Anodal tDCS of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke
Objective: The role of ipsilateral motor cortex efferent pathways in the transmission of voluntary command to spinal motor nuclei remains controversial in humans. In healthy subjects, their implication in cortical control is hidden by predominant role of crossed corticospinal tract. However, evidenc...
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th-mahidol.873412023-06-20T12:32:58Z Anodal tDCS of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke Klomjai W. Mahidol University Medicine Objective: The role of ipsilateral motor cortex efferent pathways in the transmission of voluntary command to spinal motor nuclei remains controversial in humans. In healthy subjects, their implication in cortical control is hidden by predominant role of crossed corticospinal tract. However, evidence from electrophysiological and imaging studies suggest that ipsilateral tracts may contribute to functional recovery after unilateral brain damage. This randomized-sham control study aims to explore to what extent ipsilateral tracts from the undamaged hemisphere may strengthen corticospinal control onto spinal motor networks following stroke. Methods: Anodal transcranial direct current stimulation (tDCS) was combined with monosynaptic H-reflex method to evaluate the variations of reciprocal inhibition (RI) in wrist flexors in 21 stroke participants. Results: Anodal tDCS decreased RI in wrist flexors in stroke participants in both arms. tDCS unmasks an ipsilateral control from the undamaged hemisphere onto spinal motor networks controlling affected arm muscles in stroke participants. In the unaffected (contralateral) arm, effects in stroke participants were opposite to those induced in healthy subjects. Conclusions: Stimulation of the undamaged cortex in stroke participants induces modulation of ipsilateral motor networks controlling the hemiparetic side. Significance: Rehabilitation could leverage stimulation of the undamaged hemisphere to enhance motor recovery post stroke. 2023-06-20T05:32:58Z 2023-06-20T05:32:58Z 2022-04-01 Article Clinical Neurophysiology Vol.136 (2022) , 1-12 10.1016/j.clinph.2021.12.016 18728952 13882457 35131634 2-s2.0-85124043159 https://repository.li.mahidol.ac.th/handle/123456789/87341 SCOPUS |
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Medicine Klomjai W. Anodal tDCS of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke |
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Objective: The role of ipsilateral motor cortex efferent pathways in the transmission of voluntary command to spinal motor nuclei remains controversial in humans. In healthy subjects, their implication in cortical control is hidden by predominant role of crossed corticospinal tract. However, evidence from electrophysiological and imaging studies suggest that ipsilateral tracts may contribute to functional recovery after unilateral brain damage. This randomized-sham control study aims to explore to what extent ipsilateral tracts from the undamaged hemisphere may strengthen corticospinal control onto spinal motor networks following stroke. Methods: Anodal transcranial direct current stimulation (tDCS) was combined with monosynaptic H-reflex method to evaluate the variations of reciprocal inhibition (RI) in wrist flexors in 21 stroke participants. Results: Anodal tDCS decreased RI in wrist flexors in stroke participants in both arms. tDCS unmasks an ipsilateral control from the undamaged hemisphere onto spinal motor networks controlling affected arm muscles in stroke participants. In the unaffected (contralateral) arm, effects in stroke participants were opposite to those induced in healthy subjects. Conclusions: Stimulation of the undamaged cortex in stroke participants induces modulation of ipsilateral motor networks controlling the hemiparetic side. Significance: Rehabilitation could leverage stimulation of the undamaged hemisphere to enhance motor recovery post stroke. |
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Mahidol University |
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Mahidol University Klomjai W. |
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Article |
| author |
Klomjai W. |
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Klomjai W. |
| title |
Anodal tDCS of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke |
| title_short |
Anodal tDCS of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke |
| title_full |
Anodal tDCS of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke |
| title_fullStr |
Anodal tDCS of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke |
| title_full_unstemmed |
Anodal tDCS of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke |
| title_sort |
anodal tdcs of contralesional hemisphere modulates ipsilateral control of spinal motor networks targeting the paretic arm post-stroke |
| publishDate |
2023 |
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https://repository.li.mahidol.ac.th/handle/123456789/87341 |
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1781414162467913728 |