Neuroplasticity in the context of motor rehabilitation after stroke.
about
Magnetoencephalography in Stroke Recovery and RehabilitationApplication of Transcranial Direct Current Stimulation in Neurorehabilitation: The Modulatory Effect of SleepUpper Limb Immobilisation: A Neural Plasticity Model with Relevance to Poststroke Motor RehabilitationIschemic stroke and repair: current trends in research and tissue engineering treatmentsEffects of alternating current stimulation on the healthy and diseased brain.Auditory rhythmic cueing in movement rehabilitation: findings and possible mechanismsNeurophysiology of robot-mediated training and therapy: a perspective for future use in clinical populationsBaseline frontostriatal-limbic connectivity predicts reward-based memory formation.Brain stimulation: Neuromodulation as a potential treatment for motor recovery following traumatic brain injuryCombinations of stroke neurorehabilitation to facilitate motor recovery: perspectives on Hebbian plasticity and homeostatic metaplasticitySpasticity, Motor Recovery, and Neural Plasticity after Stroke.EEG Brain Activity in Dynamic Health Qigong Training: Same Effects for Mental Practice and Physical Training?Music-supported motor training after stroke reveals no superiority of synchronization in group therapy.The role of auditory feedback in music-supported stroke rehabilitation: A single-blinded randomised controlled intervention.Diffusion tensor MRI tractography reveals increased fractional anisotropy (FA) in arcuate fasciculus following music-cued motor training.Old Dogs Learning New Tricks: Neuroplasticity Beyond the Juvenile PeriodKinematic and neurophysiological consequences of an assisted-force-feedback brain-machine interface training: a case study.Decoding continuous limb movements from high-density epidural electrode arrays using custom spatial filtersModulating the motor system by action observation after strokeCombining Multiple Types of Motor Rehabilitation Enhances Skilled Forelimb Use Following Experimental Traumatic Brain Injury in RatsMirror symmetric bimanual movement priming can increase corticomotor excitability and enhance motor learningChronic deep cerebellar stimulation promotes long-term potentiation, microstructural plasticity, and reorganization of perilesional cortical representation in a rodent modelQuantification of task-dependent cortical activation evoked by robotic continuous wrist joint manipulation in chronic hemiparetic stroke.Radial extracorporeal shock wave therapy improves cerebral blood flow and neurological function in a rat model of cerebral ischemiaEffects of healthy ageing on activation pattern within the primary motor cortex during movement and motor imagery: an fMRI study.Toward a more personalized motor function rehabilitation in Myotonic dystrophy type 1: The role of neuroplasticityNon-invasive brain stimulation in neurorehabilitation: local and distant effects for motor recovery.Changes in functional brain organization and behavioral correlations after rehabilitative therapy using a brain-computer interfaceBrain-computer interface-based robotic end effector system for wrist and hand rehabilitation: results of a three-armed randomized controlled trial for chronic stroke.The neural basis of aphasia rehabilitation: evidence from neuroimaging and neurostimulation.The changeable nervous system: studies on neuroplasticity in cerebellar culturesMoving stem cells to the clinic: potential and limitations for brain repairNew rehabilitation models for neurologic inpatients in Brazil.Parietofrontal integrity determines neural modulation associated with grasping imagery after stroke.Brain-controlled neuromuscular stimulation to drive neural plasticity and functional recoveryDecoding the Attentional Demands of Gait through EEG Gamma Band Features.White matter microstructural correlates of superior long-term skill gained implicitly under randomized practiceNeural Substrates of Motor Recovery in Severely Impaired Stroke Patients With Hand ParalysisCausal Link between the Cortico-Rubral Pathway and Functional Recovery through Forced Impaired Limb Use in Rats with Stroke.EEG response varies with lesion location in patients with chronic stroke.
P2860
Q26750361-49B6EE23-9920-4FEE-947B-7C29A72A0009Q26752553-8064DFDD-B40F-4770-9DB9-00C04CC0E392Q26769058-146AA433-3262-4802-B69E-C300CB55FA0CQ26851602-F87FBD9A-9947-4B3E-B224-DEE2DDC21359Q26866407-DCAFDF4F-574E-4BED-9138-15F36F510232Q27003861-3BA79E71-060B-46FC-867A-56D99413BD40Q27008084-5E431BAF-628C-40B0-ACA3-D9F5BC02E4C4Q27335264-1CC022C1-FAD9-4A46-9BE8-1848B5DEE664Q28073809-8266EC20-BC6F-471C-BB61-8FD4F2DFC33AQ28088397-15435522-8A7D-4F90-9B1F-94B11BEF121CQ30358455-D3E7DC81-9BD3-435D-904F-B600B609C92EQ30362943-78A5B998-1C0B-4EEB-9581-D65E83138084Q30363349-61025834-63EE-4D09-B96F-C45F01E2E8FCQ30385004-C5DFCA69-6507-4D5A-A413-F5CF9847C4A8Q30403097-A8C3E01B-AE31-46C3-9539-5E65DEBBAE2CQ30414255-8EE9493C-EC33-4F4F-B272-1059E2A1E9A5Q30447330-6E1B78CC-51DD-46D8-95E6-0848E6440A06Q30543179-F2DB7C02-6EC0-4208-B066-C889BB380CFBQ30543675-814B95A3-E93D-4C26-B75A-037F8F3C25C0Q30827139-1F7BAFD9-45F4-4018-9B6D-F72C5CB5B16BQ31053470-BEFECBE9-8295-42A5-95E4-D82CDBB016EEQ31171238-49DE8920-35C9-4663-8F24-E516F3719C76Q33568757-057CFD41-E8D2-4421-B7B3-0C6501ABEDA0Q33623223-6966900D-E435-47AC-BD50-BC4DEA52B765Q33699064-24C5B0E0-38F3-42E5-B30B-B403DAC4CFD3Q33728563-11DFF8C0-DC3A-4BCD-B6CD-70496A456044Q33813339-CBC59516-5E3D-403D-A0CF-12633696D182Q33898187-D3E37F3F-110F-431E-830E-A6BBDBBA24D6Q33965487-B1AE6CD9-1BE2-4712-9E23-130F5510BA2BQ34051509-2ADD6DDC-6439-4ACA-BDA6-CC31FD49CC4EQ34115220-94B97CDE-E7C8-4539-A115-F84B654948FBQ34470920-8166FB91-8CF4-4C3C-9E5C-FCB32251A043Q35190095-868BF722-3743-40DC-8605-EDAF7F8DC15EQ35776369-53FE1722-D02C-4F00-BD0C-1DF711D77F19Q35912182-00DC7A27-D170-45FF-AECC-895C30FE68F9Q35999490-88E48FBE-83EF-43D9-9F23-3DE7687CF3BFQ36041426-1D933A10-5617-43D0-AF76-9927429A0142Q36447816-CD79F13D-2C34-441B-A108-71A5090941CAQ36456682-D1121B55-8D02-440F-AF4B-99BCE5FCF455Q36646167-ABE11D5E-80B7-4005-80F1-F464C699D95B
P2860
Neuroplasticity in the context of motor rehabilitation after stroke.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年論文
@yue
2011年論文
@zh-hant
2011年論文
@zh-hk
2011年論文
@zh-mo
2011年論文
@zh-tw
2011年论文
@wuu
2011年论文
@zh
2011年论文
@zh-cn
name
Neuroplasticity in the context of motor rehabilitation after stroke.
@en
type
label
Neuroplasticity in the context of motor rehabilitation after stroke.
@en
prefLabel
Neuroplasticity in the context of motor rehabilitation after stroke.
@en
P2860
P1476
Neuroplasticity in the context of motor rehabilitation after stroke
@en
P2093
Leonardo G Cohen
P2860
P2888
P356
10.1038/NRNEUROL.2010.200
P407
P577
2011-01-18T00:00:00Z