PMID-sentid	Pub_year	Sent_text		comp_official_name	comp_offsetprotein_name	organism	prot_offset
9514844-7	1998	The GH-releasing effect of DA was mimicked by the D1 agonists SKF38393 (0.1-10 muM) and SKF77434 (0.1-10 muM), but not by the D2 agonist LY171555 (3 muM).	Dopamine	27-29	latexin	Homo sapiens	79-82	
21662891-4	1999	The response for dopamine was linear from 20 to 200 muM, with a LOD of 1.0 muM and a sensitivity of 52 pA/muM.	Dopamine	17-25	latexin	Homo sapiens	52-55	
21662891-4	1999	The response for dopamine was linear from 20 to 200 muM, with a LOD of 1.0 muM and a sensitivity of 52 pA/muM.	Dopamine	17-25	latexin	Homo sapiens	75-78	
21662891-4	1999	The response for dopamine was linear from 20 to 200 muM, with a LOD of 1.0 muM and a sensitivity of 52 pA/muM.	Dopamine	17-25	latexin	Homo sapiens	75-78	
9514844-8	1998	In addition, the GH response to DA (1 muM) was blocked by the D1 antagonist SCH23390 (5 muM) but not by the D2 antagonist (+/-) sulpiride (5 muM), suggesting that the GH-releasing action of DA is mediated through receptors resembling mammalian D1 receptors.	Dopamine	32-34	latexin	Homo sapiens	38-41	
9514844-8	1998	In addition, the GH response to DA (1 muM) was blocked by the D1 antagonist SCH23390 (5 muM) but not by the D2 antagonist (+/-) sulpiride (5 muM), suggesting that the GH-releasing action of DA is mediated through receptors resembling mammalian D1 receptors.	Dopamine	32-34	latexin	Homo sapiens	88-91	
9514844-8	1998	In addition, the GH response to DA (1 muM) was blocked by the D1 antagonist SCH23390 (5 muM) but not by the D2 antagonist (+/-) sulpiride (5 muM), suggesting that the GH-releasing action of DA is mediated through receptors resembling mammalian D1 receptors.	Dopamine	32-34	latexin	Homo sapiens	88-91	
31183562-5	2019	The voltammetric response to DA is linear in the 2.0 muM to 160 muM concentration range even in the presence of 1.0 mM ascorbic acid and 0.1 mM of UA.	Dopamine	29-31	latexin	Homo sapiens	53-56	
8748684-5	1995	Conversely, at concentrations above 100 muM, salsolinol inhibited the uptake of noradrenaline and dopamine, with IC50 values of 411 muM and 379 muM, respectively.	Dopamine	98-106	latexin	Homo sapiens	132-135	
8748684-5	1995	Conversely, at concentrations above 100 muM, salsolinol inhibited the uptake of noradrenaline and dopamine, with IC50 values of 411 muM and 379 muM, respectively.	Dopamine	98-106	latexin	Homo sapiens	132-135	
32253397-5	2020	Under the optimal conditions, the DA sensor shows a linear response in the DA concentration ranges of 0.1 muM-0.08 mM and 0.08-0.41 mM with a low detection limit of 0.027 muM and a high sensitivity of 602.4 muA mM-1 cm-2.	Dopamine	34-36	latexin	Homo sapiens	106-109	
32253397-5	2020	Under the optimal conditions, the DA sensor shows a linear response in the DA concentration ranges of 0.1 muM-0.08 mM and 0.08-0.41 mM with a low detection limit of 0.027 muM and a high sensitivity of 602.4 muA mM-1 cm-2.	Dopamine	34-36	latexin	Homo sapiens	171-174	
32253397-5	2020	Under the optimal conditions, the DA sensor shows a linear response in the DA concentration ranges of 0.1 muM-0.08 mM and 0.08-0.41 mM with a low detection limit of 0.027 muM and a high sensitivity of 602.4 muA mM-1 cm-2.	Dopamine	75-77	latexin	Homo sapiens	106-109	
32253397-5	2020	Under the optimal conditions, the DA sensor shows a linear response in the DA concentration ranges of 0.1 muM-0.08 mM and 0.08-0.41 mM with a low detection limit of 0.027 muM and a high sensitivity of 602.4 muA mM-1 cm-2.	Dopamine	75-77	latexin	Homo sapiens	171-174	
32043995-7	2020	The detection limits of noradrenaline, adrenaline, and dopamine were 0.1, 0.1, and 0.2 muM, respectively.	Dopamine	55-63	latexin	Homo sapiens	87-90	
31594597-6	2020	Acceptable linear response of AA, DA, UA and AC respectively have been ranged 0.01-900.0 muM, 0.01-700.0 muM, 0.01-900.0 muM, and 0.01-900.0 muM with determination limits (S/N = 3) of 3.1 nM, 2.6 nM, 2.4 nM and 4.4 nM.	Dopamine	34-36	latexin	Homo sapiens	89-92	
31594597-6	2020	Acceptable linear response of AA, DA, UA and AC respectively have been ranged 0.01-900.0 muM, 0.01-700.0 muM, 0.01-900.0 muM, and 0.01-900.0 muM with determination limits (S/N = 3) of 3.1 nM, 2.6 nM, 2.4 nM and 4.4 nM.	Dopamine	34-36	latexin	Homo sapiens	105-108	
31594597-6	2020	Acceptable linear response of AA, DA, UA and AC respectively have been ranged 0.01-900.0 muM, 0.01-700.0 muM, 0.01-900.0 muM, and 0.01-900.0 muM with determination limits (S/N = 3) of 3.1 nM, 2.6 nM, 2.4 nM and 4.4 nM.	Dopamine	34-36	latexin	Homo sapiens	105-108	
31594597-6	2020	Acceptable linear response of AA, DA, UA and AC respectively have been ranged 0.01-900.0 muM, 0.01-700.0 muM, 0.01-900.0 muM, and 0.01-900.0 muM with determination limits (S/N = 3) of 3.1 nM, 2.6 nM, 2.4 nM and 4.4 nM.	Dopamine	34-36	latexin	Homo sapiens	105-108	
31009905-6	2019	The amperometric detection of dopamine sensor, using this sensing element, exhibits a wide linear response of 0-0.8 muM with a low detection limit of 2.7 nM.	Dopamine	30-38	latexin	Homo sapiens	116-119	
1165793-4	1975	Chlorpromazine, 1 muM, or pimozide, 1 muM, antagonized selectively the reduction in 3H-noradrenaline release obtained with dopamine or apomorphine, without affecting the inhibition obtained with (-)-noradrenaline.	Dopamine	123-131	latexin	Homo sapiens	18-21	
1165793-4	1975	Chlorpromazine, 1 muM, or pimozide, 1 muM, antagonized selectively the reduction in 3H-noradrenaline release obtained with dopamine or apomorphine, without affecting the inhibition obtained with (-)-noradrenaline.	Dopamine	123-131	latexin	Homo sapiens	38-41	
1165793-6	1975	Phenoxybenzamine, 0.29 muM, prevented the inhibition of 3H-transmitter overflow obtained with (-)-noradrenaline, dopamine or apomorphine.	Dopamine	113-121	latexin	Homo sapiens	23-26	
31060035-5	2019	At optimized conditions, the calibration curve was linear in the concentration range of 0.81-16.80 muM of dopamine.	Dopamine	106-114	latexin	Homo sapiens	99-102	
31183562-5	2019	The voltammetric response to DA is linear in the 2.0 muM to 160 muM concentration range even in the presence of 1.0 mM ascorbic acid and 0.1 mM of UA.	Dopamine	29-31	latexin	Homo sapiens	64-67	
30999216-8	2019	Bath application of dopamine (1 muM), or the phosphatidylinositol (PI)-linked D1-like-receptor agonist SKF83959 (5 muM), induced reliable and reversible increases in fluo-4 fluorescence and excitatory postsynaptic currents in fan cells, but not in pyramidal cells.	Dopamine	20-28	latexin	Homo sapiens	32-35	
30999216-8	2019	Bath application of dopamine (1 muM), or the phosphatidylinositol (PI)-linked D1-like-receptor agonist SKF83959 (5 muM), induced reliable and reversible increases in fluo-4 fluorescence and excitatory postsynaptic currents in fan cells, but not in pyramidal cells.	Dopamine	20-28	latexin	Homo sapiens	115-118	
30999216-10	2019	Blocking release of calcium from internal stores by loading cells with the IP3 receptor blocker heparin (1 mM) or the ryanodine receptor blocker dantrolene (20 muM) abolished both the calcium transients and the facilitation of evoked synaptic currents induced by dopamine.	Dopamine	263-271	latexin	Homo sapiens	160-163	
30782366-4	2019	The electrochemical investigation showed that the sensor performed good selectivity and wide linear ranges for the simultaneous detection of dopamine (0.5-150 muM) and uric acid (0.5-600 muM).	Dopamine	141-149	latexin	Homo sapiens	159-162	
30782366-4	2019	The electrochemical investigation showed that the sensor performed good selectivity and wide linear ranges for the simultaneous detection of dopamine (0.5-150 muM) and uric acid (0.5-600 muM).	Dopamine	141-149	latexin	Homo sapiens	187-190	
30218923-4	2018	The PtNPs@MnO2 nanocomposite was employed in a sensing assay for the determination of glutathione (GSH) and dopamine (DA) with a linear range of 0.2 muM-11 muM for GSH and 0.1 muM-1.1 muM for DA.	Dopamine	108-116	latexin	Homo sapiens	149-152	
31049714-9	2019	The electrode respondsy to dopamine in the ranges of 0.15 to 45 muM, the detection limit is 8.2 nM (S/N = 3), and the sensitivity is 20.81 muA muM-1 cm-2.	Dopamine	27-35	latexin	Homo sapiens	64-67	
30391428-4	2019	The results showed that bioluminescence emission of aequorin was effectively quenched by increasing concentration of dopamine at the range of 1 nM to 100 muM with a detection limit of 53 nM.	Dopamine	117-125	latexin	Homo sapiens	154-157	
30597937-8	2018	The presence of ascorbic acid increased the sensitivity of dopamine determination at the modified electrode, and the detection limit was estimated to be 0.5 muM with 0.1 mM ascorbic acid to imitate physiological solutions.	Dopamine	59-67	latexin	Homo sapiens	157-160	
30218923-4	2018	The PtNPs@MnO2 nanocomposite was employed in a sensing assay for the determination of glutathione (GSH) and dopamine (DA) with a linear range of 0.2 muM-11 muM for GSH and 0.1 muM-1.1 muM for DA.	Dopamine	118-120	latexin	Homo sapiens	149-152	
29958556-5	2018	Considering dopamine detection in real biological fluid samples, the NUNCD electrode performed excellently with a detection limit of 0.39 muM and a high recovery ranging from 90-120%, revealing that NUNCD electrodes have promising use in the sensing of dopamine.	Dopamine	253-261	latexin	Homo sapiens	138-141	
32528220-6	2018	Using cyclic voltammetry, the 100-nm "thin" film microelectrode produced the most favorable combination of DA sensitivity value of 36 +-2% muA/muM/cm2 with a linear range of 33 nM to 1 muM and a limit of detection (LOD) of 9.5 +- 1.2% nM.	Dopamine	107-109	latexin	Homo sapiens	143-146	
29753967-6	2018	By taking advantage of this fact, a sensitive probe was designed for determination of dopamine, adrenaline and noradrenaline with a limit of detection of 0.07, 0.60 and 0.01 muM, respectively.	Dopamine	86-94	latexin	Homo sapiens	174-177	
29891587-6	2018	Results indicate that solriamfetol has dual reuptake inhibition activity at dopamine (DA; IC50 = 2.9 muM) and norepinephrine (NE; IC50 = 4.4 muM) transporters, and this activity is associated in vivo with increased extracellular concentration of DA and NE as measured by microdialysis.	Dopamine	86-88	latexin	Homo sapiens	101-104	
32254405-6	2018	The linear ranges are 0.001-1.5 mM, 0.05-160 muM and 0.001-0.875 mM for AA, DA and UA, and the corresponding detection limits are 0.3 muM, 20 nM and 0.3 muM, respectively.	Dopamine	76-78	latexin	Homo sapiens	134-137	
32254405-6	2018	The linear ranges are 0.001-1.5 mM, 0.05-160 muM and 0.001-0.875 mM for AA, DA and UA, and the corresponding detection limits are 0.3 muM, 20 nM and 0.3 muM, respectively.	Dopamine	76-78	latexin	Homo sapiens	134-137	
29704250-9	2018	Using this system with a gold microelectrode, dopamine, and epinephrine could be quantified within the concentration range of 1-500 muM and detected at a concentration of 0.3 muM.	Dopamine	46-54	latexin	Homo sapiens	132-135	
29704250-9	2018	Using this system with a gold microelectrode, dopamine, and epinephrine could be quantified within the concentration range of 1-500 muM and detected at a concentration of 0.3 muM.	Dopamine	46-54	latexin	Homo sapiens	175-178	
29958556-4	2018	Furthermore, the marked selectivity of the NUNCD electrode is very favorable for the determination of dopamine (DA) concentration (0.32 muM) in the presence of ascorbic acid (AA) and uric acid (UA).	Dopamine	102-110	latexin	Homo sapiens	136-139	
29958556-4	2018	Furthermore, the marked selectivity of the NUNCD electrode is very favorable for the determination of dopamine (DA) concentration (0.32 muM) in the presence of ascorbic acid (AA) and uric acid (UA).	Dopamine	112-114	latexin	Homo sapiens	136-139	
29958556-5	2018	Considering dopamine detection in real biological fluid samples, the NUNCD electrode performed excellently with a detection limit of 0.39 muM and a high recovery ranging from 90-120%, revealing that NUNCD electrodes have promising use in the sensing of dopamine.	Dopamine	12-20	latexin	Homo sapiens	138-141	
29537707-5	2018	We found that blockade of D1/D5 receptors by SCH 23390 (20 muM) significantly reduced the magnitude of LTP in both DH and VH similarly suggesting that dopamine endogenously released during TBS, presumably mimicking low activity of DA neurons, exerts a homogeneous modulation of LTP along the hippocampal long axis.	Dopamine	151-159	latexin	Homo sapiens	59-62	
29442624-5	2018	Linear analytical curves were obtained in the range from 2 to 120 muM for dopamine by differential pulse voltammetry, with the detection limit of 0.13 muM (signal-to-noise ratio of 3).	Dopamine	74-82	latexin	Homo sapiens	66-69	
29442624-5	2018	Linear analytical curves were obtained in the range from 2 to 120 muM for dopamine by differential pulse voltammetry, with the detection limit of 0.13 muM (signal-to-noise ratio of 3).	Dopamine	74-82	latexin	Homo sapiens	151-154	
32528220-6	2018	Using cyclic voltammetry, the 100-nm "thin" film microelectrode produced the most favorable combination of DA sensitivity value of 36 +-2% muA/muM/cm2 with a linear range of 33 nM to 1 muM and a limit of detection (LOD) of 9.5 +- 1.2% nM.	Dopamine	107-109	latexin	Homo sapiens	185-188	
29226668-10	2017	However, it is still able to detect DA down to 1 pM range in the presence of [AA] = 100 muM and 100 pM in the presence of [UA] = 3 muM, these values for AA and UA being the physiological levels in the cerebrospinal fluid and the striatum, respectively.	Dopamine	36-38	latexin	Homo sapiens	88-91	
29400087-4	2018	RESULTS: Heterocumulenes derived from dopamine and beta-O-methylnoradrenaline were strong antiproliferative agents (GI50&lt;10 muM).	Dopamine	38-46	latexin	Homo sapiens	127-130	
28960783-6	2018	Dopamine in the range 20-100 muM can be linearly detected by the fluorescence quenching ratio of gold nanoclusters.	Dopamine	0-8	latexin	Homo sapiens	29-32	
29156235-5	2018	The linear detection range for dopamine is 2.5-1500 muM with detection limit of 1.5 muM.	Dopamine	31-39	latexin	Homo sapiens	52-55	
29156235-5	2018	The linear detection range for dopamine is 2.5-1500 muM with detection limit of 1.5 muM.	Dopamine	31-39	latexin	Homo sapiens	84-87	
29594573-5	2018	The peak current (best measured at a working voltage of 0.17 V vs. Ag/AgCl) increases linearly in the 0.1 to 400 muM DA concentration range, with a 40 nM detection limit (at S/N = 3).	Dopamine	117-119	latexin	Homo sapiens	113-116	
29594573-9	2018	The determination of the DPV curves provides satisfactory results which can be characterized by a linear response for DA concentrations ranging from 0.1 to 400.0 muM with a 40 nM detection limit (at S/N = 3).	Dopamine	118-120	latexin	Homo sapiens	162-165	
29226668-10	2017	However, it is still able to detect DA down to 1 pM range in the presence of [AA] = 100 muM and 100 pM in the presence of [UA] = 3 muM, these values for AA and UA being the physiological levels in the cerebrospinal fluid and the striatum, respectively.	Dopamine	36-38	latexin	Homo sapiens	131-134	
28714693-5	2017	We find that in vivo imaging of neuromodulation requires simultaneous optimization of dopamine nanosensor reversibility and sensitivity: dopamine imaging in the striatum or nucleus accumbens requires nanosensors with an optimal dopamine dissociation constant (Kd) of 1 muM, whereas Kds above 10 muM are required for dopamine imaging in the prefrontal cortex.	Dopamine	137-145	latexin	Homo sapiens	269-272	
29027462-3	2017	The proposed system responses specifically to dopamine with a detection limit of 1.43 muM.	Dopamine	46-54	latexin	Homo sapiens	86-89	
28714693-5	2017	We find that in vivo imaging of neuromodulation requires simultaneous optimization of dopamine nanosensor reversibility and sensitivity: dopamine imaging in the striatum or nucleus accumbens requires nanosensors with an optimal dopamine dissociation constant (Kd) of 1 muM, whereas Kds above 10 muM are required for dopamine imaging in the prefrontal cortex.	Dopamine	137-145	latexin	Homo sapiens	295-298	
28714693-5	2017	We find that in vivo imaging of neuromodulation requires simultaneous optimization of dopamine nanosensor reversibility and sensitivity: dopamine imaging in the striatum or nucleus accumbens requires nanosensors with an optimal dopamine dissociation constant (Kd) of 1 muM, whereas Kds above 10 muM are required for dopamine imaging in the prefrontal cortex.	Dopamine	137-145	latexin	Homo sapiens	269-272	
28714693-5	2017	We find that in vivo imaging of neuromodulation requires simultaneous optimization of dopamine nanosensor reversibility and sensitivity: dopamine imaging in the striatum or nucleus accumbens requires nanosensors with an optimal dopamine dissociation constant (Kd) of 1 muM, whereas Kds above 10 muM are required for dopamine imaging in the prefrontal cortex.	Dopamine	137-145	latexin	Homo sapiens	295-298	
28714693-5	2017	We find that in vivo imaging of neuromodulation requires simultaneous optimization of dopamine nanosensor reversibility and sensitivity: dopamine imaging in the striatum or nucleus accumbens requires nanosensors with an optimal dopamine dissociation constant (Kd) of 1 muM, whereas Kds above 10 muM are required for dopamine imaging in the prefrontal cortex.	Dopamine	137-145	latexin	Homo sapiens	269-272	
28714693-5	2017	We find that in vivo imaging of neuromodulation requires simultaneous optimization of dopamine nanosensor reversibility and sensitivity: dopamine imaging in the striatum or nucleus accumbens requires nanosensors with an optimal dopamine dissociation constant (Kd) of 1 muM, whereas Kds above 10 muM are required for dopamine imaging in the prefrontal cortex.	Dopamine	137-145	latexin	Homo sapiens	295-298	
28752884-4	2017	Amperometric dopamine biosensors based on dendritic Pt3Ni nanoalloy microelectrode exhibit a wide linear detection ranges from 0.5 muM to 250 muM with ultrahigh sensitivity, fast response, and excellent selectivity at a potential of 0.3 V in a 0.1 M phosphate buffered solution (pH = 7.2).	Dopamine	13-21	latexin	Homo sapiens	131-134	
28752884-4	2017	Amperometric dopamine biosensors based on dendritic Pt3Ni nanoalloy microelectrode exhibit a wide linear detection ranges from 0.5 muM to 250 muM with ultrahigh sensitivity, fast response, and excellent selectivity at a potential of 0.3 V in a 0.1 M phosphate buffered solution (pH = 7.2).	Dopamine	13-21	latexin	Homo sapiens	142-145	
32264558-7	2017	The relative intensity of restored fluorescence is proportional to the concentration of DA in the wide linear range of 0.25-50 muM with a low detection limit of 57 nM (S/N = 3).	Dopamine	88-90	latexin	Homo sapiens	127-130	
28482573-6	2017	The composite of DAAO-Hb/MnO2 NPs/PTh to construct a bi-enzyme biosensor in this study showed a linear response with DA in the concentration range of 0.04-9.0muM with R-squared value of 0.994 (for S/N=3) and its sensitivity and detection limite were about 12.801muA/muM and 41nM respectively.	Dopamine	17-19	latexin	Homo sapiens	158-161	
27770936-4	2017	Under optimum conditions with differential pulse voltammetry method, a broad linear response versus the concentrations of DA and AC has been observed in the ranges of 2.0 to 250.0muM and 5.0 to 300.0muM, respectively.	Dopamine	122-124	latexin	Homo sapiens	179-182	
26530000-5	2015	This near-infrared quantum dot based ECL sensor displayed a linear response over the range 3.7 &lt;= [dopamine] &lt;= 450 muM, allowing the rapid detection of dopamine and providing a platform for future development.	Dopamine	102-110	latexin	Homo sapiens	122-125	
27420730-3	2016	This treatment did suppress the detection of ascorbic acid oxidation signal, but only in a manner suitable for single-use detection of high concentrations of dopamine (i.e., &gt; 1 muM).	Dopamine	158-166	latexin	Homo sapiens	181-184	
27155116-9	2016	The DA concentration changed from 42.8 to 481.6muM when the MEA probe inserted from cortex into deep brain nucleus of striatum, which reflected the inhomogeneous distribution of DA in brains.	Dopamine	4-6	latexin	Homo sapiens	47-50	
27455760-6	2016	These surface modified pin type electrode was applied to detect low concentration of DA and successfully detect various concentration of DA from 100 muM to 1 muM with linear relationship in the presence of ascorbic acid and uric acid.	Dopamine	85-87	latexin	Homo sapiens	149-152	
27455760-6	2016	These surface modified pin type electrode was applied to detect low concentration of DA and successfully detect various concentration of DA from 100 muM to 1 muM with linear relationship in the presence of ascorbic acid and uric acid.	Dopamine	85-87	latexin	Homo sapiens	158-161	
27455760-6	2016	These surface modified pin type electrode was applied to detect low concentration of DA and successfully detect various concentration of DA from 100 muM to 1 muM with linear relationship in the presence of ascorbic acid and uric acid.	Dopamine	137-139	latexin	Homo sapiens	149-152	
27455760-6	2016	These surface modified pin type electrode was applied to detect low concentration of DA and successfully detect various concentration of DA from 100 muM to 1 muM with linear relationship in the presence of ascorbic acid and uric acid.	Dopamine	137-139	latexin	Homo sapiens	158-161	
26530000-5	2015	This near-infrared quantum dot based ECL sensor displayed a linear response over the range 3.7 &lt;= [dopamine] &lt;= 450 muM, allowing the rapid detection of dopamine and providing a platform for future development.	Dopamine	159-167	latexin	Homo sapiens	122-125	
25756085-4	2015	For simultaneous detection of AA, DA, and UA, the linear current-concentration responses were observed from 1.0 muM-4.1 mM, 0.05-112.0 muM, and 3.0-186.0 muM, with the detection limits of 0.185, 0.017, and 0.654 muM (S/N = 3), respectively.	Dopamine	34-36	latexin	Homo sapiens	112-115	
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.	Dopamine	248-256	latexin	Homo sapiens	102-105	
32262771-3	2015	The oxidation peak current of DA is linearly proportional to its concentration in the range from 1.5-215.56 muM, with a detection limit of 0.1 muM (at S/N = 3).	Dopamine	30-32	latexin	Homo sapiens	108-111	
32262771-3	2015	The oxidation peak current of DA is linearly proportional to its concentration in the range from 1.5-215.56 muM, with a detection limit of 0.1 muM (at S/N = 3).	Dopamine	30-32	latexin	Homo sapiens	143-146	
32262714-4	2015	The relevant detection limit toward dopamine is 0.3 nM with a wide linear range from 0.001 muM to 200 muM.	Dopamine	36-44	latexin	Homo sapiens	91-94	
32262714-4	2015	The relevant detection limit toward dopamine is 0.3 nM with a wide linear range from 0.001 muM to 200 muM.	Dopamine	36-44	latexin	Homo sapiens	102-105	
26212665-2	2015	High selectivity and sensitivity (detection limit of 0.5 muM, a linear range from 10 muM to 1 mM) have been achieved through the strong interaction between the nonstick PTFE and DA via its oxidative self-polymerization, and the output voltage and current of the developed TENS can reach 116 V and 33 muA, which is exceptionally attractive for the fabrication of self-powered and portable device toward the detection of dopamine.	Dopamine	178-180	latexin	Homo sapiens	57-60	
26212665-2	2015	High selectivity and sensitivity (detection limit of 0.5 muM, a linear range from 10 muM to 1 mM) have been achieved through the strong interaction between the nonstick PTFE and DA via its oxidative self-polymerization, and the output voltage and current of the developed TENS can reach 116 V and 33 muA, which is exceptionally attractive for the fabrication of self-powered and portable device toward the detection of dopamine.	Dopamine	178-180	latexin	Homo sapiens	85-88	
26184200-6	2015	The linear range of the constructed DA sensor was from 1.6 muM to 39.7 muM with a detection limit of 0.1 muM (S/N = 3).	Dopamine	36-38	latexin	Homo sapiens	59-62	
26184200-6	2015	The linear range of the constructed DA sensor was from 1.6 muM to 39.7 muM with a detection limit of 0.1 muM (S/N = 3).	Dopamine	36-38	latexin	Homo sapiens	71-74	
26184200-6	2015	The linear range of the constructed DA sensor was from 1.6 muM to 39.7 muM with a detection limit of 0.1 muM (S/N = 3).	Dopamine	36-38	latexin	Homo sapiens	71-74	
25882962-5	2015	Therewith, the aptamer affinity for dopamine increases one order of magnitude due to electrostatically regulated immobilization, with the aptamer-dopamine dissociation constant of 0.12 +- 0.01 muM versus 1.6 +- 0.17 muM shown in solution.	Dopamine	36-44	latexin	Homo sapiens	193-196	
25882962-5	2015	Therewith, the aptamer affinity for dopamine increases one order of magnitude due to electrostatically regulated immobilization, with the aptamer-dopamine dissociation constant of 0.12 +- 0.01 muM versus 1.6 +- 0.17 muM shown in solution.	Dopamine	36-44	latexin	Homo sapiens	216-219	
25882962-5	2015	Therewith, the aptamer affinity for dopamine increases one order of magnitude due to electrostatically regulated immobilization, with the aptamer-dopamine dissociation constant of 0.12 +- 0.01 muM versus 1.6 +- 0.17 muM shown in solution.	Dopamine	146-154	latexin	Homo sapiens	193-196	
25882962-5	2015	Therewith, the aptamer affinity for dopamine increases one order of magnitude due to electrostatically regulated immobilization, with the aptamer-dopamine dissociation constant of 0.12 +- 0.01 muM versus 1.6 +- 0.17 muM shown in solution.	Dopamine	146-154	latexin	Homo sapiens	216-219	
25882962-6	2015	Under optimal conditions, 0.1-2 muM dopamine was specifically and 85.4 nA muM(-1) cm(-2) sensitively detected, with no interference from structurally related catecholamines.	Dopamine	36-44	latexin	Homo sapiens	32-35	
25882962-7	2015	The results allow improvement of the robustness of dopamine monitoring by aptamer-modified electrodes in biological systems, within the 0.01-1 muM dopamine fluctuation range.	Dopamine	51-59	latexin	Homo sapiens	143-146	
25882962-7	2015	The results allow improvement of the robustness of dopamine monitoring by aptamer-modified electrodes in biological systems, within the 0.01-1 muM dopamine fluctuation range.	Dopamine	147-155	latexin	Homo sapiens	143-146	
25756085-4	2015	For simultaneous detection of AA, DA, and UA, the linear current-concentration responses were observed from 1.0 muM-4.1 mM, 0.05-112.0 muM, and 3.0-186.0 muM, with the detection limits of 0.185, 0.017, and 0.654 muM (S/N = 3), respectively.	Dopamine	34-36	latexin	Homo sapiens	135-138	
25756085-4	2015	For simultaneous detection of AA, DA, and UA, the linear current-concentration responses were observed from 1.0 muM-4.1 mM, 0.05-112.0 muM, and 3.0-186.0 muM, with the detection limits of 0.185, 0.017, and 0.654 muM (S/N = 3), respectively.	Dopamine	34-36	latexin	Homo sapiens	135-138	
25756085-4	2015	For simultaneous detection of AA, DA, and UA, the linear current-concentration responses were observed from 1.0 muM-4.1 mM, 0.05-112.0 muM, and 3.0-186.0 muM, with the detection limits of 0.185, 0.017, and 0.654 muM (S/N = 3), respectively.	Dopamine	34-36	latexin	Homo sapiens	135-138	
25045758-5	2014	The ErGO-based biosensor exhibited a linear response towards dopamine in the concentration range of 0.1-10 muM with a low detection limit of 0.1 muM.	Dopamine	61-69	latexin	Homo sapiens	145-148	
25804204-2	2015	The deposited graphene significantly increased the surface area of working electrode, which led to the nMEA (with diameter of 20 mum) with excellent selectivity and sensitivity to DA.	Dopamine	180-182	latexin	Homo sapiens	129-132	
25576954-6	2015	The lowest detection limits (signal/noise=3) were 25.0, 0.04, and 0.2 muM for AA, DA, and UA, respectively.	Dopamine	82-84	latexin	Homo sapiens	70-73	
28191042-8	2015	Limits of detection for dopamine and NO were 130 nM and 1.8 muM, respectively.	Dopamine	24-32	latexin	Homo sapiens	60-63	
26294980-4	2015	Analyzing DA participation in striatal GABAergic plasticity we observed that high frequency stimulation (HFS) of GABAergic interneurons in the presence of DA at a low concentration (200 nM) favored the expression of inhibitory striatal LTD, whereas higher concentration of DA (20 muM) primarily induced LTP.	Dopamine	155-157	latexin	Homo sapiens	280-283	
25045758-5	2014	The ErGO-based biosensor exhibited a linear response towards dopamine in the concentration range of 0.1-10 muM with a low detection limit of 0.1 muM.	Dopamine	61-69	latexin	Homo sapiens	107-110	
25325840-5	2014	On the basis of large potential separation and high current response, selective and sensitive simultaneous determination of AA, DA, and UA was successfully accomplished by differential pulse voltammetry, displaying a linear response from 50 to 2000 muM, from 0.1 to 50 muM, and from 0.1 to 50 muM with a detection limit (S/N = 3) of 0.78, 0.02, and 0.06 muM.	Dopamine	128-130	latexin	Homo sapiens	249-252	
25029608-5	2014	This novel sensor exhibits fast amperometric response and high sensitivity toward DA with a wide linear concentration range of 10-500 muM and a low detection limit of 0.11 muM (S/N = 3), wherein the interference of UA and AA can be eliminated effectively.	Dopamine	82-84	latexin	Homo sapiens	134-137	
25029608-5	2014	This novel sensor exhibits fast amperometric response and high sensitivity toward DA with a wide linear concentration range of 10-500 muM and a low detection limit of 0.11 muM (S/N = 3), wherein the interference of UA and AA can be eliminated effectively.	Dopamine	82-84	latexin	Homo sapiens	172-175	
25000168-6	2014	Under the optimum conditions, the oxidation peak currents of ACOP and DA were linearly correlated to their concentrations in the ranges of 1-100 and 1-50 muM, respectively.	Dopamine	70-72	latexin	Homo sapiens	154-157	
24441542-5	2014	The voltammetric response of AA was well resolved from the responses of DA and UA, and the oxidation potential of AA was negatively shifted to -0.20 V. The biosensor tolerated a wide linear concentration range for AA, from 1.0 x 10(-5)M to 2.63 x 10(-3)M (R(2)=0.9929), with a detection limit of 0.5 muM (S/N = 3).	Dopamine	72-74	latexin	Homo sapiens	300-303	
24140872-5	2014	By simultaneously changing the concentrations of AA, DA and UA, their oxidation peaks appeared at -0.05 V, 0.16 V and 2.6 V, and the good linear responses ranges were 73.52-2305.53 muM, 1.36-125.69 muM and 3.98-371.49 muM, respectively.	Dopamine	53-55	latexin	Homo sapiens	181-184	
24140872-5	2014	By simultaneously changing the concentrations of AA, DA and UA, their oxidation peaks appeared at -0.05 V, 0.16 V and 2.6 V, and the good linear responses ranges were 73.52-2305.53 muM, 1.36-125.69 muM and 3.98-371.49 muM, respectively.	Dopamine	53-55	latexin	Homo sapiens	198-201	
24140872-5	2014	By simultaneously changing the concentrations of AA, DA and UA, their oxidation peaks appeared at -0.05 V, 0.16 V and 2.6 V, and the good linear responses ranges were 73.52-2305.53 muM, 1.36-125.69 muM and 3.98-371.49 muM, respectively.	Dopamine	53-55	latexin	Homo sapiens	198-201	
24725464-5	2014	In the presence of dopamine (25 muM), the translocation events at--85 pA shifted to--80 pA, which also represents translocation events, because the event time decreases with increasing voltage.	Dopamine	19-27	latexin	Homo sapiens	32-35	
24725464-7	2014	Event profiles for an N-terminal 1-60-residue peptide and a C-terminal 96-140-residue peptide were both altered in the presence of 25 muM dopamine.	Dopamine	138-146	latexin	Homo sapiens	134-137	
25325840-5	2014	On the basis of large potential separation and high current response, selective and sensitive simultaneous determination of AA, DA, and UA was successfully accomplished by differential pulse voltammetry, displaying a linear response from 50 to 2000 muM, from 0.1 to 50 muM, and from 0.1 to 50 muM with a detection limit (S/N = 3) of 0.78, 0.02, and 0.06 muM.	Dopamine	128-130	latexin	Homo sapiens	269-272	
25325840-5	2014	On the basis of large potential separation and high current response, selective and sensitive simultaneous determination of AA, DA, and UA was successfully accomplished by differential pulse voltammetry, displaying a linear response from 50 to 2000 muM, from 0.1 to 50 muM, and from 0.1 to 50 muM with a detection limit (S/N = 3) of 0.78, 0.02, and 0.06 muM.	Dopamine	128-130	latexin	Homo sapiens	269-272	
25325840-5	2014	On the basis of large potential separation and high current response, selective and sensitive simultaneous determination of AA, DA, and UA was successfully accomplished by differential pulse voltammetry, displaying a linear response from 50 to 2000 muM, from 0.1 to 50 muM, and from 0.1 to 50 muM with a detection limit (S/N = 3) of 0.78, 0.02, and 0.06 muM.	Dopamine	128-130	latexin	Homo sapiens	269-272	
24308368-6	2013	Of all five carbon electrode types, freshly cleaved basal plane HOPG showed the clearest signal (distinct from the background) at low concentrations of DA (&lt;10 muM) as a consequence of the low capacitance.	Dopamine	152-154	latexin	Homo sapiens	163-166	
24012662-3	2013	Being employed as an electrochemical sensor for detection of dopamine, the modified electrode exhibits remarkable sensitivity (3.44muA/muM) and lower detection limit (5nM), with linear response in a range of 0.05-20muM.	Dopamine	61-69	latexin	Homo sapiens	135-138	
24245864-6	2013	Optimization of FSCAV yielded a sensitivity of 81 +- 11 nA/muM for dopamine, corresponding to a limit of detection of 3.7 +- 0.5 nM.	Dopamine	67-75	latexin	Homo sapiens	59-62	
23481547-9	2013	Exogenous DA (50 muM) also evoked a glutamate-receptor independent increase in firing and an inward current when D2 receptors were blocked.	Dopamine	10-12	latexin	Homo sapiens	17-20	
24283218-5	2013	Dopamine (20 muM) and SKF 81297 (10 muM) caused inhibition of TTX-R sodium current in small DRG neurons by 23% and 37%, respectively.	Dopamine	0-8	latexin	Homo sapiens	13-16	
23651571-5	2013	By simultaneously changing the concentrations of AA, DA, UA and AC, their electrochemical oxidation peaks appeared at -0.03, 0.15, 0.24 and 0.35 V, and good linear current responses were obtained in the concentration ranges of 6-350, 0.5-50, 1-90 and 0.4-32 muM with the detection limits of 1, 0.1, 0.2 and 0.05 muM (S/N=3), respectively.	Dopamine	53-55	latexin	Homo sapiens	258-261	
23651571-5	2013	By simultaneously changing the concentrations of AA, DA, UA and AC, their electrochemical oxidation peaks appeared at -0.03, 0.15, 0.24 and 0.35 V, and good linear current responses were obtained in the concentration ranges of 6-350, 0.5-50, 1-90 and 0.4-32 muM with the detection limits of 1, 0.1, 0.2 and 0.05 muM (S/N=3), respectively.	Dopamine	53-55	latexin	Homo sapiens	312-315	
23929722-5	2013	METHODS AND RESULTS: Nonivamide (1 muM) stimulated the Ca(2+) -dependent release of serotonin (272 +- 115%) and dopamine (646 +- 48%) in SH-SY5Y cells compared to nontreated cells (100%) to a similar extent as capsaicin.	Dopamine	112-120	latexin	Homo sapiens	35-38	
22720719-6	2012	Specifically, good-quality signal of dopamine and its oxidized form, dopamine o-quinone, was obtained using 10 muL of 1 muM solution of dopamine on the IDA.	Dopamine	37-45	latexin	Homo sapiens	120-123	
23202347-7	2013	The sensitivity of AA, DA and UA at the sensor is 0.012, 4.031, 0.605 muA/muM respectively.	Dopamine	23-25	latexin	Homo sapiens	74-77	
23598203-6	2013	Under optimum conditions, the relative fluorescence intensity was linearly proportional to the concentration of DA within the range from 0.05 to 10 muM, with the detection limit down to 12 nM (n=3).	Dopamine	112-114	latexin	Homo sapiens	148-151	
23020235-4	2012	The determined linear range for DA detection was 0.2-600 muM (N = 3) and the sensitivity was 178 nA/muM cm(2), while the detection limit was 26 nM (S/N = 3).	Dopamine	32-34	latexin	Homo sapiens	57-60	
23020235-4	2012	The determined linear range for DA detection was 0.2-600 muM (N = 3) and the sensitivity was 178 nA/muM cm(2), while the detection limit was 26 nM (S/N = 3).	Dopamine	32-34	latexin	Homo sapiens	100-103	
22590703-5	2012	Moreover, the excellent differential pulse voltammetric (DPV) response toward dopamine, hydroquinone and catechol was obtained and the detection limits was determined to be 0.337, 0.289 and 0.369 muM, respectively.	Dopamine	78-86	latexin	Homo sapiens	196-199	
23397090-7	2013	This configuration achieved a detection limit of 0.454 +- 0.026 muM dopamine at the collector in the presence of 100 muM ascorbic acid in artificial cerebrospinal fluid buffer, concentrations that are consistent with physiological levels.	Dopamine	68-76	latexin	Homo sapiens	64-67	
23397090-7	2013	This configuration achieved a detection limit of 0.454 +- 0.026 muM dopamine at the collector in the presence of 100 muM ascorbic acid in artificial cerebrospinal fluid buffer, concentrations that are consistent with physiological levels.	Dopamine	68-76	latexin	Homo sapiens	117-120	
22512377-10	2012	In primary neonatal rat astrocyte cell cultures, dopamine (200 muM) significantly (P &lt; 0.05) increased numbers of intracellular tachyzoites after 24 hr.	Dopamine	49-57	latexin	Homo sapiens	63-66	
22570010-5	2012	After exposure of synaptosomes to Tat(1-86) (1 muM), DAT immunoreactivity was decreased in plasma membrane enriched fractions (P3) and increased in vesicle-enriched fractions (P4) relative to controls without change in total synaptosomal fractions (P2), suggesting that Tat-induced inhibition of DA uptake is attributable to DAT internalization.	Dopamine	53-55	latexin	Homo sapiens	47-50	
22720719-6	2012	Specifically, good-quality signal of dopamine and its oxidized form, dopamine o-quinone, was obtained using 10 muL of 1 muM solution of dopamine on the IDA.	Dopamine	69-77	latexin	Homo sapiens	120-123	
19225762-11	2009	Administration of alpha-flupenthixol (20 muM) attenuated eIPSC inhibition by dopamine but had no effect on met-enkephalin-induced inhibition.	Dopamine	77-85	latexin	Homo sapiens	41-44	
22391457-7	2012	This, combined with the porosity that enhances the adsorption activity of C(60)-modified electrodes, enable the electrocatalytic analysis of target biomolecules with detection limit as low as 0.1 nM for DA in the presence of AA, and 1 muM for UA in the presence of RSH.	Dopamine	203-205	latexin	Homo sapiens	235-238	
22299833-5	2012	Application of dopamine at a low concentration (1 muM) did not induce an increase in Ca(2+) signal frequency by itself.	Dopamine	15-23	latexin	Homo sapiens	50-53	
22676038-6	2012	GSK-3beta inhibitors completely blocked high-dose (20 muM) DA-induced depressive effects on IPSCs but exhibited limited effects on the facilitating regulation of IPSC in low-dose DA (200 nM).	Dopamine	59-61	latexin	Homo sapiens	54-57	
22224417-4	2012	In vivo, focal application of 100 muM d-kynurenine by reverse microdialysis led to a steady rise in extracellular kynurenic acid in the rat striatum, causing a 4-fold elevation after 2 h. Attesting to functional significance, this increase was accompanied by a 36% reduction in extracellular dopamine.	Dopamine	292-300	latexin	Homo sapiens	34-37	
19195936-4	2009	The electrocatalytic currents increases linearly with the DA and UA concentrations in the ranges of 0.1-900 microM and 20-650 microM, and the detection limits for DA and UA, were 0.087 and 15 muM, respectively.	Dopamine	58-60	latexin	Homo sapiens	192-195	
19074002-4	2009	Bromocriptine (100 nM) and dopamine (100 nM and 10 muM) increased tyrosine phosphorylation during the capacitation period.	Dopamine	27-35	latexin	Homo sapiens	51-54	
19074002-7	2009	We also showed that bromocriptine (100 nM) and low-concentration dopamine (100 nM and 10 muM) increased total and progressive motility of sperm.	Dopamine	65-73	latexin	Homo sapiens	89-92	
19195936-4	2009	The electrocatalytic currents increases linearly with the DA and UA concentrations in the ranges of 0.1-900 microM and 20-650 microM, and the detection limits for DA and UA, were 0.087 and 15 muM, respectively.	Dopamine	163-165	latexin	Homo sapiens	192-195	
18542926-7	2008	However, when used in combination with ADP (10 muM), dopamine in a range of 1 to 100 muM significantly potentiated platelet microaggregate formation and adhesion to collagen under low shear flow conditions.	Dopamine	53-61	latexin	Homo sapiens	47-50	
18542926-7	2008	However, when used in combination with ADP (10 muM), dopamine in a range of 1 to 100 muM significantly potentiated platelet microaggregate formation and adhesion to collagen under low shear flow conditions.	Dopamine	53-61	latexin	Homo sapiens	85-88