Cerebellar-dependent motor learning is based on pruning a Purkinje cell population response.
about
Strength and timing of motor responses mediated by rebound firing in the cerebellar nuclei after Purkinje cell activationVisual Space Constructed by Saccade Motor MapsCircuit mechanisms underlying motor memory formation in the cerebellum.Perceptual task induces saccadic adaptation by target selection.Cerebellar contributions to adaptive control of saccades in humans.Similarities in error processing establish a link between saccade prediction at baseline and adaptation performance.Changes in simple spike activity of some Purkinje cells in the oculomotor vermis during saccade adaptation are appropriate to participate in motor learning.Fine-scale plasticity of microscopic saccadesSaccade and vestibular ocular motor adaptation.Releasing dentate nucleus cells from Purkinje cell inhibition generates output from the cerebrocerebellumContext-specific saccadic adaptation in monkeys.Disruption of saccadic adaptation with repetitive transcranial magnetic stimulation of the posterior cerebellum in humans.Behavior of the oculomotor vermis for five different types of saccade.Brain processing of visual information during fast eye movements maintains motor performance.Changes in Purkinje cell simple spike encoding of reach kinematics during adaption to a mechanical perturbation.Effect of inactivation and disinhibition of the oculomotor vermis on saccade adaptationCerebellar transcranial direct current stimulation effects on saccade adaptationThe role of the posterior cerebellum in saccadic adaptation: a transcranial direct current stimulation studyDevelopment of cerebellar connectivity in human fetal brains revealed by high angular resolution diffusion tractographyAdaptation and adaptation transfer characteristics of five different saccade types in the monkey.Oculomotor Adaptation Elicited By Intra-Saccadic Visual Stimulation: Time-Course of Efficient Visual Target PerturbationEncoding of action by the Purkinje cells of the cerebellum.Head-unrestrained gaze adaptation in the rhesus macaque.Multiplexed coding by cerebellar Purkinje neuronsEncoding and decoding of learned smooth-pursuit eye movements in the floccular complex of the monkey cerebellum.The same oculomotor vermal Purkinje cells encode the different kinematics of saccades and of smooth pursuit eye movementsVisuomotor cerebellum in human and nonhuman primates.The role of the cerebellum in saccadic adaptation as a window into neural mechanisms of motor learning.The multiple roles of Purkinje cells in sensori-motor calibration: to predict, teach and command.From cerebellar texture to movement optimization.The Errors of Our Ways: Understanding Error Representations in Cerebellar-Dependent Motor Learning.Smooth pursuit adaptation (SPA) exhibits features useful to compensate changes in the properties of the smooth pursuit eye movement system due to usage.The reference frames in saccade adaptation.Impairment of saccade adaptation in a patient with a focal thalamic lesion.A vermal Purkinje cell simple spike population response encodes the changes in eye movement kinematics due to smooth pursuit adaptation.Change in sensitivity to visual error in superior colliculus during saccade adaptation.Synchrony and neural coding in cerebellar circuits.Changes in control of saccades during gain adaptation.Saccadic Adaptation in 10-41 Month-Old Children.Saccadic adaptation to a systematically varying disturbance.
P2860
Q24630442-17841819-447A-4EE7-8416-3A37F47C7CE1Q26744738-0B775FE9-B53E-445E-A075-BD42E3EBBB70Q27305743-36ECC437-5BB0-4DDA-A3DC-2046D2A508CBQ27317794-3AF3FB40-ED20-4E4B-B2CB-E5AD71469811Q30497510-23DB6E36-A619-4E01-851A-6D8EB8B43D95Q33708068-80BE4E39-51E1-4262-B78B-9AB2513B71FFQ33828759-6F629D4D-95B7-4671-AAA6-C636614E65FCQ34091162-452C3064-482C-4CD6-8226-12826F6AE9D3Q34163248-DD36DFC1-9BBB-4953-8F32-A300B63F2E9CQ34287294-E2397BD7-9D8F-41BD-94E2-32285055534DQ34288540-E6D782CF-2116-4FCA-8D16-E45A25FEA69EQ34376641-BA7849B5-BB47-4172-967A-58D4DAD1DBCEQ34430309-C69E5A06-B665-404F-A9F3-E5FFA3047D66Q34575558-3157A08F-BC56-4BF9-9084-05C3DC59D84AQ34989944-86A7D39B-EE21-4A2F-966A-957D9906A9D9Q35072061-0C19FD4C-14CE-4915-BF5B-042FB4BB6997Q35188195-C04752E5-82B2-49BD-9838-93D577FAC188Q35307517-323B3927-3BBF-4EFF-BDC1-22A5DA13322EQ35446844-E8A52522-60BF-4ED4-B605-E1906AEFA8FDQ35867519-17B78FDF-CE1F-47AE-84CF-ADF5FD745310Q36665555-D08687DB-0D6B-44CB-956A-462A5D01A56CQ36876842-D038EA6F-C0C9-489E-B453-92FD8611DA3DQ37086525-C5A30121-965C-44EF-B3F3-852FE0F4F5EBQ37127353-D4AA761D-A333-45CD-8A73-6C2BCE6E9229Q37416693-997165B7-9AE7-4512-981C-D5B2BBB5DEFBQ37587594-BEE1F534-A0C1-4035-B9AC-AC9CAF23059BQ37784430-406EBADA-1B1A-43BF-B380-47D3893C40D5Q37885425-DDB61E20-2737-4B06-8B75-4B3796342310Q37891431-8884A094-7A2B-4C05-93B6-B1D6FAB6AB18Q38231028-22C45DDB-32C9-484B-B79A-CFBEBBD91569Q38538080-D86C9F34-F88C-48CC-9F0E-A4819954EDA3Q39305081-1A34CDC1-0C6C-408F-A63A-C59B1EE66932Q39886693-C3C3383A-B9D3-4871-95EC-D1D39E95FE7FQ40155326-E21E8C4F-971B-4027-A5D8-58F7DADF1A63Q41205724-7A93B4D9-1802-479F-BA0C-C181EEA352F7Q41547817-09EC88B5-3296-4EA4-A932-CEE837E5A2B0Q41942928-6044492D-1D91-4B32-9B5C-FE77D7D5F021Q42011107-E5B9A57B-D266-4DDC-91BC-2770E9726F47Q42159415-208FF9D8-7F08-4785-AD4E-FD943B9B0D07Q42388446-1A4B391B-AF87-4C04-BEE3-9CD7528BDB15
P2860
Cerebellar-dependent motor learning is based on pruning a Purkinje cell population response.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
2008年论文
@zh
2008年论文
@zh-cn
name
Cerebellar-dependent motor lea ...... inje cell population response.
@ast
Cerebellar-dependent motor lea ...... inje cell population response.
@en
type
label
Cerebellar-dependent motor lea ...... inje cell population response.
@ast
Cerebellar-dependent motor lea ...... inje cell population response.
@en
prefLabel
Cerebellar-dependent motor lea ...... inje cell population response.
@ast
Cerebellar-dependent motor lea ...... inje cell population response.
@en
P2860
P356
P1476
Cerebellar-dependent motor lea ...... inje cell population response.
@en
P2093
Nicolas Catz
Peter W Dicke
P2860
P304
P356
10.1073/PNAS.0706032105
P407
P50
P577
2008-05-13T00:00:00Z