Sensorimotor Training in Virtual Reality: a Review

Overview

Journal NeuroRehabilitation

Publisher Sage Publications

Specialties Neurology
Rehabilitation Medicine

Date 2009 Aug 29

PMID 19713617

Citations 146

Authors

Sergei V Adamovich

Gerard G Fluet

Eugene Tunik

Alma S Merians

Affiliations

Soon will be listed here.

Abstract

Recent experimental evidence suggests that rapid advancement of virtual reality (VR) technologies has great potential for the development of novel strategies for sensorimotor training in neurorehabilitation. We discuss what the adaptive and engaging virtual environments can provide for massive and intensive sensorimotor stimulation needed to induce brain reorganization.Second, discrepancies between the veridical and virtual feedback can be introduced in VR to facilitate activation of targeted brain networks, which in turn can potentially speed up the recovery process. Here we review the existing experimental evidence regarding the beneficial effects of training in virtual environments on the recovery of function in the areas of gait,upper extremity function and balance, in various patient populations. We also discuss possible mechanisms underlying these effects. We feel that future research in the area of virtual rehabilitation should follow several important paths. Imaging studies to evaluate the effects of sensory manipulation on brain activation patterns and the effect of various training parameters on long term changes in brain function are needed to guide future clinical inquiry. Larger clinical studies are also needed to establish the efficacy of sensorimotor rehabilitation using VR in various clinical populations and most importantly, to identify VR training parameters that are associated with optimal transfer to real-world functional improvements.

Citing Articles

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Grospretre S, Mathiot J, Eon P, Ruffino C Exp Brain Res. 2025; 243(3):69.

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Effects of semi-immersive virtual reality and manipulation of optic flow speed on gait biomechanics in people post-stroke.

De Keersmaecker E, Van Bladel A, Zaccardi S, Lefeber N, Rodriguez-Guerrero C, Kerckhofs E J Rehabil Med. 2024; 56:jrm12384.

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Effects of balance training with visual input manipulations on balance performance and sensory integration in healthy young adults: a randomized controlled trial.

Ketterer J, Gollhofer A, Ringhof S, Asslander L, Granacher U, Gehring D Sci Rep. 2024; 14(1):28589.

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An investigation of feed-forward and feedback eye movement training in immersive virtual reality.

Harris D, Wilson M, Jones M, de Burgh T, Mundy D, Arthur T J Eye Mov Res. 2024; 15(3).

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Sensorimotor Simulation's Influence on Stress: EEG and Autonomic Responses in Digital Interviews.

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