about
Bretylium abolishes neurotransmitter release without necessarily abolishing the nerve terminal action potential in sympathetic terminals5-Chloroindole: a potent allosteric modulator of the 5-HT₃ receptorActions of two main metabolites of propiverine (M-1 and M-2) on voltage-dependent L-type Ca2+ currents and Ca2+ transients in murine urinary bladder myocytes.The sources and sequestration of Ca(2+) contributing to neuroeffector Ca(2+) transients in the mouse vas deferens.Mechanisms involved in nicotinic acetylcholine receptor-induced neurotransmitter release from sympathetic nerve terminals in the mouse vas deferens.Intermittent ATP release from nerve terminals elicits focal smooth muscle Ca2+ transients in mouse vas deferens.Neuroeffector Ca2+ transients for the direct measurement of purine release and indirect measurement of cotransmitters in rodents.Oxaliplatin induces hyperexcitability at motor and autonomic neuromuscular junctions through effects on voltage-gated sodium channels.Prostaglandin E2 induces spontaneous rhythmic activity in mouse urinary bladder independently of efferent nerves.A Regional Reduction in Ito and IKACh in the Murine Posterior Left Atrial Myocardium Is Associated with Action Potential Prolongation and Increased Ectopic Activity.Electrical and optical study of nerve impulse-evoked ATP-induced, P2X-receptor-mediated sympathetic neurotransmission at single smooth muscle cells in mouse isolated VAS deferens.Spontaneous purinergic neurotransmission in the mouse urinary bladderEffects of 17beta-oestradiol on rat detrusor smooth muscle contractility.Ion channel modulators and urinary tract function.High-Probability Neurotransmitter Release Sites Represent an Energy-Efficient Design.Dynamic monitoring of NET activity in mature murine sympathetic terminals using a fluorescent substrateThe effect of epibatidine on spontaneous and evoked neurotransmitter release in the mouse and guinea pig isolated vas deferens.Autonomic synaptic transmission at single boutons and calyces.An automated system using spatial oversampling for optical mapping in murine atria. Development and validation with monophasic and transmembrane action potentials.Focal Ca2+ transient detection in smooth muscle.Prejunctional and postjunctional actions of heptanol and 18 beta-glycyrretinic acid in the rodent vas deferens.Parasympathetic cholinergic transmission, minus the vesicles.A Method for the Analysis of AP Foot Convexity: Insights into Smooth Muscle Biophysics.Modeling extracellular fields for a three-dimensional network of cells using NEURON.A four-component model of the action potential in mouse detrusor smooth muscle cell.Phosphorylation of proteins in chick ciliary ganglion under conditions that induce long-lasting changes in synaptic transmission: phosphoprotein targets for nitric oxide action.Calcium in sympathetic boutons of rat superior cervical ganglion during facilitation, augmentation and potentiation.Calcium transients evoked by action potentials in the somata of chick ciliary neurons.A computational model of urinary bladder smooth muscle syncytium : validation and investigation of electrical properties.Real-time stochastic detection of multiple neurotransmitters with a protein nanopore.Spatiotemporal dynamics of synaptic drive in urinary bladder syncytium: A computational investigation.Investigation of the Syncytial Nature of Detrusor Smooth Muscle as a Determinant of Action Potential ShapeA biophysically constrained computational model of the action potential of mouse urinary bladder smooth muscleSyncytial Basis for Diversity in Spike Shapes and their Propagation in Detrusor Smooth Muscle191 Advancement of Optical Mapping through Automated Algorithms and Second Generation CMOS Detectors to Reveal Murine Atrial Activation Patterns and Regional Variation of Action Potential DurationObituary: Professor Alison Brading, PhDP3.7 Cellular mechanism of action of Prostaglandin E2 on mouse urinary bladderS14.5 The effects of Δ9-tetrahydrocannabinol on sympathetic cotransmission in the mouse vas deferensCalcium in the nerve terminals of chick ciliary ganglia during facilitation, augmentation and potentiationDynamic monitoring of single-terminal norepinephrine transporter rate in the rodent cardiovascular system: A novel fluorescence imaging method
P50
Q24657727-6542284F-CCE2-4C57-BA7F-F937579EC778Q28289112-A2891B3A-9F1C-4DC0-B839-A37132325803Q30483622-5FDE89A1-A7DB-49E1-A65F-4B912CD0505CQ33193075-70FDCDAC-46F9-46BF-A892-C6CB2B7FB80FQ34117342-E5CEB33F-296F-49B3-A8F5-EDA32E9FF534Q34133704-B6ED53EF-51C3-40E0-B468-8D2225F7BFDEQ34832699-37EA11E7-331B-4338-9C47-7C581A3856BBQ35545122-1D7BA397-2BD5-4DDE-94BE-F976DF52A049Q35708152-A6D51957-5514-477F-AE0E-AE1D05FB9D7FQ36009627-2320350F-E7AE-4A17-8FD4-007DC6F361F7Q36294471-9D5EB3F9-B6EE-4193-8F20-8B4C159387A9Q37127645-0774CBED-53D1-42F0-A2ED-1A511CCC878AQ37377507-88D202E9-A0B9-46C0-B46E-BD2721347575Q37835087-3732AA18-D615-4C4B-ADC8-4B9FEA431D74Q38436124-8676F330-A4ED-447A-A3CF-D7ECDF02D301Q39300253-6C12097A-4FCC-4F31-88D1-816334305722Q41584797-DA92714B-2716-4710-8027-FB33A7BCB645Q41628312-5B808F73-3BF6-4F5B-89EE-59D3E883C050Q41871786-BF27E352-02EF-4065-B272-03FCD9587614Q42577858-13A6EC74-85B3-4E52-9936-B64A2E7A172EQ42578800-0693389D-9321-4D70-9EC9-709DB3E6B962Q43164750-D637AE8D-743D-4734-A37F-2E4A57C98CBDQ47133816-F9403E4D-F335-4B52-8C06-D94CF75263DCQ47767231-513D8869-6B59-43B2-8D33-49918D467E27Q47851708-E72B0408-194F-44E8-BE29-F1120F3B8C89Q48228976-D4053444-A233-4490-BB79-E505A0E694B2Q48354980-188235DF-2985-4FEC-B092-26FFEA01872AQ48382242-EF5DB72C-9EEA-4D73-B770-E5373146C312Q48493716-125E7CE5-86F7-496C-943A-AB8F54F60743Q48498775-576959A5-A5C7-41C4-8B51-A83F3CEA63D8Q49035392-DB26826A-15E5-4EFA-8E29-62A0A240CCC9Q57191816-0CD9C37C-C784-48ED-99B2-1163A38DA1A7Q61660281-67F1EAC4-F772-44A5-B313-B44DE3B2AAE4Q61660286-ACFD2536-A719-44A5-9C36-7C5A6AC5DD69Q61660289-3720B9CD-4971-48BB-8F64-27E83D5084EDQ61660293-58BCAE22-5745-4BD8-A4C0-04DAE5ABBECAQ61660297-B22D3326-3AFF-45F6-BDC3-A83A09DDF4C0Q61660300-3B319632-BB86-43AA-BF4D-4A6371FAD47BQ61660309-C9FAA0AB-FDC2-493C-8377-AB5156FFE6F7Q92416153-2B48A099-840B-4354-9AFD-2CB66293C13B
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Keith Brain
@en
Keith L Brain
@ast
Keith L Brain
@es
Keith L Brain
@nl
type
label
Keith Brain
@en
Keith L Brain
@ast
Keith L Brain
@es
Keith L Brain
@nl
altLabel
Keith L Brain
@en
prefLabel
Keith Brain
@en
Keith L Brain
@ast
Keith L Brain
@es
Keith L Brain
@nl
P106
P1153
36815489300
7005692977
P31
P496
0000-0002-0906-7012