Neural substrates of visuomotor learning based on improved feedback control and prediction.
about
Greater intermanual transfer in the elderly suggests age-related bilateral motor cortex activation is compensatorySensitivity of the action observation network to physical and observational learningLow-frequency transcranial magnetic stimulation over left dorsal premotor cortex improves the dynamic control of visuospatially cued actions.The DIVA model: A neural theory of speech acquisition and productionfMRI investigation of unexpected somatosensory feedback perturbation during speech.The integration of large-scale neural network modeling and functional brain imaging in speech motor controlGaze fixation improves the stability of expert jugglingModeling fMRI signals can provide insights into neural processing in the cerebral cortex.Computational and dynamic models in neuroimaging.Visuomotor adaptive improvement and aftereffects are impaired differentially following cerebellar lesions in SCA and PICA territory.The cerebellum and cognition: evidence from functional imaging studies.The neural correlates of learned motor acuityThe future of functionally-related structural change assessment.Brain representations for acquiring and recalling visual-motor adaptationsHow the brain handles temporally uncoupled bimanual movements.Dynamic sensorimotor planning during long-term sequence learning: the role of variability, response chunking and planning errors.Developing a new experimental system for an undergraduate laboratory exercise to teach theories of visuomotor learning.Characterization of information-based learning benefits with submovement dynamics and muscular rhythmicityComparison of haptic guidance and error amplification robotic trainings for the learning of a timing-based motor task by healthy seniors.Remembering forward: neural correlates of memory and prediction in human motor adaptation.Representation of limb kinematics in Purkinje cell simple spike discharge is conserved across multiple tasks.Self-regulation of circumscribed brain activity modulates spatially selective and frequency specific connectivity of distributed resting state networks.Reciprocal relations between cognitive neuroscience and formal cognitive models: opposites attract?Structural correlates of skilled performance on a motor sequence taskUpper extremity rehabilitation of stroke: facilitation of corticospinal excitability using virtual mirror paradigm.Bilateral and unilateral arm training improve motor function through differing neuroplastic mechanisms: a single-blinded randomized controlled trial.The Human Motor System Supports Sequence-Specific Representations over Multiple Training-Dependent Timescales.Individuals with cerebellar degeneration show similar adaptation deficits with large and small visuomotor errors.Preservation of motor skill learning in patients with multiple sclerosis.Structural and functional bases for individual differences in motor learning.Children with heavy prenatal alcohol exposure experience reduced control of isotonic force.Early imaging correlates of subsequent motor recovery after stroke.Gender Differences in Cognitive Control: an Extended Investigation of the Stop Signal Task.Neural correlates of learning and working memory in the primate posterior parietal cortex.Neural substrates of contingency learning and executive control: dissociating physical, valuative, and behavioral changesResting-state cortical connectivity predicts motor skill acquisition.Neural substrates of visual spatial coding and visual feedback control for hand movements in allocentric and target-directed tasks.Neural, physiological, and behavioral correlates of visuomotor cognitive load.Neurocognitive mechanisms of error-based motor learning.Effect of Error Augmentation on Brain Activation and Motor Learning of a Complex Locomotor Task.
P2860
Q28652003-72253FC5-0027-40D3-98E6-EBA5B28D927AQ30369698-A2ABD25F-CA13-4B8B-A454-6563CE94AEB8Q30451981-F1796147-B1EB-4FBB-A33B-2C24E597E959Q30454730-F03F30DC-179F-418A-A193-A7C4808B15D6Q30469114-CF6CEE3F-B771-4D25-8D6D-F4A718846A22Q30474390-A9BE3C6F-CD7C-431F-823F-F1B644120FDBQ30504545-935821A5-DD64-4CD5-82CD-EFDE3021BB54Q30951342-CA66ECE6-30C5-49A7-8FA2-8E17B6FE89E6Q33520876-71F88BD5-BE6D-40C6-91E4-1762A6F793A6Q33706674-A93E54E2-8F9C-4C93-B084-6FA4A548E50FQ33836937-0F18619A-27E9-4DE1-BAD8-F6DA517EE57EQ34006615-EEF2374D-D207-4F1A-87B8-9A8FDF2E26CEQ34067915-4F5AF0CA-7490-4994-A043-3E568620034BQ34195180-D2BCF67C-6D9B-47B5-A51A-432013EB78EAQ34413552-EBD568F8-4B4E-4E95-B80F-65A3B4909EC5Q34443029-F0D52A95-F66A-4592-ADDE-42C408A61F77Q34796116-EB5413AF-A30D-4A89-9649-C43B44822451Q35075474-73BEEF50-AA96-47FB-9B96-FE4DA12E8CB4Q35233609-ECEC9B06-870A-4EBB-A493-92A9FFB4C77DQ35375039-82A6E085-4ADA-4E2D-852B-C5CCC41BFFEFQ35544047-C17E0102-5178-4149-AAA2-3DEC2FBA156FQ35847685-7E88C7D2-61F0-48EB-80F5-CB5C972013C8Q36062562-9D60564C-B9CA-4EAB-9B55-60174C05B1A1Q36364457-DC6ABEDF-A7D4-4D61-B30A-2DF69450DAB7Q36526846-698E4C7D-2F90-41B2-BC80-C41A4280B40AQ36544148-034A8E83-80B5-40D6-99FB-30ABC17976DAQ36562945-62F22840-EF86-4D12-8883-6312D36ACCD0Q36600783-A60FFC61-7F3B-410A-BC2B-A5945961FD9DQ36898750-3E5A3884-68E2-4E70-B643-5240525CFADBQ36907467-FF19E848-10E4-4A05-8F3D-BA87B56C069CQ37117221-A88A3A81-6E24-4790-A142-8F1D34D85CC1Q37307327-E78AEDB9-C97A-440C-808B-B75204422F37Q37310456-DAC31EA5-F1F2-469F-BA35-24DE78AF1AFDQ37360268-02E67C25-3D19-4A68-B25B-E20256E2A2D5Q37381161-DE70B3FD-AD79-47EF-BC1B-2E9ADC779EEFQ37662671-59D52BBC-1766-4CE8-8192-C3D98F9C3CC4Q38371411-77F9CBC4-8A23-4059-8975-7F29C8A36CE6Q38617976-6E08CF8E-8112-42FB-A3B4-B61963ED248FQ41887475-35E34090-7479-4B49-8B89-735D764BE2ABQ42288839-20E8F463-B2AA-46AB-A5AF-6B9FFDCAE448
P2860
Neural substrates of visuomotor learning based on improved feedback control and prediction.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年学术文章
@wuu
2007年学术文章
@zh-cn
2007年学术文章
@zh-hans
2007年学术文章
@zh-my
2007年学术文章
@zh-sg
2007年學術文章
@yue
2007年學術文章
@zh
2007年學術文章
@zh-hant
name
Neural substrates of visuomoto ...... edback control and prediction.
@ast
Neural substrates of visuomoto ...... edback control and prediction.
@en
type
label
Neural substrates of visuomoto ...... edback control and prediction.
@ast
Neural substrates of visuomoto ...... edback control and prediction.
@en
altLabel
Neural substrates of visuomoto ...... eedback control and prediction
@en
prefLabel
Neural substrates of visuomoto ...... edback control and prediction.
@ast
Neural substrates of visuomoto ...... edback control and prediction.
@en
P2860
P1433
P1476
Neural substrates of visuomoto ...... edback control and prediction.
@en
P2093
Paul Schmitt
Scott T Grafton
P2860
P304
P356
10.1016/J.NEUROIMAGE.2007.09.062
P407
P577
2007-10-12T00:00:00Z