentration of hydrogen peroxide compared to 2.32 +- 0.54% in controlcells.	Hydrogen Peroxide	170-187	latexin	Homo sapiens	149-152	
28490955-6	2017	The apoptotic alterations in MG63 cell morphology were prevented significantly on pre-treatment with 30 muM doses of dihydromyricetin for 48 h. Annexin V-FITC and PI staining showed reduction of hydrogen peroxide induced apoptotic cell percentage to 3.07 +- 0.86% on pre-treatment of MG63 cells with 30 muM dose of dihydromyricetin.	Hydrogen Peroxide	195-212	latexin	Homo sapiens	104-107	
28490955-6	2017	The apoptotic alterations in MG63 cell morphology were prevented significantly on pre-treatment with 30 muM doses of dihydromyricetin for 48 h. Annexin V-FITC and PI staining showed reduction of hydrogen peroxide induced apoptotic cell percentage to 3.07 +- 0.86% on pre-treatment of MG63 cells with 30 muM dose of dihydromyricetin.	Hydrogen Peroxide	195-212	latexin	Homo sapiens	303-306	
28490955-7	2017	Western blot analysis showed a significant increase in the activation of caspase-3 and -9 on treatment of MG63 cells for 24 h with 100 muM concentration of hydrogen peroxide.	Hydrogen Peroxide	156-173	latexin	Homo sapiens	135-138	
28490955-8	2017	The expression level of Bcl-2 was decreased significantly by 100 muM concentration of hydrogen peroxide in MG63 cells.	Hydrogen Peroxide	86-103	latexin	Homo sapiens	65-68	
28490955-9	2017	However, pre-treatment of MG63 cells with 30 muM dose of dihydromyricetin for 48 h significantly prevented hydrogen peroxide induced increase in caspase-3 and -9 levels and reduction in Bcl-2 level.	Hydrogen Peroxide	107-124	latexin	Homo sapiens	45-48	
27975200-3	2017	The results indicated that 265 nm UV/H2O2 treatment had a high removal efficiency of MC-LR ([MC-LR] = 0.1 muM, apparent rate constants reached 0.2077 min-1, half-time at 3.3 min).	Hydrogen Peroxide	37-41	latexin	Homo sapiens	106-109	
27254786-3	2016	The AuPd@GR nanohybrids exhibited excellent catalytic activity towards H2O2 detection with a wide detection range (5muM-11.5mM), high sensitivity (186.86muAmM(-1)cm(-2)), low limit of detection (1muM), fast response (3s), and long-term working stability (2500s).	Hydrogen Peroxide	71-75	latexin	Homo sapiens	116-119	
28452733-5	2017	The viability of Jurkat cells incubated for 24 hours under acquit oxidative stress conditions dose-depenently, monotonically decreased (irreversibly at 100 muM of H2O2 and reaches the 30% of intact Jurkat cells viability level at 50 muM of H2O2).	Hydrogen Peroxide	163-167	latexin	Homo sapiens	156-159	
28452733-5	2017	The viability of Jurkat cells incubated for 24 hours under acquit oxidative stress conditions dose-depenently, monotonically decreased (irreversibly at 100 muM of H2O2 and reaches the 30% of intact Jurkat cells viability level at 50 muM of H2O2).	Hydrogen Peroxide	163-167	latexin	Homo sapiens	233-236	
27866421-9	2017	DPBF responds to hydrogen peroxide in a very specific way with the limits of detection and quantitation of 88 and 122.8 muM, respectively.	Hydrogen Peroxide	17-34	latexin	Homo sapiens	120-123	
28118826-6	2017	Concentrations of NAC &gt;=1 muM reduced the pro-oxidant response (peroxidase activity, hydrogen peroxide, malondialdehyde, nitric oxide), and improved the anti-oxidant response (total anti-oxidant capacity, glutathione, superoxide dismutase) induced by LPS.	Hydrogen Peroxide	88-105	latexin	Homo sapiens	29-32	
27308956-4	2017	A preliminary bioassay revealed that compounds 3 and 7 exhibited significant protective effects against hydrogen peroxide-induced damage in human retinal endothelial cells (HRECs) with the concentration of 10 muM, respectively.	Hydrogen Peroxide	104-121	latexin	Homo sapiens	209-212	
27612728-4	2016	Amperometric study using ERGO/GCE showed high sensitivity (0.3muA/muM) and faster response upon the addition of H2O2 at an applied potential of -0.25V vs. Ag/AgCl.	Hydrogen Peroxide	112-116	latexin	Homo sapiens	66-69	
32263534-5	2016	Under optimum conditions, the HN-RGO/AuNP-modified electrode shows a wide linear response ranges from 0.05 muM to 518.15 muM towards H2O2 with a fast response time (3 s).	Hydrogen Peroxide	133-137	latexin	Homo sapiens	107-110	
32263534-5	2016	Under optimum conditions, the HN-RGO/AuNP-modified electrode shows a wide linear response ranges from 0.05 muM to 518.15 muM towards H2O2 with a fast response time (3 s).	Hydrogen Peroxide	133-137	latexin	Homo sapiens	121-124	
27556215-6	2016	Curcumin treatment at concentrations between 1 and 20 muM reduced the production of iROS in H2O2-exposed TM cells in a dose-dependent manner.	Hydrogen Peroxide	92-96	latexin	Homo sapiens	54-57	
27351826-5	2016	In this work we report that H2O2 at low doses (1 pM-1muM) exerts an inhibitory effect on TO901317-induced mRNA expression of LXRalpha and of its target genes encoding the ATP-binding cassette (ABC) transporters ABCA1 and ABCG1, and the sterol regulatory element-binding protein 1c (SREBP1c).	Hydrogen Peroxide	28-32	latexin	Homo sapiens	53-56	
26952442-5	2016	The sensitivity and detection limit for H2O2 at the operating potential of +0.35 V were 167 nA muM(-1)cm(-2) and 1.2 muM, respectively and better than those obtained at the operating potential of -0.25 V (68 nA muM(-1)cm(-2) and 14 muM).	Hydrogen Peroxide	40-44	latexin	Homo sapiens	95-98	
26916736-8	2016	The high performance was indicated by some of the key parameters, for example the linear H2O2 concentration response range (1-30 muM), the detection limit (100 nM), and the high amperometric sensitivity (5 A cm(-2) M(-1)).	Hydrogen Peroxide	89-93	latexin	Homo sapiens	129-132	
26952442-5	2016	The sensitivity and detection limit for H2O2 at the operating potential of +0.35 V were 167 nA muM(-1)cm(-2) and 1.2 muM, respectively and better than those obtained at the operating potential of -0.25 V (68 nA muM(-1)cm(-2) and 14 muM).	Hydrogen Peroxide	40-44	latexin	Homo sapiens	117-120	
27110794-5	2016	Under the optimal reaction conditions, the resulting sensor displayed a good response to H2O2 with a linear range of 1 to 500 muM, and a detection limit of 1 muM at a signal-to-noise ratio of 3.	Hydrogen Peroxide	89-93	latexin	Homo sapiens	126-129	
26804444-3	2016	Exposure of cells to glutamate (60-80 mM) or H2O2 (200-300 muM) for 24 h decreased cellular viability and increased dichlorofluorescein (DCF) fluorescence (indicative of increased reactive oxygen species, ROS) and nitric oxide (NO) production (assessed by mono-nitrogen oxides, NOx, levels).	Hydrogen Peroxide	45-49	latexin	Homo sapiens	59-62	
26804444-4	2016	Creatine (1-10 mM) or MK-801 (0.1-10 muM) reduced glutamate- and H2O2-induced toxicity.	Hydrogen Peroxide	65-69	latexin	Homo sapiens	37-40	
27110794-5	2016	Under the optimal reaction conditions, the resulting sensor displayed a good response to H2O2 with a linear range of 1 to 500 muM, and a detection limit of 1 muM at a signal-to-noise ratio of 3.	Hydrogen Peroxide	89-93	latexin	Homo sapiens	158-161	
26830534-4	2016	The mechanism likely involves inhibition of catalase activity by nitrite (IC50, 9 muM), which allows H2O2 to accumulate and oxidize Cys moieties of oxyhemoglobin and erythrocytic GSH to form HbSSG in addition to GSSG.	Hydrogen Peroxide	101-105	latexin	Homo sapiens	82-85	
27019266-6	2016	The retinoic acid differentiated SH-S cell line (10 muM) shows a clear apoptosis when treated with H2O2 150 muM, with a Bax/Bcl-2 ratio of 3.75 (SD 0.80) in contrast to the differentiated control cells subjected to H2O2 and with extract, which have the same ratio of 1.02 (SD 0.01-0.03).	Hydrogen Peroxide	99-103	latexin	Homo sapiens	52-55	
26593482-1	2016	Three nationally prominent commercial powdered infant formulas generated hydrogen peroxide, ranging from 10.46 to 11.62 muM, when prepared according to the manufacturer"s instructions.	Hydrogen Peroxide	73-90	latexin	Homo sapiens	120-123	
27019266-6	2016	The retinoic acid differentiated SH-S cell line (10 muM) shows a clear apoptosis when treated with H2O2 150 muM, with a Bax/Bcl-2 ratio of 3.75 (SD 0.80) in contrast to the differentiated control cells subjected to H2O2 and with extract, which have the same ratio of 1.02 (SD 0.01-0.03).	Hydrogen Peroxide	99-103	latexin	Homo sapiens	108-111	
26511954-7	2016	The absorption of PDA-PBA at 650 nm is linearly related to the concentration of H2O2 and a detection limit of ~5 muM could be achieved.	Hydrogen Peroxide	80-84	latexin	Homo sapiens	113-116	
26745155-5	2016	H2O2 induced a significant decrease in rate constant for SO4= uptake at both 100 and 300 muM H2O2.	Hydrogen Peroxide	0-4	latexin	Homo sapiens	89-92	
26745155-5	2016	H2O2 induced a significant decrease in rate constant for SO4= uptake at both 100 and 300 muM H2O2.	Hydrogen Peroxide	93-97	latexin	Homo sapiens	89-92	
26362642-2	2016	In this study, a simulated experiment was conducted to examine the effects of hydrogen peroxide (at a concentration range of 5-50 muM) on the abiotic oxidation of arsenopyrite cubes.	Hydrogen Peroxide	78-95	latexin	Homo sapiens	130-133	
26770658-4	2016	Experiment 2 was designed to study a high (50 muM) and low dose (12.5 muM) of H2O2 compared to a control (0 muM).	Hydrogen Peroxide	78-82	latexin	Homo sapiens	70-73	
26770658-4	2016	Experiment 2 was designed to study a high (50 muM) and low dose (12.5 muM) of H2O2 compared to a control (0 muM).	Hydrogen Peroxide	78-82	latexin	Homo sapiens	70-73	
26605980-8	2015	Multiple experimental approaches showed that exposure to 1,2-NQ at concentrations as low as 3 muM induces H2O2-dependent protein sulfenylation in BEAS-2B cells.	Hydrogen Peroxide	106-110	latexin	Homo sapiens	94-97	
26581173-10	2015	H2O2 was higher in patients with ARDS, compared to controls (0.09 (0.06-0.12) muM versus 0.03 (0.01-0.09) muM, p  =  0.043), while no difference was found in proteins content, 8-isoprostane, 4-hydroxy-2-nonhenal.	Hydrogen Peroxide	0-4	latexin	Homo sapiens	78-81	
26514845-4	2015	Using CuNCs as probes, H2O2 was determined in the range from 1 muM to 50 muM based on a linear decrease of fluorescence intensity as well as a detection limit of 0.2 muM with a signal-to-noise ratio of 3.	Hydrogen Peroxide	23-27	latexin	Homo sapiens	63-66	
26514845-4	2015	Using CuNCs as probes, H2O2 was determined in the range from 1 muM to 50 muM based on a linear decrease of fluorescence intensity as well as a detection limit of 0.2 muM with a signal-to-noise ratio of 3.	Hydrogen Peroxide	23-27	latexin	Homo sapiens	73-76	
26514845-4	2015	Using CuNCs as probes, H2O2 was determined in the range from 1 muM to 50 muM based on a linear decrease of fluorescence intensity as well as a detection limit of 0.2 muM with a signal-to-noise ratio of 3.	Hydrogen Peroxide	23-27	latexin	Homo sapiens	73-76	
26581173-10	2015	H2O2 was higher in patients with ARDS, compared to controls (0.09 (0.06-0.12) muM versus 0.03 (0.01-0.09) muM, p  =  0.043), while no difference was found in proteins content, 8-isoprostane, 4-hydroxy-2-nonhenal.	Hydrogen Peroxide	0-4	latexin	Homo sapiens	106-109	
26249610-3	2015	The resulting sensor exhibited a good response to hydrogen peroxide over linear range from 0.2 to 60.0muM with a limit of detection of 0.08muM, good reproducibility, long-term stability and negligible interference from ascorbic acid, uric acid and dopamine.	Hydrogen Peroxide	50-67	latexin	Homo sapiens	102-105	
26535076-4	2015	Although H2O2 (200 muM) increased intracellular ROS levels in human MSCs, lycopene (10 muM) pretreatment suppressed H2O2-induced ROS generation and increased survival.	Hydrogen Peroxide	116-120	latexin	Homo sapiens	87-90	
26469539-4	2015	The resulting biosensor showed good electrochemical activity toward the reduction of H2O2 with low detection limit down to 1 muM (S/N = 3) and wide linear detection ranging from 0.01 mM to 3.5 mM (R(2) = 0.990).	Hydrogen Peroxide	85-89	latexin	Homo sapiens	125-128	
26003691-3	2015	The CQDs have an average size of 3.6 nm in diameter with narrow size distribution, and can be used as highly selective and sensitive fluorescence probes for hydrogen peroxide and glucose, with limits of detection of 3.8 muM and 3.5 muM, respectively.	Hydrogen Peroxide	157-174	latexin	Homo sapiens	232-235	
26399738-10	2015	The detecting limit for H2O2 was estimated at 2.9 and 5.0 muM in vitro and in cultured cells, respectively.	Hydrogen Peroxide	24-28	latexin	Homo sapiens	58-61	
32262645-7	2015	The fluorescence quenching of MCPs@GNR can be achieved by addition of H2O2 which shows linearity over a range of increasing concentration of 10 muM to 150 muM.	Hydrogen Peroxide	70-74	latexin	Homo sapiens	144-147	
32262645-7	2015	The fluorescence quenching of MCPs@GNR can be achieved by addition of H2O2 which shows linearity over a range of increasing concentration of 10 muM to 150 muM.	Hydrogen Peroxide	70-74	latexin	Homo sapiens	155-158	
25818356-4	2015	The proposed PdCo/CNF-based biosensor showed excellent analytical performances toward hydrogen peroxide (detection limit: 0.1 muM; linear range: 0.2 muM-23.5 mM) and nitrite (detection limit: 0.2 muM; linear range: 0.4-30 muM and 30-400 muM).	Hydrogen Peroxide	86-103	latexin	Homo sapiens	126-129	
26213787-4	2015	The optimized ECL imaging system showed that hydrogen peroxide as low as 10 muM was visible and the efflux of hydrogen peroxide from cells could be determined.	Hydrogen Peroxide	45-62	latexin	Homo sapiens	76-79	
26225726-4	2015	Under optimal conditions, the resulting biosensor displayed a good response for H2O2 with a linear range of 0.2 to 12.8 mM, and a detection limit of 7.8 muM at a signal-to-noise ratio of 3.	Hydrogen Peroxide	80-84	latexin	Homo sapiens	153-156	
25818356-4	2015	The proposed PdCo/CNF-based biosensor showed excellent analytical performances toward hydrogen peroxide (detection limit: 0.1 muM; linear range: 0.2 muM-23.5 mM) and nitrite (detection limit: 0.2 muM; linear range: 0.4-30 muM and 30-400 muM).	Hydrogen Peroxide	86-103	latexin	Homo sapiens	149-152	
25818356-4	2015	The proposed PdCo/CNF-based biosensor showed excellent analytical performances toward hydrogen peroxide (detection limit: 0.1 muM; linear range: 0.2 muM-23.5 mM) and nitrite (detection limit: 0.2 muM; linear range: 0.4-30 muM and 30-400 muM).	Hydrogen Peroxide	86-103	latexin	Homo sapiens	149-152	
25818356-4	2015	The proposed PdCo/CNF-based biosensor showed excellent analytical performances toward hydrogen peroxide (detection limit: 0.1 muM; linear range: 0.2 muM-23.5 mM) and nitrite (detection limit: 0.2 muM; linear range: 0.4-30 muM and 30-400 muM).	Hydrogen Peroxide	86-103	latexin	Homo sapiens	149-152	
25818356-4	2015	The proposed PdCo/CNF-based biosensor showed excellent analytical performances toward hydrogen peroxide (detection limit: 0.1 muM; linear range: 0.2 muM-23.5 mM) and nitrite (detection limit: 0.2 muM; linear range: 0.4-30 muM and 30-400 muM).	Hydrogen Peroxide	86-103	latexin	Homo sapiens	149-152	
25774435-8	2015	On the basis of the high activity of CeO2/nanotube-TiO2, the reaction provides a simple method for colorimetric detection of H2O2 and glucose with the detection limits of 3.2 and 6.1 muM, respectively.	Hydrogen Peroxide	125-129	latexin	Homo sapiens	183-186	
32262292-4	2015	With such a process, as low as 68 nM H2O2 could be detected with a linear range from 0.1 to 100 muM.	Hydrogen Peroxide	37-41	latexin	Homo sapiens	96-99	
25868604-6	2015	The approach achieves a low detection limit of 0.1 muM for H2O2.	Hydrogen Peroxide	59-63	latexin	Homo sapiens	51-54	
25660330-13	2015	Treatment with 20 muM also elevated GR activity after in vitro incubation at 37 C. Electrophoretic profiles revealed that incubation with ibogaine mitigates H2O2 mediated suppression of SOD1 activity.	Hydrogen Peroxide	157-161	latexin	Homo sapiens	18-21	
32262778-4	2015	The bi-directional sensor showed a linear range from 0.05 muM to 17.5 mM with a detection limit of 0.02 muM (S/N = 3) at an applied potential of +0.5 V and a linear range from 0.5 muM to 110 mM with a detection limit of 0.25 muM (S/N = 3) at an applied potential of -0.3 V. The proposed sensor was tested to determine H2O2 released from living cells and shows good application potential in biological electrochemistry.	Hydrogen Peroxide	318-322	latexin	Homo sapiens	58-61	
32262778-4	2015	The bi-directional sensor showed a linear range from 0.05 muM to 17.5 mM with a detection limit of 0.02 muM (S/N = 3) at an applied potential of +0.5 V and a linear range from 0.5 muM to 110 mM with a detection limit of 0.25 muM (S/N = 3) at an applied potential of -0.3 V. The proposed sensor was tested to determine H2O2 released from living cells and shows good application potential in biological electrochemistry.	Hydrogen Peroxide	318-322	latexin	Homo sapiens	104-107	
32262778-4	2015	The bi-directional sensor showed a linear range from 0.05 muM to 17.5 mM with a detection limit of 0.02 muM (S/N = 3) at an applied potential of +0.5 V and a linear range from 0.5 muM to 110 mM with a detection limit of 0.25 muM (S/N = 3) at an applied potential of -0.3 V. The proposed sensor was tested to determine H2O2 released from living cells and shows good application potential in biological electrochemistry.	Hydrogen Peroxide	318-322	latexin	Homo sapiens	104-107	
32262778-4	2015	The bi-directional sensor showed a linear range from 0.05 muM to 17.5 mM with a detection limit of 0.02 muM (S/N = 3) at an applied potential of +0.5 V and a linear range from 0.5 muM to 110 mM with a detection limit of 0.25 muM (S/N = 3) at an applied potential of -0.3 V. The proposed sensor was tested to determine H2O2 released from living cells and shows good application potential in biological electrochemistry.	Hydrogen Peroxide	318-322	latexin	Homo sapiens	104-107	
25818144-4	2015	The linearity between the analyte concentration and absorption ranged from 20 to 1170 muM for H2O2 and 25 to 375 muM for glucose with a detection limit of 5.3 muM for H2O2 and 16 muM for glucose.	Hydrogen Peroxide	94-98	latexin	Homo sapiens	86-89	
25818144-4	2015	The linearity between the analyte concentration and absorption ranged from 20 to 1170 muM for H2O2 and 25 to 375 muM for glucose with a detection limit of 5.3 muM for H2O2 and 16 muM for glucose.	Hydrogen Peroxide	167-171	latexin	Homo sapiens	113-116	
25818144-4	2015	The linearity between the analyte concentration and absorption ranged from 20 to 1170 muM for H2O2 and 25 to 375 muM for glucose with a detection limit of 5.3 muM for H2O2 and 16 muM for glucose.	Hydrogen Peroxide	167-171	latexin	Homo sapiens	113-116	
25818144-4	2015	The linearity between the analyte concentration and absorption ranged from 20 to 1170 muM for H2O2 and 25 to 375 muM for glucose with a detection limit of 5.3 muM for H2O2 and 16 muM for glucose.	Hydrogen Peroxide	167-171	latexin	Homo sapiens	113-116	
25688934-5	2015	Cytochrome C-functionalized electrodes prepared using the induced dual nanoelectrospray process showed bioactivity toward aqueous solutions of hydrogen peroxide below 50 muM.	Hydrogen Peroxide	143-160	latexin	Homo sapiens	170-173	
25262340-4	2015	It was determined at the characterization studies on the biosensor that linear results are obtained between the ranges of 0.1muM to 70.0muM for H2O2 concentration and 1-250muM for NO2(-).	Hydrogen Peroxide	144-148	latexin	Homo sapiens	125-128	
25588103-4	2015	After pretreatment at the concentrations of 5 and 10 muM, oxyresveratrol increased cell viability, exhibited significant suppressions on UVA- or H2O2-induced cellular ROS.	Hydrogen Peroxide	145-149	latexin	Homo sapiens	53-56	
25686273-8	2015	The result indicated that 23 and 24 significantly inhibited H2O2-induced decrease of the cell mitochondrial membrane potential (DeltaPsim) at 25 muM.	Hydrogen Peroxide	60-64	latexin	Homo sapiens	145-148	
25611970-7	2015	H2O2 is thus consumed in a catalytic cycle and leads to less efficient HOBr scavenging at even low iodide concentrations (&lt;1 muM).	Hydrogen Peroxide	0-4	latexin	Homo sapiens	128-131	
32264480-8	2015	The lowest detection limits for H2O2 and glucose were 0.6 nM and 0.6 muM, respectively.	Hydrogen Peroxide	32-36	latexin	Homo sapiens	69-72	
25447319-1	2015	A new nano contrast agent has been prepared incorporating a molecular magnet in oxidation-responsive nanoparticles; this system has shown a remarkable sensitivity to hydrogen peroxide (detection down to at least 40 muM), which was used as a model reactive oxygen species.	Hydrogen Peroxide	166-183	latexin	Homo sapiens	215-218	
25527723-7	2015	We showed that the linear detection range for H2O2-induced DNA damage in human lymphoblastoid cells is between 30 and 100 muM, and that within this range, inter-sample coefficient of variance was between 5 and 10%.	Hydrogen Peroxide	46-50	latexin	Homo sapiens	122-125	
25269106-5	2014	The rate of superoxide anion radical (O2(-)) production under Fe(III)-oxalate/H2O2/UV (350 nm) was 0.19 +- 0.02 muM/min with a steady-state concentration of 5.43 +- 0.473 x 10(-10) M. Detailed product studies using liquid chromatography coupled to Q-TOF/MS demonstrate both reduction (multiple dehalogenations) and oxidation (aromatic ring and side chains) contribute to the degradation pathways.	Hydrogen Peroxide	78-82	latexin	Homo sapiens	112-115	
25390796-8	2014	With optimal conditions, the approach achieves a low detection limit of 0.10 muM for H2O2.	Hydrogen Peroxide	85-89	latexin	Homo sapiens	77-80	
25326781-3	2014	Zinc carnosine at the concentration 16 muM was optimal in protecting cells from hydrogen peroxide-induced cytotoxicity and gave the lowest percentage of apoptotic and necrotic cells.	Hydrogen Peroxide	80-97	latexin	Homo sapiens	39-42	
25326781-4	2014	Results showed that zinc carnosine was able to induce glutathione production and protect cells from hydrogen peroxide-induced oxidative stress at all concentration and the highest protection was observed at 32-muM zinc carnosine culture.	Hydrogen Peroxide	100-117	latexin	Homo sapiens	210-213	
25326781-5	2014	Cytokinesis-block micronucleus cytome assay showed that cells cultured with 4-32 muM of zinc carnosine showed significant reduction in micronuclei formation, nucleoplasmic bridges and nuclear bud frequencies (p &lt; 0.05), suggesting that these concentrations maybe optimal in protecting cells from hydrogen peroxide-induced DNA damage.	Hydrogen Peroxide	299-316	latexin	Homo sapiens	81-84	
25196578-5	2014	The detecting limit of NP1 toward H2O2 is estimated as 0.17 muM.	Hydrogen Peroxide	34-38	latexin	Homo sapiens	60-63	
25123289-8	2014	In cultured human umbilical vein endothelial cells (HUVECs), 1 muM metformin reversed AGE-induced increase of ROS and attenuated AGE- and H2O2- induced downregulation of IKCa and SKCa after long-term incubation (&gt;24 hours).	Hydrogen Peroxide	138-142	latexin	Homo sapiens	63-66	
24887508-5	2014	The developed sensor gave a linear response over a wide concentration range of H2O2 (0.68-78.6 muM).	Hydrogen Peroxide	79-83	latexin	Homo sapiens	95-98	
24857484-6	2014	The detection limit (S/N=3) for H2O2 was about 1 muM.	Hydrogen Peroxide	32-36	latexin	Homo sapiens	49-52	
32261860-7	2014	A linear relationship between the anodic current and [H2O2] allows quantitative determination of the latter with a detection limit and sensitivity of 5 muM and 0.7 muA muM-1, respectively.	Hydrogen Peroxide	54-58	latexin	Homo sapiens	152-155	
32261661-3	2014	The as-made NP-PdCr alloy exhibits high sensing performance toward H2O2, such as a wide linear range from 0.1 to 1.9 mM, fast amperometric response, and a low detection limit of 3.1 muM.	Hydrogen Peroxide	67-71	latexin	Homo sapiens	182-185	
24995368-2	2014	It was corroborated that changes in the concentration of hydrogen peroxide as small as 0.05 muM could lead to nanoparticle solutions of completely different tonality.	Hydrogen Peroxide	57-74	latexin	Homo sapiens	92-95	
25033439-5	2014	In Cu(I)-H2O2 system (Fenton reaction conditions) BTPA compounds 6, 8, and 10 (NCH2Ph) were identified as most potent antioxidants (IC50 32, 56, and 29 muM, respectively), whereas BOPA analogues 7, 9 (NEt), and 11 (NCH2Ph) were found to be poor antioxidants.	Hydrogen Peroxide	9-13	latexin	Homo sapiens	152-155	
25033439-6	2014	In Fe(II)-H2O2 system, IC50 values for both BTPA and BOPA compounds exceeded 500 muM indicating high selectivity to Cu(I) versus the borderline Fe(II)-ion.	Hydrogen Peroxide	10-14	latexin	Homo sapiens	81-84	
24388509-8	2014	Impact of exogenous nitric oxide donor (sodium nitroprusside/SNP) was therefore tested and results showed amelioration of 1000 muM Mn-induced oxidative stress in seedlings (decrease in H2O2 and increase in NO content while antioxidative enzyme activities were variably affected) concomitantly with depleted Mn accumulation.	Hydrogen Peroxide	185-189	latexin	Homo sapiens	127-130	
24890692-4	2014	In addition, NP-PdFe performs high sensing performance towards H2O2 in a wide linear range from 0.5 to 6 mM with a low detection limit of 2.1 muM.	Hydrogen Peroxide	63-67	latexin	Homo sapiens	142-145	
24315179-1	2014	A microcosm experiment was conducted to examine the effects of hydrogen peroxide (at a concentration range of 5-50 muM) on the release of arsenic from the dissolution of arsenopyrite, a dominant arsenic-bearing mineral occurring in natural environments.	Hydrogen Peroxide	63-80	latexin	Homo sapiens	115-118	
24410662-2	2014	We found that electron paramagnetic resonance (EPR)-monitored inhibition of OH radicals production from H2O2, in an Fe(2+)-H2O2 system, by bisphosphate derivatives 1, 3, and 5 (IC50 = 36, 24, and 40 muM, respectively), was more effective than it was by ethylenediaminetetraacetic acid (EDTA), by a factor of 1.5, 2, and 1.4, respectively.	Hydrogen Peroxide	104-108	latexin	Homo sapiens	199-202	
24615460-7	2014	The spiky Pt nanosphere decorated G/S film was directly used as a H2O2 electrode with a sensitivity of 0.56 mA mM(-1) cm(-2), a linear range of 0-2.5 mM and an ultralow detection limit of 0.2 muM (S/N = 3).	Hydrogen Peroxide	66-70	latexin	Homo sapiens	192-195	
24512566-4	2014	The prepared PtCu NC electrode exhibited excellent electrocatalytic activity towards H2O2, with a wide liner range from 5 muM to 22.25 mM, a relatively high sensitivity of 295.3 muA mM-1 cm-2, and a low detection limit of 5 muM (S/N = 3).	Hydrogen Peroxide	85-89	latexin	Homo sapiens	122-125	
24512566-4	2014	The prepared PtCu NC electrode exhibited excellent electrocatalytic activity towards H2O2, with a wide liner range from 5 muM to 22.25 mM, a relatively high sensitivity of 295.3 muA mM-1 cm-2, and a low detection limit of 5 muM (S/N = 3).	Hydrogen Peroxide	85-89	latexin	Homo sapiens	224-227	
32261329-5	2013	The fabricated H2O2 biosensor reveals a wide linear range from 0.25 to 22.5 mM, low detection limit of 6.2 muM (S/N = 3), high selectivity, and long-term stability.	Hydrogen Peroxide	15-19	latexin	Homo sapiens	107-110	
24055680-6	2014	Under the optimized experimental conditions, the linear ranges for H2O2 and glucose are 0.5-10 muM and 10-100 muM, respectively.	Hydrogen Peroxide	67-71	latexin	Homo sapiens	95-98	
24055680-6	2014	Under the optimized experimental conditions, the linear ranges for H2O2 and glucose are 0.5-10 muM and 10-100 muM, respectively.	Hydrogen Peroxide	67-71	latexin	Homo sapiens	110-113	
24055680-7	2014	And the detection limits for H2O2 and glucose are 0.4 and 8 muM, respectively.	Hydrogen Peroxide	29-33	latexin	Homo sapiens	60-63	
24602819-5	2014	In cultured fibroblasts taken from human skin, hydrogen peroxide (100-1000 muM) damaged 62-92% of the cells compared to only 35-47% when the cells were preincubated in extract (200 mug/ml) for 24 h. UVA (40 J/cm2) irradiation of human fibroblasts damaged 25% of the cells but the death rate was reduced to 10% with extract.	Hydrogen Peroxide	47-64	latexin	Homo sapiens	75-78	
23787095-7	2013	Moreover, the resulting electrode exhibited excellent electrocatalytic ability towards the reduction of hydrogen peroxide (H2O2) with the linear dynamic range of 2.0-225.0 muM.	Hydrogen Peroxide	104-121	latexin	Homo sapiens	172-175	
23787095-7	2013	Moreover, the resulting electrode exhibited excellent electrocatalytic ability towards the reduction of hydrogen peroxide (H2O2) with the linear dynamic range of 2.0-225.0 muM.	Hydrogen Peroxide	123-127	latexin	Homo sapiens	172-175	
23712505-5	2013	SIPS was established by exposure to H2 O2 at a subcytotoxic concentration of 20 muM for two weeks.	Hydrogen Peroxide	36-41	latexin	Homo sapiens	80-83	
23868495-5	2013	As a proof-of-concept demonstration, we investigate its use in high-performance supercapacitors (~392 F g(-1)), and for sensitive detection of H2O2 (with a low detection limit of ~0.1 muM) and methanol (with a low detection limit of ~60 muM).	Hydrogen Peroxide	143-147	latexin	Homo sapiens	184-187	
23817786-6	2013	Relative CL intensity is linearly related to the concentration of H2O2 in the range from 0.01 to 50 muM.	Hydrogen Peroxide	66-70	latexin	Homo sapiens	100-103	
24090008-6	2013	Antioxidant activity was evaluated through exposing the cells to sub-lethal extract concentrations for 24 hours and then to oxidative stress induced by 60 muM arachidonic acid and 50 muM H2O2.	Hydrogen Peroxide	187-191	latexin	Homo sapiens	183-186	
32261076-6	2013	Under an optimal experimental condition, the created biosensor for detecting hydrogen peroxide has a sensitivity of 160.6 muA mM-1 cm-2, a wide linear range from 0.5 to 30 mM and a detection limit of 18.6 muM (S/N = 3), which indicates that this novel and simple strategy for fabricating electrochemical sensor by an electrospinning technique has wide potential applications in bio-analysis and detection.	Hydrogen Peroxide	77-94	latexin	Homo sapiens	205-208	
32260935-7	2013	The detection limit was estimated to be 0.6 muM at a signal/noise (S/N) ratio of 3, and the linear range of H2O2 concentration was from 1 muM to 1100 muM.	Hydrogen Peroxide	108-112	latexin	Homo sapiens	138-141	
32260935-7	2013	The detection limit was estimated to be 0.6 muM at a signal/noise (S/N) ratio of 3, and the linear range of H2O2 concentration was from 1 muM to 1100 muM.	Hydrogen Peroxide	108-112	latexin	Homo sapiens	138-141	
23333646-8	2013	A linear increase in the catalytic current is observed for the reduction of hydrogen peroxide in the concentration range from 1 to 20 muM, with a detection limit of 0.4 muM.	Hydrogen Peroxide	76-93	latexin	Homo sapiens	134-137	
23333646-8	2013	A linear increase in the catalytic current is observed for the reduction of hydrogen peroxide in the concentration range from 1 to 20 muM, with a detection limit of 0.4 muM.	Hydrogen Peroxide	76-93	latexin	Homo sapiens	169-172	
23154514-6	2013	Under the optimized conditions, the H(2)O(2) sensor exhibited a low detection limit down to 33.9 nM with a wide linear range from 0.05 to 1000 muM.	Hydrogen Peroxide	36-44	latexin	Homo sapiens	143-146	
32260780-11	2013	Its electrochemical response shows the linear dependence of hydrogen peroxide concentration in a range between 10 muM and 80 muM with a detection limit of 0.1 muM.	Hydrogen Peroxide	60-77	latexin	Homo sapiens	114-117	
32260780-11	2013	Its electrochemical response shows the linear dependence of hydrogen peroxide concentration in a range between 10 muM and 80 muM with a detection limit of 0.1 muM.	Hydrogen Peroxide	60-77	latexin	Homo sapiens	125-128	
32260780-11	2013	Its electrochemical response shows the linear dependence of hydrogen peroxide concentration in a range between 10 muM and 80 muM with a detection limit of 0.1 muM.	Hydrogen Peroxide	60-77	latexin	Homo sapiens	125-128	
23313413-1	2013	At optimal NADH concentration (50muM), the complex I-mediated process results in a formation of two superoxide anions and H(2)O(2) as the reaction products in approximately 0.7 ratio.	Hydrogen Peroxide	122-130	latexin	Homo sapiens	33-36	
23849871-5	2013	By varying the glucose oxidase concentration in the medium, target ranges of steady-state H2O2 concentrations (30-90 muM) can be attained for up to 6h, with subsequent assessment of cellular signaling and glucose transport activity.	Hydrogen Peroxide	90-94	latexin	Homo sapiens	117-120	
21645672-3	2011	The PB-graphene/GCE showed sensitive response to H(2)O(2) with a wide linear range of 10-1440 muM at 0.0V, and to hydrazine with a wide linear range of 10-3000 muM at 0.35 V. The detection limit was 3 muM and 7 muM, respectively, and both of them had rapid response within 5s to reach 95% steady state response.	Hydrogen Peroxide	49-57	latexin	Homo sapiens	94-97	
22949159-5	2012	Additionally, electrochemical pretreatment of platinum working electrodes aiming at surface oxidation improves the limit of detection of the sensor and the linearity of the calibration curve at low H2O2 concentrations (&lt;10 muM).	Hydrogen Peroxide	198-202	latexin	Homo sapiens	226-229	
25683399-6	2012	Using siRNA to knock down TrxR-1 or Nrf2, sulforaphane (5 muM)-protected cell viability was reduced from 73% to 46% and 34%, respectively, suggesting that TrxR-1 is an important enzyme in protection against hydrogen peroxide-induced cell death.	Hydrogen Peroxide	207-224	latexin	Homo sapiens	58-61	
21663493-4	2011	METHODS: Human retinal D407 RPE cells were pretreated with resveratrol at 3 different concentrations (25, 50, and 100 muM) for 24 h and exposed for 1 h to 500 muM hydrogen peroxide.	Hydrogen Peroxide	163-180	latexin	Homo sapiens	159-162	
25486783-8	2013	While a sub-lethal H2O2 dose (200 muM) promoted in hMESC only SIPS, the higher H2O2 doses induced also apoptosis in the part of the cell population.	Hydrogen Peroxide	19-23	latexin	Homo sapiens	34-37	
25486783-9	2013	On the contrary, in hESC, H2O2 regardless of the doses tested (from 50 to 500 muM) triggered apoptosis, that was the only pronounced response of these cells to oxidative damage.	Hydrogen Peroxide	26-30	latexin	Homo sapiens	78-81	
22716478-6	2012	Amperometric determination of H2O2 at -0.55 V gave a limit of detection of 1.6 muM (S / N = 3) and a sensitivity of 19.29 mA cm-2 M-1 up to 6 mM, with a response time (steady state, t95) of 30 to 40 s. Energy dispersive X-ray analysis, transmission electron microscopic image, cyclic voltammetry (CV), and scanning electron microscopic images were utilized to characterize the modified electrode.	Hydrogen Peroxide	30-34	latexin	Homo sapiens	79-82	
22200560-10	2012	Melatonin also has significant neuroprotective effects, reversing the inhibition of neuritogenesis by 200 and 500 muM hydrogen peroxide.	Hydrogen Peroxide	118-135	latexin	Homo sapiens	114-117	
22276528-6	2012	This reagentless biosensing approach was capable of detecting H(2)O(2), a simple molecule but plays an important role in analytical and biological chemistry, as low as 0.1 muM with linearity of 0.1-60 muM and a response time of &lt;0.8 s, comparing favorably with other carbon based electrodes (5 s).	Hydrogen Peroxide	62-70	latexin	Homo sapiens	172-175	
22276528-6	2012	This reagentless biosensing approach was capable of detecting H(2)O(2), a simple molecule but plays an important role in analytical and biological chemistry, as low as 0.1 muM with linearity of 0.1-60 muM and a response time of &lt;0.8 s, comparing favorably with other carbon based electrodes (5 s).	Hydrogen Peroxide	62-70	latexin	Homo sapiens	201-204	
22138566-2	2012	We evaluated DNA damage induced by treatment with hydrogen peroxide (H(2)O(2); 5, 25 and 50muM) and methyl methane sulfonate (MMS; 5, 25 and 50muM) in both human B- and T-lymphocytes obtained by MACS, and compared their DNA damage levels.	Hydrogen Peroxide	50-67	latexin	Homo sapiens	91-94	
22002943-11	2012	For all assays performed with 33 muM Mn(2+), the initial rate of the decolorization process was found to be dependent on the dosage of H(2)O(2).	Hydrogen Peroxide	135-143	latexin	Homo sapiens	33-36	
21075044-1	2011	Redox cycling compounds (RCCs) generate muM concentrations of hydrogen peroxide (H(2)O(2)) in the presence of strong reducing agents, common buffer components used to maintain the catalytic activity and/or folding of target proteins for high throughput screening (HTS) assays.	Hydrogen Peroxide	62-79	latexin	Homo sapiens	40-43	
21172384-6	2011	In vitro, 250 muM H2O2 was treated to SH-SY5Y cells after the pre-treatment of SP-8203 (2, 20 and 200 muM).	Hydrogen Peroxide	18-22	latexin	Homo sapiens	14-17	
21172384-6	2011	In vitro, 250 muM H2O2 was treated to SH-SY5Y cells after the pre-treatment of SP-8203 (2, 20 and 200 muM).	Hydrogen Peroxide	18-22	latexin	Homo sapiens	102-105	
21595444-4	2011	Moreover, release of cargo has been enzymatically driven by oxidoreductase enzymes such as chloroperoxidase and myeloperoxidase in the presence of low concentrations of sodium chloride (200 mM) and hydrogen peroxide (500 muM).	Hydrogen Peroxide	198-215	latexin	Homo sapiens	221-224	
21286651-3	2011	In the Cu(I)/H(2)O(2) system, selenocystine, selenomethionine, and methyl-selenocysteine inhibit DNA damage with IC(50) values ranging from 3.34 to 25.1 muM.	Hydrogen Peroxide	13-21	latexin	Homo sapiens	153-156	
21047171-4	2011	When cells were challenged with hydrogen peroxide (H(2)O(2)), following mitoQ treatment (0.1-1.0 muM), the ratio of reduced to oxidized forms of glutathione increased, the levels of oxidative DNA damage decreased and there was an increase in the mitochondrial membrane potential.	Hydrogen Peroxide	32-49	latexin	Homo sapiens	97-100	
21255447-5	2011	Cell death of nef-expressing astrocytes exposed to 10 muM hydrogen peroxide for 30 min occurred within 4 h. CONCLUSION: HIV-1 Nef may contribute to neuronal dysfunction and the development of HAD by causing death of astrocytes through decreasing their tolerance for hydrogen peroxide.	Hydrogen Peroxide	58-75	latexin	Homo sapiens	54-57	
21255447-5	2011	Cell death of nef-expressing astrocytes exposed to 10 muM hydrogen peroxide for 30 min occurred within 4 h. CONCLUSION: HIV-1 Nef may contribute to neuronal dysfunction and the development of HAD by causing death of astrocytes through decreasing their tolerance for hydrogen peroxide.	Hydrogen Peroxide	266-283	latexin	Homo sapiens	54-57	
21063685-10	2011	L-NBP treatment at dose of 10 muM inhibited H2O2-induced down-regulation of Bcl-2, Bcl-w, and PKCalpha but also attenuated the overexpression of Bax.	Hydrogen Peroxide	44-48	latexin	Homo sapiens	30-33	
21111806-9	2011	Inhibition occurred at hydroperoxide concentrations of &gt;=1muM for oxidized amino acids and peptides and &gt;=10muM for oxidized proteins, compared with ca.	Hydrogen Peroxide	23-36	latexin	Homo sapiens	61-64	
21215240-3	2010	Using the MTT reduction assay and Calcein-AM staining assay, we showed that pretreatment with H2O2 (10 muM, 24 hr) of COS7 cells partially protected cells against subsequent H2O2 (6 mM, 1 hr) - induced cytotoxicity.	Hydrogen Peroxide	94-98	latexin	Homo sapiens	103-106	
20921226-4	2010	Indeed, we found that high concentrations of hydroperoxide activator (e.g. 65 muM) overcame a prolonged lag phase (&gt;1 h) and unveiled a dioxygenase activity with arachidonic acid; the main products were the 5-, 9-, and 7-hydroperoxyeicosatetraenoic acids (HPETEs).	Hydrogen Peroxide	45-58	latexin	Homo sapiens	78-81	
21215240-3	2010	Using the MTT reduction assay and Calcein-AM staining assay, we showed that pretreatment with H2O2 (10 muM, 24 hr) of COS7 cells partially protected cells against subsequent H2O2 (6 mM, 1 hr) - induced cytotoxicity.	Hydrogen Peroxide	174-178	latexin	Homo sapiens	103-106	
21215240-4	2010	The phosphorylation of Akt/PKB, a downstream target of phosphatydylinositol-3 kinase (PI3K), at Ser473 was augmented by H2O2 (10 muM) administration.	Hydrogen Peroxide	120-124	latexin	Homo sapiens	129-132	
21215240-5	2010	This augmentation peaked at 10 minutes after H2O2 (10 muM) treatment and fell to the basal level at 24 hr.	Hydrogen Peroxide	45-49	latexin	Homo sapiens	54-57	
21215240-6	2010	A blocker of PI3K, LY294002, significantly attenuated H2O2 (10 muM, 24 hr) - induced cytoprotection.	Hydrogen Peroxide	54-58	latexin	Homo sapiens	63-66	
21215240-7	2010	In addition, pretreatment with LY294002 reduced H2O2 (10 muM, 10 min)-induced phosphorylation of Akt at Ser473.	Hydrogen Peroxide	48-52	latexin	Homo sapiens	57-60	
23105852-4	2009	Hydrogen peroxide was studied at 50, 100 and 200muM and was found to increase a dose dependent increase in lipid peroxidation and micronuclei frequency.	Hydrogen Peroxide	0-17	latexin	Homo sapiens	48-51	
19100530-5	2010	Oxidative stress was induced by hydrogen peroxide (H(2)O(2), 100 muM).	Hydrogen Peroxide	32-49	latexin	Homo sapiens	65-68	
20832166-4	2010	In addition, the TOC removal efficiencies of the alachlor under initial H(2)O(2) concentrations of 0, 0.5 and 1.0 muM were 59.5, 74.8 and 83.8%, respectively, at an absorbed dose of 20 k Gy.	Hydrogen Peroxide	72-80	latexin	Homo sapiens	114-117	
20869113-3	2010	We found that TRH and all the tested analogues at concentrations 0.1-50 muM attenuated cell damage induced by MPP(+) (2 mM), 3-nitropropionate (10 mM), hydrogen peroxide (0.5 mM), homocysteine (250 muM) and beta-amyloid (20muM) in retinoic acid differentiated SH-SY5Y cells.	Hydrogen Peroxide	152-169	latexin	Homo sapiens	72-75	
21030031-7	2010	The limit of detection for hydrogen peroxide was 6 muM by HPLC/FD, and 0.6 muM by HPLC/ED.	Hydrogen Peroxide	27-44	latexin	Homo sapiens	51-54	
20815781-2	2010	Hydrogen peroxide (15 muM) and taurine chloramine (200 muM) induced HL 60 differentiation, which was detected by CD11b expression and superoxide production.	Hydrogen Peroxide	0-17	latexin	Homo sapiens	22-25	
20815781-2	2010	Hydrogen peroxide (15 muM) and taurine chloramine (200 muM) induced HL 60 differentiation, which was detected by CD11b expression and superoxide production.	Hydrogen Peroxide	0-17	latexin	Homo sapiens	55-58	
24301826-4	1996	15% of the total cyt b-559 could be transiently oxidised by 200 muM H2O2 in the dark.	Hydrogen Peroxide	68-72	latexin	Homo sapiens	64-67	
20021146-7	2004	Interference with the detection of H(2)O(2)-induced DNA strand breaks appears to be SM concentration-dependent up to 30 muM, and independent of SM concentration at &gt;/=30 muM.	Hydrogen Peroxide	35-43	latexin	Homo sapiens	120-123	
20021146-7	2004	Interference with the detection of H(2)O(2)-induced DNA strand breaks appears to be SM concentration-dependent up to 30 muM, and independent of SM concentration at &gt;/=30 muM.	Hydrogen Peroxide	35-43	latexin	Homo sapiens	173-176	
21043868-1	1992	Hydrogen peroxide (H(2)O(2)) triggers activation of platelets "primed" by low concentrations of arachidonic acid (&lt; 20 muM) or collagen (&lt; 0.2 mug/ml), but has no effect on platelets exposed to low concentrations of thrombin, ADP or A23187.	Hydrogen Peroxide	0-17	latexin	Homo sapiens	122-125	
27405834-7	1995	Low concentration of ebselen (5 muM) plus GSH (50 muM) decomposed hydroperoxides in pre-oxidized LDL whether EDTA was added or not.	Hydrogen Peroxide	66-80	latexin	Homo sapiens	32-35	
27405834-7	1995	Low concentration of ebselen (5 muM) plus GSH (50 muM) decomposed hydroperoxides in pre-oxidized LDL whether EDTA was added or not.	Hydrogen Peroxide	66-80	latexin	Homo sapiens	50-53	
21043622-5	1995	Treatment of endothelial cells with hydrogen peroxide also induced endothelial cell injury in a dose dependent manner (50-150 muM).	Hydrogen Peroxide	36-53	latexin	Homo sapiens	126-129	
21043622-6	1995	Dipyridamole also prevented the endothelial cell injury induced by hydrogen peroxide with a dose dependent fashion (1-10 muM).	Hydrogen Peroxide	67-84	latexin	Homo sapiens	121-124