CaRuby-Nano: a novel high affinity calcium probe for dual color imagingTargeting neurons and photons for optogeneticsPurkinje cells in awake behaving animals operate in stable upstate membrane potentialBistability of cerebellar Purkinje cells modulated by sensory stimulationTraveling waves in developing cerebellar cortex mediated by asymmetrical Purkinje cell connectivity.Parallel processing of visual space by neighboring neurons in mouse visual cortex.Dendritic patch-clamp recording.Predicting the synaptic information efficacy in cortical layer 5 pyramidal neurons using a minimal integrate-and-fire model.One rule to grow them all: a general theory of neuronal branching and its practical applicationInitiation of simple and complex spikes in cerebellar Purkinje cells.Sensitivity to perturbations in vivo implies high noise and suggests rate coding in cortexIntegration of quanta in cerebellar granule cells during sensory processing.Target-specific effects of somatostatin-expressing interneurons on neocortical visual processingDendritic spikes mediate negative synaptic gain control in cerebellar Purkinje cellsDendritic enlightenment: using patterned two-photon uncaging to reveal the secrets of the brain's smallest dendrites.Inverse Stochastic Resonance in Cerebellar Purkinje Cells.Encoding of oscillations by axonal bursts in inferior olive neuronsElectrophysiology in the age of light.Dendrites: bug or feature?Reading out a spatiotemporal population code by imaging neighbouring parallel fibre axons in vivo.Quantitative comparison of genetically encoded Ca indicators in cortical pyramidal cells and cerebellar Purkinje cellsCerebellar LTD and pattern recognition by Purkinje cells.Neuronal microcircuits: frequency-dependent flow of inhibition.A scaling law derived from optimal dendritic wiring.Targeted dendrotomy reveals active and passive contributions of the dendritic tree to synaptic integration and neuronal output.All-Optical Interrogation of Neural CircuitsDendritic computation.Control of cerebellar granule cell output by sensory-evoked Golgi cell inhibition.Inhibition dominates sensory responses in the awake cortex.Neural coding: hybrid analog and digital signalling in axons.An excitatory basis for divisive normalization in visual cortexMillisecond Coupling of Local Field Potentials to Synaptic Currents in the Awake Visual CortexConditional Spike Transmission Mediated by Electrical Coupling Ensures Millisecond Precision-Correlated Activity among Interneurons In Vivo.Simultaneous all-optical manipulation and recording of neural circuit activity with cellular resolution in vivoDendritic excitability and synaptic plasticity.Dendritic calcium signaling triggered by spontaneous and sensory-evoked climbing fiber input to cerebellar Purkinje cells in vivo.Synaptically induced long-term modulation of electrical coupling in the inferior oliveThe single dendritic branch as a fundamental functional unit in the nervous system.How to build a grid cell.Optogenetics: the age of light.
P50
Q21128761-20A28949-4EF1-439B-B98B-9CE2B64E0A01Q27023926-0D3A0DE1-6906-495D-8A60-97F9B6F57F67Q29035717-BD57D990-3CF5-4947-9963-CFF38FD9E515Q30048329-4252E798-CBE7-4984-BACD-1441FDD9F87FQ30495784-F804DF74-4A30-4C91-82B5-0F4B48E9D5B1Q30497618-BD60CB0E-7DDB-410C-A5EC-320A088784FAQ33280956-3D3366C7-55AA-4F68-9D41-14BDDC34D33FQ33557166-4FA3A7A2-C714-498A-BDF6-A6EB4DFDEF3EQ33654178-DC90A92A-8DE9-462F-8D72-909FD678EB54Q33922520-FC4F7291-8F8D-4FF7-997D-E978ED25674EQ33969410-C0890A84-12F1-43FB-8BBB-6E3093B62EC3Q34315693-336C7CDC-789A-4E7F-94C1-D0EE191E538EQ34391868-A215D126-3A86-4681-BCDC-C50D09B45402Q34438481-21EF5AD7-F8EB-4E82-B750-B433C23F380CQ34516291-AC01CDFF-2DFC-45F6-B4F5-7401F6300E25Q34537878-BAEE0D05-2FAF-4720-AF02-07F759A286D4Q34981349-25C6619C-8A03-4620-AC87-BAFDB817997EQ35008002-BB307513-2465-4F06-AD69-E7C84EE4AFCAQ35172828-0301845B-CE1A-4A85-A2AE-633583710F1BQ35196975-C4CED2B6-F236-4343-9657-A7B5BE4FC999Q35238198-1001C0A0-DB0D-48B7-8FD2-1CB581F42280Q35830172-12E10934-B336-4FDB-BFCF-A2D8140274EBQ35905591-19C17159-2D50-49AB-8DA1-B7BF1396516BQ36079342-EED7B9ED-B6BA-443F-B89B-B863B19C7B9CQ36090215-04D11532-B152-44D9-B4E0-C766D6C00198Q36157770-DCF5F44D-3FCD-47A1-8B67-7F0ACCCF4A49Q36201603-06BEBDB0-4E38-489D-9960-C6B9D24F672BQ36207379-845B7701-292A-4CA6-A22D-C00D040A0718Q36510784-80C0F425-7CCA-4160-82BE-B9A11FA2AF9DQ36557137-4E0F94DA-83BF-42E9-9AAA-BFC0C810F7F0Q36756913-4B03D264-CFBE-43EE-9C00-05F7BDBEA880Q36783150-5C4CD073-D3D6-4638-8D51-7C114369E345Q36940940-80682E9B-F591-41EA-A0EC-77DB5B86BFF2Q37065814-D3F0C2A0-9BDD-493B-8D5E-838D6546F1B1Q37129354-E5760B5E-1AB2-4E7C-BE5D-561FD43DB3FBQ37135645-EE0E5EF4-F6A0-497A-B061-DB84347D86E7Q37706526-388D2B75-7299-422E-907B-854B6C39A3DCQ37783684-82B018D2-7C5D-4FED-9F79-CB8A944F1730Q38173648-2834B0A2-168E-44EF-86A4-A1FF4A10D6D2Q38255205-33D5DCB7-AF71-492E-A203-2486C0265E72
P50
description
Professor of Neuroscience, bas ...... h at University College London
@en
onderzoeker
@nl
name
Michael Hausser
@ast
Michael Hausser
@en
Michael Hausser
@es
Michael Hausser
@fr
Michael Hausser
@nl
Michael Hausser
@sl
type
label
Michael Hausser
@ast
Michael Hausser
@en
Michael Hausser
@es
Michael Hausser
@fr
Michael Hausser
@nl
Michael Hausser
@sl
prefLabel
Michael Hausser
@ast
Michael Hausser
@en
Michael Hausser
@es
Michael Hausser
@fr
Michael Hausser
@nl
Michael Hausser
@sl
P166
P214
P244
P268
P269
P106
P1153
7003425281
P184
P2070
michael-häusser-11592
P21
P213
0000 0000 3368 1034