Neural coupling between homologous muscles during bimanual tasks: effects of visual and somatosensory feedback.

MedStar author(s):
Citation: Journal of Neurophysiology. 117(2):655-664, 2017 Feb 01PMID: 27852730Institution: MedStar National Rehabilitation NetworkForm of publication: Journal ArticleMedline article type(s): Journal ArticleSubject headings: *Feedback, Sensory/ph [Physiology] | *Isometric Contraction/ph [Physiology] | *Muscle, Skeletal/ph [Physiology] | *Psychomotor Performance/ph [Physiology] | Adult | Analysis of Variance | Elbow/ph [Physiology] | Electromyography | Female | Functional Laterality/ph [Physiology] | Humans | Male | Reflex/ph [Physiology] | Young AdultYear: 2017Local holdings: Available online from MWHC library: 1997 - present (after 1 year)ISSN:
  • 0022-3077
Name of journal: Journal of neurophysiologyAbstract: Copyright � 2017 the American Physiological Society.NEW & NOTEWORTHY: This study investigated the effects of somatosensory feedback during bimanual tasks on the neural coupling between arm muscles, which remains largely unexplored. Somatosensory feedback using a balancing apparatus, compared with visual feedback, significantly increased neural coupling between homologous muscles (indicated by intermuscular coherence values) and improved temporal correlation of bilateral force production. Notably, feedback type modulated coherence in the alpha- and gamma-bands (more subcortical pathways), whereas task type mainly affected beta-band coherence (corticospinal pathway).While the effects of sensory feedback on bimanual tasks have been studied extensively at two ends of the motor control hierarchy, the cortical and behavioral levels, much less is known about how it affects the intermediate levels, including neural control of homologous muscle groups. We investigated the effects of somatosensory input on the neural coupling between homologous arm muscles during bimanual tasks. Twelve subjects performed symmetric elbow flexion/extension tasks under different types of sensory feedback. The first two types involve visual feedback, with one imposing stricter force symmetry than the other. The third incorporated somatosensory feedback via a balancing apparatus that forced the two limbs to produce equal force levels. Although the force error did not differ between feedback conditions, the somatosensory feedback significantly increased temporal coupling of bilateral force production, indicated by a high correlation between left/right force profiles (P < 0.001). More importantly, intermuscular coherence between biceps brachii muscles was significantly higher with somatosensory feedback than others (P = 0.001). Coherence values also significantly differed between tasks (flexion/extension). Notably, whereas feedback type mainly modulated coherence in the alpha- and gamma-bands, task type only affected beta-band coherence. Similar feedback effects were observed for triceps brachii muscles, but there was also a strong phase effect on the coherence values (P < 0.001) that could have diluted feedback effects. These results suggest that somatosensory feedback can significantly increase neural coupling between homologous muscles. Additionally, the between-task difference in beta-band coherence may reflect different neural control strategies for the elbow flexor and extensor muscles.All authors: Harris-Love ML, Lee SW, Lum PS, Nguyen HBFiscal year: FY2017Digital Object Identifier: Date added to catalog: 2017-05-06
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Item type Current library Collection Call number Status Date due Barcode
Journal Article MedStar Authors Catalog Article 27852730 Available 27852730

Available online from MWHC library: 1997 - present (after 1 year)

Copyright � 2017 the American Physiological Society.

NEW & NOTEWORTHY: This study investigated the effects of somatosensory feedback during bimanual tasks on the neural coupling between arm muscles, which remains largely unexplored. Somatosensory feedback using a balancing apparatus, compared with visual feedback, significantly increased neural coupling between homologous muscles (indicated by intermuscular coherence values) and improved temporal correlation of bilateral force production. Notably, feedback type modulated coherence in the alpha- and gamma-bands (more subcortical pathways), whereas task type mainly affected beta-band coherence (corticospinal pathway).

While the effects of sensory feedback on bimanual tasks have been studied extensively at two ends of the motor control hierarchy, the cortical and behavioral levels, much less is known about how it affects the intermediate levels, including neural control of homologous muscle groups. We investigated the effects of somatosensory input on the neural coupling between homologous arm muscles during bimanual tasks. Twelve subjects performed symmetric elbow flexion/extension tasks under different types of sensory feedback. The first two types involve visual feedback, with one imposing stricter force symmetry than the other. The third incorporated somatosensory feedback via a balancing apparatus that forced the two limbs to produce equal force levels. Although the force error did not differ between feedback conditions, the somatosensory feedback significantly increased temporal coupling of bilateral force production, indicated by a high correlation between left/right force profiles (P < 0.001). More importantly, intermuscular coherence between biceps brachii muscles was significantly higher with somatosensory feedback than others (P = 0.001). Coherence values also significantly differed between tasks (flexion/extension). Notably, whereas feedback type mainly modulated coherence in the alpha- and gamma-bands, task type only affected beta-band coherence. Similar feedback effects were observed for triceps brachii muscles, but there was also a strong phase effect on the coherence values (P < 0.001) that could have diluted feedback effects. These results suggest that somatosensory feedback can significantly increase neural coupling between homologous muscles. Additionally, the between-task difference in beta-band coherence may reflect different neural control strategies for the elbow flexor and extensor muscles.

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