Cerebellar plasticity and the automation of first-order rules.
about
Consensus paper: the cerebellum's role in movement and cognitionDelegation to automaticity: the driving force for cognitive evolution?Cerebellar contributions to motor control and language comprehension: searching for common computational principles.Cerebellar integrity in the amyotrophic lateral sclerosis-frontotemporal dementia continuumDifferentiating neural systems mediating the acquisition vs. expression of goal-directed and habitual behavioral control.Single session imaging of cerebellum at 7 Tesla: obtaining structure and function of multiple motor subsystems in individual subjects.Motor Demands Constrain Cognitive Rule Structures.Attention to Automatic Movements in Parkinson's Disease: Modified Automatic Mode in the Striatum.Social and monetary reward processing in autism spectrum disorders.Differential brain shrinkage over 6 months shows limited association with cognitive practice.Cerebellar BOLD signal during the acquisition of a new lexicon predicts its early consolidation.Volumetric analysis of regional variability in the cerebellum of children with dyslexia.Cerebellar tDCS does not improve performance in probabilistic classification learningThe time course of task-specific memory consolidation effects in resting state networks.Sensory integration, sensory processing, and sensory modulation disorders: putative functional neuroanatomic underpinnings.Frontal lobe and posterior parietal contributions to the cortico-cerebellar system.The cerebellum for jocks and nerds alike.The Next Step: A Common Neural Mechanism for Freezing of Gait.Motor automaticity in Parkinson's disease.The Errors of Our Ways: Understanding Error Representations in Cerebellar-Dependent Motor Learning.Are individuals with higher psychopathic traits better learners at lying? Behavioural and neural evidenceDecreased cerebellar-cerebral connectivity contributes to complex task performanceBridging the gap between functional and anatomical features of cortico-cerebellar circuits using meta-analytic connectivity modeling.Cerebellum and neurodegenerative diseases: Beyond conventional magnetic resonance imaging.Sleep-dependent neurophysiological processes in implicit sequence learning.Hierarchical control of procedural and declarative category-learning systems.Move faster, think later: Women who play action video games have quicker visually-guided responses with later onset visuomotor-related brain activity.Non-invasive Cerebellar Stimulation: a Promising Approach for Stroke Recovery?Altered gray matter volume and functional connectivity of the motor network in young divers.Cerebellum and cognition: evidence for the encoding of higher order rules.Cerebellar atrophy in Parkinson's disease and its implication for network connectivity.Cerebellum engages in automation of verb-generation skill.Gender-related differences in neural responses to gaming cues before and after gaming: Implications for gender-specific vulnerabilities to Internet gaming disorder
P2860
Q28655933-2D5F5CF1-DA18-4699-A1FD-E877339F5159Q28657942-820E2F3F-E7E4-4C09-9B23-ED5A6E69A07FQ30365118-52034026-4967-4C72-BB4B-20F38CE8129FQ34075618-362E04B3-E883-4536-8C57-49C03DC40E6FQ35734462-D2CEE77D-1737-4E2B-A65C-D53A622607D8Q35741549-5D0528DF-09EB-4AC7-9642-A24F7AC7BF48Q35953675-0DAA171F-A388-4972-A5AE-77487C35F743Q36139227-DCC456AD-D6F0-4093-AB49-EA011BA462CEQ36403101-2946A754-F8BA-49D3-BBAF-F85FD2C8F756Q36888187-B1EA993F-22D6-487D-832B-37C275E0406AQ37344379-27F5BE53-B3CD-4644-BE2D-94F85F5550ACQ37477728-B06A659C-4DA2-4213-AFC8-7AD3DB11A1B4Q37610813-91E7F9DF-8815-4F7D-BD72-93C7EC756F92Q37633622-73F23402-E69E-4452-8B6E-B45DFE6399C8Q37883158-C1B0AE12-CAEB-4A4B-853E-68C93FBF9E1CQ37889167-497BC5D4-6F59-4C2E-91B2-1DCD8509747EQ38225538-0FBB5E79-BB77-4791-AB7A-5EC11C8E1437Q38268278-F69AFA54-C16D-4C09-AEE9-D672873FFAC8Q38535233-8B234EE6-2BDD-4FA8-9DE8-AF40E68989DAQ38538080-E13E1427-7722-49D8-BE30-14E73D6CEE9DQ41197055-092EBADB-B56F-444B-AC23-27DA55491E51Q41207407-3A59870C-6FF1-46C9-BD77-C2531D2EFF29Q41915570-EE6EC456-1B53-441B-BAA2-1FBD85C108B7Q44772136-36C311F5-4270-476F-B80F-33B079091481Q46006368-1A031891-6EC2-42BA-9825-7A99B394C1F6Q46124902-0A21997D-0CD3-41AA-BDB5-91F9D0A8B5E4Q47549488-084DE75D-A70E-491D-9B43-833960C285CFQ47914886-AB6A4E8B-1C6B-43C0-BE42-F48FB8AAD349Q48201051-4A115A24-0A86-4754-B13C-B2CD5A95AFCCQ48497872-1F0EDF84-2DDB-4E6D-9619-60333D4F118DQ48958384-5D2F6809-A1F6-4279-A37A-BBAD6BE78B24Q50648317-10DB7EE6-206E-4F28-908D-9C90F9C1F456Q57067761-4FC2B910-CB68-4D96-A866-4E47DA1AAA90
P2860
Cerebellar plasticity and the automation of first-order rules.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年学术文章
@wuu
2011年学术文章
@zh
2011年学术文章
@zh-cn
2011年学术文章
@zh-hans
2011年学术文章
@zh-my
2011年学术文章
@zh-sg
2011年學術文章
@yue
2011年學術文章
@zh-hant
name
Cerebellar plasticity and the automation of first-order rules.
@en
Cerebellar plasticity and the automation of first-order rules.
@nl
type
label
Cerebellar plasticity and the automation of first-order rules.
@en
Cerebellar plasticity and the automation of first-order rules.
@nl
prefLabel
Cerebellar plasticity and the automation of first-order rules.
@en
Cerebellar plasticity and the automation of first-order rules.
@nl
P1476
Cerebellar plasticity and the automation of first-order rules
@en
P304
P356
10.1523/JNEUROSCI.4358-10.2011
P407
P577
2011-02-01T00:00:00Z