CSF-contacting neurons regulate locomotion by relaying mechanical stimuli to spinal circuits.Fast Calcium Imaging with Optical Sectioning via HiLo MicroscopyThree-dimensional spatiotemporal focusing of holographic patternsSmelling a single component of male sweat alters levels of cortisol in womenRemote z-scanning with a macroscopic voice coil motor for fast 3D multiphoton laser scanning microscopyCholinergic left-right asymmetry in the habenulo-interpeduncular pathwayZebraZoom: an automated program for high-throughput behavioral analysis and categorizationHierarchy of neural organization in the embryonic spinal cord: Granger-causality graph analysis of in vivo calcium imaging data.Investigation of spinal cerebrospinal fluid-contacting neurons expressing PKD2L1: evidence for a conserved system from fish to primatesThe dual developmental origin of spinal cerebrospinal fluid-contacting neurons gives rise to distinct functional subtypesMechanosensory neurons control the timing of spinal microcircuit selection during locomotionA light-gated, potassium-selective glutamate receptor for the optical inhibition of neuronal firing.Emergence of patterned activity in the developing zebrafish spinal cordRemote control of neuronal activity with a light-gated glutamate receptor.Comparative distribution and in vitro activities of the urotensin II-related peptides URP1 and URP2 in zebrafish: evidence for their colocalization in spinal cerebrospinal fluid-contacting neurons.Filtering of visual information in the tectum by an identified neural circuit.Deletion of a kinesin I motor unmasks a mechanism of homeostatic branching control by neurotrophin-3.State-Dependent Modulation of Locomotion by GABAergic Spinal Sensory Neurons.Plaque-induced neurite abnormalities: implications for disruption of neural networks in Alzheimer's disease.Colloid-guided assembly of oriented 3D neuronal networks.Optogenetic dissection of a behavioural module in the vertebrate spinal cord.Optogenetics: a new enlightenment age for zebrafish neurobiology.Let there be light: zebrafish neurobiology and the optogenetic revolution.Optogenetics in a transparent animal: circuit function in the larval zebrafish.Inhibition and motor control in the developing zebrafish spinal cord.Spinal sensory circuits in motion.Intraspinal Sensory Neurons Provide Powerful Inhibition to Motor Circuits Ensuring Postural Control during Locomotion.Constrained synaptic connectivity in functional mammalian neuronal networks grown on patterned surfaces.Dynamics of excitatory synaptic components in sustained firing at low rates.Endothelial cilia mediate low flow sensing during zebrafish vascular development.BEHAVIOR. A brain conditioned for social defeat.Tracking microscopy enables whole-brain imaging in freely moving zebrafish.Neuronal wiring: linking dendrite placement to synapse formation.Locomotion: Electrical Coupling of Motor and Premotor Neurons.Investigation of hindbrain activity during active locomotion reveals inhibitory neurons involved in sensorimotor processingMultiplexed temporally focused light shaping for high-resolution multi-cell targetingOptogenetic neuromodulation: New tools for monitoring and breaking neural circuitsBuilding behaviors, one layer at a timeA calibrated optogenetic toolbox of stable zebrafish opsin linesOrigin and role of the cerebrospinal fluid bidirectional flow in the central canal
P50
Q27325769-6958B23E-088C-4A45-899A-44FE6B03E39DQ27339307-BAB9A723-75EA-4B0B-9BB6-ADF5213ED6FBQ27342994-7E4BB510-99B7-447E-A50C-5F97A286E988Q28287321-589102B6-5EF6-43A9-A8C1-5786B41915D4Q30383025-FAA4A668-009E-4E80-B536-4C4A12A1BD7DQ30412360-DE24B513-29BF-4FC3-832E-A54F9FE26660Q30540558-18924649-7D15-426A-B450-69D20AF32A81Q30842707-CE5E2AC8-4970-4540-BB92-59FF0669D3F7Q33600510-039A8268-91FF-4DE9-A18A-1A79ABEA64D8Q33670972-421E0CE8-DA29-42B9-84F2-EF4FE283E537Q33879245-C090419E-83B1-4820-90E7-4AD47193D9F1Q34043480-4DF9A651-B157-485C-BF17-D90E71ACA0A7Q34242855-EBAFEF21-0D21-4219-973E-68D36A309BACQ34631094-F05955AF-43D1-44F3-9804-FFC2B9B9FA11Q35191049-81140AEF-00D1-4BAB-821E-D65E07BD8DDCQ35626742-EF88F54A-D04B-43A6-B10F-1B02E43D7BB4Q35664198-95343E2E-5A46-4609-945F-B9654BFFD553Q35890373-1D7F5EAD-A75B-474D-AB32-5C063F87D353Q36342344-C2592C73-5B43-4A9D-AA64-DF312C401D50Q37269785-806FCDFB-E2AA-4C7B-83BE-2E4E20D81AE4Q37405062-02C16F4C-2120-4AB2-8A63-FF98406D5135Q37875036-0CE77FF2-05B1-4B2A-8B3F-15B4D2DAEE1DQ37880100-3501C88A-B9A3-4014-904B-CEB9BE2C0ACDQ38067974-55C7781F-46E0-4A26-9021-8505AFC35D1BQ38179738-F8C9B2E5-1752-4F63-96AB-D8D53436D983Q38940233-2C32D0EE-D758-4AFD-8BA5-FE57EC928D6FQ39308550-6328F9A7-3C41-4670-A2C6-9DE555B081BAQ44052352-60423F97-782B-4123-9B58-6691146DEDE7Q45240133-3BD42B33-1BCA-4F63-A0C8-F05D35029B63Q46040457-4229165C-0139-4E5A-968F-FD1A415F42D4Q47439086-BDB05421-D79C-47F7-89E1-F8DACD3D75E4Q47993492-A06972A8-E2C3-4A04-A160-0A503E002C85Q52794263-F9A514A6-F696-4819-BC3A-CF1CFD35FA42Q53140156-2B7D518E-526F-480A-85DD-F00494611D8FQ58751577-33C6536F-C854-432B-A622-526173D0608EQ60365035-272CCDAF-D799-4BFE-990A-D74E06D39E5EQ60365064-6B09EA9B-4A4A-439B-BE36-5B98D4A668CAQ64075878-EEE2094D-AD20-429E-8298-C9FA4BF1DEEDQ90683969-8C8340BA-336A-40F8-ADAB-63FADD7AFD55Q92513013-32CF467B-BBE5-45EA-B6D4-CD4592F93E43
P50
description
Frans neurowetenschapster
@nl
French biophysicist and neuroscientist
@en
biophysicienne et neuroscientifique française
@fr
neurocientífica francesa
@ast
neurocientífica francesa
@es
французский нейробиолог
@ru
عالمة أعصاب فرنسية
@ar
name
Claire Wyart
@ast
Claire Wyart
@ca
Claire Wyart
@de
Claire Wyart
@en
Claire Wyart
@es
Claire Wyart
@fi
Claire Wyart
@fr
Claire Wyart
@it
Claire Wyart
@nl
Claire Wyart
@oc
type
label
Claire Wyart
@ast
Claire Wyart
@ca
Claire Wyart
@de
Claire Wyart
@en
Claire Wyart
@es
Claire Wyart
@fi
Claire Wyart
@fr
Claire Wyart
@it
Claire Wyart
@nl
Claire Wyart
@oc
altLabel
Вияр, Клер
@ru
prefLabel
Claire Wyart
@ast
Claire Wyart
@ca
Claire Wyart
@de
Claire Wyart
@en
Claire Wyart
@es
Claire Wyart
@fi
Claire Wyart
@fr
Claire Wyart
@it
Claire Wyart
@nl
Claire Wyart
@oc
P108
P69
P214
P269
P1053
H-3783-2016
P19
P21
P213
0000 0003 5815 8014