Evaluation of the effect of biofeedback system driven by optoelectronic conjugate materials in VR exercise rehabilitation

  • Ying Wang Department of Physical Education, Tiangong University, Tianjin 300387, China
DOI: https://doi.org/10.62617/mcb628
Keywords: optoelectronic conjugate materials; biofeedback system; rehabilitation; virtual reality
Article ID: 628

Abstract

Presently, Exercise Rehabilitation is crucial to restoring and improving a person’s well-being in physical fitness. The present research investigates the significance of Optoelectronic Conjugate Materials (OCM) in Biofeedback Systems to enhance the effectiveness of Virtual Reality (VR) Exercise Rehabilitation. This work presents the Design of Biofeedback System-driven Optoelectronic Conjugate Materials (DBS-OCM), which offers a novel methodology to enhance VR Exercise Rehabilitation. The DBS-OCM framework amalgamates synthesis and material characterization techniques for tissue healing during VR Exercise Rehabilitation. The present research aims to elucidate a resistance trainer’s design and preparation methodology during the Evaluation of the Effect of a Biofeedback System Driven by OCM. This approach seeks to optimize the flexibility of the system to cater to individual requirements during VR Exercise Rehabilitation. The experimental findings demonstrate notable advancements, including a 93.9% augmentation in tissue regeneration, a 95.5% enhancement in the efficacy of resistance training, and a 95.5% boost in involvement during virtual reality exercise. The results highlight the DBS-OCM’s capacity to enhance the Biofeedback System’s efficiency Driven by Optoelectronic Conjugate Materials in VR Exercise Rehabilitation. These findings provide essential insights that have the potential to shape future research endeavors and facilitate the development of practical applications in the domain of VR Exercise Rehabilitation.

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Published
2024-12-09
How to Cite
Wang, Y. (2024). Evaluation of the effect of biofeedback system driven by optoelectronic conjugate materials in VR exercise rehabilitation. Molecular & Cellular Biomechanics, 21(4), 628. https://doi.org/10.62617/mcb628
Issue
Vol. 21 No. 4 (2024)
Section
Article

Copyright (c) 2024 Ying Wang

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