Biofeedback Improves Postural Control Recovery from Multi-axis Discrete Perturbations

Overview

Journal J Neuroeng Rehabil

Publisher Biomed Central

Specialties Biomedical Engineering
Neurology
Rehabilitation Medicine

Date 2012 Aug 7

PMID 22863399

Citations 24

Authors

Kathleen H Sienko

M David Balkwill

Conrad Wall 3rd

Affiliations

Soon will be listed here.

Abstract

Background: Multi-axis vibrotactile feedback has been shown to significantly reduce the root-mean-square (RMS) sway, elliptical fits to sway trajectory area, and the time spent outside of the no feedback zone in individuals with vestibular deficits during continuous multidirectional support surface perturbations. The purpose of this study was to examine the effect of multidirectional vibrotactile biofeedback on postural stability during discrete multidirectional support surface perturbations.

Methods: The vibrotactile biofeedback device mapped tilt estimates onto the torso using a 3-row by 16-column tactor array. The number of columns displayed was varied to determine the effect of spatial resolution upon subject response. Torso kinematics and center of pressure data were measured in six subjects with vestibular deficits. Transient and steady state postural responses with and without feedback were characterized in response to eight perturbation directions. Four feedback conditions in addition to the tactors off (no feedback) configuration were evaluated. Postural response data captured by both a force plate and an inertial measurement unit worn on the torso were partitioned into three distinct phases: ballistic, recovery, and steady state.

Results: The results suggest that feedback has minimal effects during the ballistic phase (body's outbound trajectory in response to the perturbation), and the greatest effects during the recovery (return toward baseline) and steady state (post-recovery) phases. Specifically, feedback significantly decreases the time required for the body tilt to return to baseline values and significantly increases the velocity of the body's return to baseline values. Furthermore, feedback significantly decreases root mean square roll and pitch sway and significantly increases the amount of time spent in the no feedback zone. All four feedback conditions produced comparable performance improvements. Incidences of delayed and uncontrolled responses were significantly reduced with feedback while erroneous (sham) feedback resulted in poorer performance when compared with the no feedback condition.

Conclusions: The results show that among the displays evaluated in this study, no one tactor column configuration was optimal for standing tasks involving discrete surface perturbations. Feedback produced larger effects on body tilt versus center of pressure parameters. Furthermore, the subjects' performance worsened when erroneous feedback was provided, suggesting that vibrotactile stimulation applied to the torso is actively processed and acted upon rather than being responsible for simply triggering a stiffening response.

Citing Articles

Does vibrotactile biofeedback for postural control interfere with cognitive processes?.

Schulleri K, Feizian F, Steinbock M, Lee D, Johannsen L J Neuroeng Rehabil. 2024; 21(1):184.

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A Review of Artificial Intelligence-Based Gait Evaluation and Rehabilitation in Parkinson's Disease.

Jadhwani P, Harjpal P Cureus. 2023; 15(10):e47118.

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Acute unilateral vestibular neuritis contributes to alterations in vestibular function modulating circumvention around obstacles: A pilot study suggesting a role for vestibular signals in the spatial perception of orientation during circumvention.

Allum J, Rust H, Honegger F Front Integr Neurosci. 2022; 16:807686.

PMID: 36339968 PMC: 9630838. DOI: 10.3389/fnint.2022.807686.

Less Vibrotactile Feedback Is Effective to Improve Human Balance Control during Sensory Cues Alteration.

Anctil N, Malenfant Z, Cyr J, Turcot K, Simoneau M Sensors (Basel). 2022; 22(17).

PMID: 36080897 PMC: 9460360. DOI: 10.3390/s22176432.

Reducing Slip Risk: A Feasibility Study of Gait Training with Semi-Real-Time Feedback of Foot-Floor Contact Angle.

Zong-Hao Ma C, Bao T, DiCesare C, Harris I, Chambers A, Shull P Sensors (Basel). 2022; 22(10).

PMID: 35632054 PMC: 9144019. DOI: 10.3390/s22103641.

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