IEEE Transactions on Neural Systems and Rehabilitation Engineering (Jan 2024)

Immediate Effect of Wearable Balance Training Device on Muscle Co-Contraction and Postural Control During Standing

  • Masataka Yamamoto,
  • Koji Shimatani,
  • Michael E. Hahn,
  • Hiroshi Takemura

DOI
https://doi.org/10.1109/TNSRE.2024.3412686
Journal volume & issue
Vol. 32
pp. 2230 – 2238

Abstract

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Postural control is one of the primary body functions for fall prevention. Unexpected perturbation-based balance training is effective for improving postural control. However, the effect of perturbation-based training using assistive devices on muscle activity and co-contraction for standing balance is still unclear. This training is also difficult to perform easily because it requires large instruments or expert guidance. The purpose of this study is to demonstrate the effect of perturbation-based balance training using a wearable balance training device (WBTD) on postural control. In this study, fourteen healthy young adult males were assigned to either a WBTD group or a sham group. In the intervention session, participants in the WBTD group were perturbed either left or right direction at random timing by the WBTD during tandem stance balance training. Participants in the Sham group did not receive external perturbation during tandem stance balance training. Before and after the intervention session, participants of both groups underwent unexpected lateral perturbation postural control testing (pre- and post-test). The normalized integral of electromyography (IEMG), co-contraction index (CCI), and center of pressure (COP) parameters were measured in the pre- and post-test. Experimental results showed that the WBTD group in the post-test significantly decreased left Gluteus Medius IEMG, CCI of both Gluteus Medius, and peak $\text {COP}_{\text {ML}}$ velocity, compared to those of the pre-test ( ${p} \lt 0.001$ , ${p} \,\, =0.024$ , ${p} \,\, =0.031$ , respectively). We conclude that balance training using WBTD could improve flexible postural control adjustment via cooperative muscle activation.

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