Rewiring the Brain: Potential Role of the Premotor Cortex in Motor Control, Learning, and Recovery of Function Following Brain Injury

Rewiring the Brain Potential Role of the Premotor Cortex in Motor Control, Learning, and Recovery of Function Following Brain Injury

The brain is a plastic organ with a capability to reorganize in response to behavior and/or injury. Following injury to the motor cortex or emergent corticospinal pathways, recovery of function depends on the capacity of surviving anatomical resources to recover and repair in response to task-specif...

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Bibliographic Details
Published in:Neurorehabilitation and neural repair Vol. 26; no. 3; pp. 282 - 292
Main Authors: Kantak, Shailesh S., Stinear, James W., Buch, Ethan R., Cohen, Leonardo G.
Format: Journal Article
Language:English
Published: Los Angeles, CA SAGE Publications 01-03-2012
Subjects:
Brain Injuries - pathology
Brain Injuries - physiopathology
Brain Injuries - rehabilitation
Humans
Learning - physiology
Motor Activity - physiology
Motor Cortex - physiology
Motor Cortex - physiopathology
Recovery of Function - physiology
premotor cortex
motor control learning
poststroke recovery
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Summary:The brain is a plastic organ with a capability to reorganize in response to behavior and/or injury. Following injury to the motor cortex or emergent corticospinal pathways, recovery of function depends on the capacity of surviving anatomical resources to recover and repair in response to task-specific training. One such area implicated in poststroke reorganization to promote recovery of upper extremity recovery is the premotor cortex (PMC). This study reviews the role of distinct subdivisions of PMC: dorsal (PMd) and ventral (PMv) premotor cortices as critical anatomical and physiological nodes within the neural networks for the control and learning of goal-oriented reach and grasp actions in healthy individuals and individuals with stroke. Based on evidence emerging from studies of intrinsic and extrinsic connectivity, transcranial magnetic stimulation, functional neuroimaging, and experimental studies in animals and humans, the authors propose 2 distinct patterns of reorganization that differentially engage ipsilesional and contralesional PMC. Research directions that may offer further insights into the role of PMC in motor control, learning, and poststroke recovery are also proposed. This research may facilitate neuroplasticity for maximal recovery of function following brain injury.
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ISSN:1545-9683
1552-6844
DOI:10.1177/1545968311420845