Motor Cortex Organization After Stroke is Related to Side of Stroke and Level of Recovery

Overview

Journal Stroke

Specialties Cardiology & Vascular Diseases
Neurology

Date 2003 Apr 5

PMID 12677024

Citations 43

Authors

Anna C Zemke

Patrick J Heagerty

Christopher Lee

Steven C Cramer

Affiliations

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Abstract

Background And Purpose: The present study hypothesized that side of stroke and level of recovery influence motor system organization after stroke.

Methods: Functional MRI was performed on 14 control subjects and 21 patients with chronic stroke during index finger tapping (control subjects, right; patients, recovered side).

Results: On functional MRI, stroke patients with right arm involvement showed (1) significantly smaller activation in contralateral motor cortexes compared with control subjects; (2) smaller ipsilateral (nonstroke) premotor and larger contralateral (stroke-side) sensorimotor activation compared with patients with left arm involvement, although electromyogram across groups was similar; and (3) 2.7-fold-larger contralateral sensorimotor cortex activation, ventrally, in those with full recovery compared with those with partial recovery, despite similar tapping force, frequency, range of motion, and electromyogram between groups. Supplementary motor area activation was unrelated to level of recovery.

Conclusions: After stroke that causes mild to moderate initial impairment and mild residual hand weakness, cortical organization varies with side of injury and with final motor status. The findings may have implications for treatment after stroke.

Citing Articles

The impact of lesion side on bilateral upper limb coordination after stroke.

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Distinguishing Distinct Neural Systems for Proximal vs Distal Upper Extremity Motor Control After Acute Stroke.

Lin D, Hardstone R, DiCarlo J, Mckiernan S, Snider S, Jacobs H Neurology. 2023; 101(4):e347-e357.

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Neural recovery after cortical injury: Effects of MSC derived extracellular vesicles on motor circuit remodeling in rhesus monkeys.

Calderazzo S, Covert M, de Alba D, Bowley B, Pessina M, Rosene D IBRO Neurosci Rep. 2023; 13:243-254.

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Home-based portable fNIRS-derived cortical laterality correlates with impairment and function in chronic stroke.

Lee Friesen C, Lawrence M, Ingram T, Boe S Front Hum Neurosci. 2022; 16:1023246.

PMID: 36569472 PMC: 9780676. DOI: 10.3389/fnhum.2022.1023246.

Targeting neuroplasticity to improve motor recovery after stroke: an artificial neural network model.

Norman S, Wolpaw J, Reinkensmeyer D Brain Commun. 2022; 4(6):fcac264.

PMID: 36458210 PMC: 9700163. DOI: 10.1093/braincomms/fcac264.