about
Recent trends in carbon nanomaterial-based electrochemical sensors for biomolecules: A review.O2 Plasma Etching and Antistatic Gun Surface Modifications for CNT Yarn Microelectrode Improve Sensitivity and Antifouling Properties.Evaluation of carbon nanotube fiber microelectrodes for neurotransmitter detection: Correlation of electrochemical performance and surface properties.Automated Algorithm for Detection of Transient Adenosine Release.Analytical Techniques in Neuroscience: Recent Advances in Imaging, Separation, and Electrochemical Methods.Transient Adenosine Release Is Modulated by NMDA and GABAB Receptors.Optogenetic control of serotonin and dopamine release in Drosophila larvae.Polyethylenimine carbon nanotube fiber electrodes for enhanced detection of neurotransmitters.Sawhorse waveform voltammetry for selective detection of adenosine, ATP, and hydrogen peroxide.Mechanical stimulation evokes rapid increases in extracellular adenosine concentration in the prefrontal cortex.High temporal resolution measurements of dopamine with carbon nanotube yarn microelectrodesKinetics of the dopamine transporter in Drosophila larvaQuantitation of dopamine, serotonin and adenosine content in a tissue punch from a brain slice using capillary electrophoresis with fast-scan cyclic voltammetry detectionCharacterization of spontaneous, transient adenosine release in the caudate-putamen and prefrontal cortex.Nafion-CNT coated carbon-fiber microelectrodes for enhanced detection of adenosineA1 receptors self-regulate adenosine release in the striatum: evidence of autoreceptor characteristics.Adenosine Release Evoked by Short Electrical Stimulations in Striatal Brain Slices is Primarily Activity Dependent.Both synthesis and reuptake are critical for replenishing the releasable serotonin pool in Drosophila.Synapsins differentially control dopamine and serotonin releaseQuantitative evaluation of serotonin release and clearance in Drosophila.Carbon-fiber microelectrodes for in vivo applicationsSubsecond detection of physiological adenosine concentrations using fast-scan cyclic voltammetry.Carbon nanotube-modified microelectrodes for simultaneous detection of dopamine and serotonin in vivo.Fast-scan cyclic voltammetry for the detection of tyramine and octopamine.Response times of carbon fiber microelectrodes to dynamic changes in catecholamine concentration.Real-time decoding of dopamine concentration changes in the caudate-putamen during tonic and phasic firing.Regional Variations of Spontaneous, Transient Adenosine Release in Brain Slices.Transient changes in nucleus accumbens amino acid concentrations correlate with individual responsivity to the predator fox odor 2,5-dihydro-2,4,5-trimethylthiazoline.Virtual Issue Highlighting Selected Women Analytical Chemists.Cocaine increases dopamine release by mobilization of a synapsin-dependent reserve pool.Pharmacologically induced, subsecond dopamine transients in the caudate-putamen of the anesthetized rat.Drosophila as a Model System for Neurotransmitter Measurements.Nicotinic acetylcholine receptor (nAChR) mediated dopamine release in larval Drosophila melanogaster.Early changes in transient adenosine during cerebral ischemia and reperfusion injury.Electrochemical Measurements of Acetylcholine-Stimulated Dopamine Release in Adult Drosophila melanogaster Brains3D-Printed Carbon Electrodes for Neurotransmitter Detection3D-Printed Carbon Electrodes for Neurotransmitter DetectionEpoxy insulated carbon fiber and carbon nanotube fiber microelectrodesCaffeine Modulates Spontaneous Adenosine and Oxygen Changes during Ischemia and ReperfusionExpanding University Student Outreach: Professional Development Workshops for Teachers Led by Graduate Students
P50
Q26796285-6616B305-16FD-4E40-89F9-2E82C9248969Q30252591-D5478F95-4FB9-41E4-B0A8-6CBCC03BD628Q30252748-7F351337-372F-4614-9A25-AE5960FC4130Q30274772-732FC887-93E9-49FD-8266-FA0C3572CCFAQ30274955-C8BE7472-A920-401C-97A6-95E0D630AE29Q30275036-1E646287-2363-49B9-8F04-BC209BA97FB8Q30371354-8EE9B2CF-A945-4B34-BA0B-225BCAEB688BQ30371401-2BCE6F97-F03B-4DEF-B830-AF592CE50F93Q30379958-FDBAF806-DBC2-4D53-8BEB-EADCF6481023Q30384461-EED35319-F84C-4DBB-ADB2-5C30D1256072Q30398241-9829EFCF-629B-4BD0-9152-425CAC999975Q30413072-41D52DC3-547A-48C6-A6E0-580C758B0D2DQ30413724-633F29A0-88EE-456C-914B-EEABC870A9B5Q30414925-7B7D5B5C-AD4C-4C63-A301-D29C10091B96Q30418355-6D3714FE-7E24-4B67-8ABA-6B5890EF0F55Q30429218-EBB774E5-9F1E-4526-93DD-86435CF79B05Q30430403-2F09EC49-01DB-469B-B337-210833FC4C30Q30432852-0D86D677-6F51-408D-B32E-04F982977C83Q30433690-AA5B4F76-1367-489C-859B-6D5E6E56C4DDQ30436140-190BC612-425C-4B85-9FFB-BA5727072F76Q30437442-51F0AD4C-3CB1-464C-8C53-DE93FAA31DBDQ30442596-B126419A-6C26-444D-A69F-732C858027EBQ30444306-9277088F-CAAD-49A2-A2B7-2195B12A412EQ30447800-67528DC5-A742-40A1-A264-658FD7E669A1Q42170596-159A6242-9209-4BB5-9E95-CEC1C2BF7C49Q44658060-4926B76E-71F5-4916-B870-BA9BB85478D4Q45072902-1FA0A8AE-05C9-4A58-83C8-729AA2D79E4CQ46814134-7F88C713-263F-43DA-8C1B-472D310C970DQ48096850-6B03E47A-4AF4-40D5-8898-0E0468FFA9DFQ48608171-4953493D-AE0E-40A0-9AE6-2A2A2DFBA61DQ48648963-6BA7BD91-900A-47D3-BC63-3E860F98D94BQ50056855-B4DF70CC-495B-4255-ABC3-73D750A97F91Q50153910-5213FE29-91E9-439E-B172-BD083B92FF66Q55039936-8D2D544B-3D55-4710-A953-550EC24EFCC6Q56334117-F14D6619-AC99-473F-BD91-5D8BCDA28759Q57442662-54E36AF7-A650-4E26-A430-B193EBBB5D87Q57442664-B994D405-BAC9-49EA-B0AD-C9D240303DEBQ57444248-B654972A-1CF0-4654-A66E-51517FCAD323Q57449740-BF601BCC-564C-4FA2-9B16-6F0D08187817Q57449744-D92CAF4C-56F6-493A-8EB4-497941063477
P50
description
Forscher
@de
chercheur
@fr
investigador
@es
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
研究者
@zh
name
B. Jill Venton
@ast
B. Jill Venton
@en
B. Jill Venton
@es
B. Jill Venton
@nl
type
label
B. Jill Venton
@ast
B. Jill Venton
@en
B. Jill Venton
@es
B. Jill Venton
@nl
prefLabel
B. Jill Venton
@ast
B. Jill Venton
@en
B. Jill Venton
@es
B. Jill Venton
@nl
P1053
A-2902-2008
P106
P31
P3829
P496
0000-0002-5096-9309