Postural compensation for unilateral vestibular loss.

Diane M Wrisley,Fay B Horak,Kennyn D Statler,Robert J Peterka

doi:10.3389/fneur.2011.00057

Diane M Wrisley, Fay B Horak + Show 2 more

Open Access

https://doi.org/10.3389/fneur.2011.00057

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Abstract

Postural control of upright stance was investigated in well-compensated, unilateral vestibular loss (UVL) subjects compared to age-matched control subjects. The goal was to determine how sensory weighting for postural control in UVL subjects differed from control subjects, and how sensory weighting related to UVL subjects’ functional compensation, as assessed by standardized balance and dizziness questionnaires. Postural control mechanisms were identified using a model-based interpretation of medial–lateral center-of-mass body-sway evoked by support-surface rotational stimuli during eyes-closed stance. The surface-tilt stimuli consisted of continuous pseudorandom rotations presented at four different amplitudes. Parameters of a feedback control model were obtained that accounted for each subject’s sway response to the surface-tilt stimuli. Sensory weighting factors quantified the relative contributions to stance control of vestibular sensory information, signaling body-sway relative to earth-vertical, and proprioceptive information, signaling body-sway relative to the surface. Results showed that UVL subjects made significantly greater use of proprioceptive, and therefore less use of vestibular, orientation information on all tests. There was relatively little overlap in the distributions of sensory weights measured in UVL and control subjects, although UVL subjects varied widely in the amount they could use their remaining vestibular function. Increased reliance on proprioceptive information by UVL subjects was associated with their balance being more disturbed by the surface-tilt perturbations than control subjects, thus indicating a deficiency of balance control even in well-compensated UVL subjects. Furthermore, there was some tendency for UVL subjects who were less able to utilize remaining vestibular information to also indicate worse functional compensation on questionnaires.

Highlights

Unilateral loss of vestibular function usually results in functional compensation such that patients are able to stand and walk independently with little or no ataxia and/or vertigo
The CoM sway responses of the representative control and unilateral vestibular loss (UVL) subjects shown in Figure 2A illustrate that stimulus-evoked CoM sway increased with increasing stimulus amplitude, but that the CoM sway amplitude was slightly larger in the UVL subject compared to the control subject
The Root mean square (RMS) data revealed a non-linearity in sway responses across stimulus amplitude for both UVL and control subjects in that the stimulusevoked RMS sway did not increase in direct proportion to the stimulus amplitude

Summary

Introduction

Unilateral loss of vestibular function (unilateral vestibular loss, UVL) usually results in functional compensation such that patients are able to stand and walk independently with little or no ataxia and/or vertigo. Postural compensation for bilateral loss of vestibular function depends upon the ability to increase reliance on the remaining sensory systems for postural orientation (Horak, 2010). Following bilateral loss of vestibular function, studies have shown that subjects increase reliance upon their remaining sensory systems as demonstrated by increased orientation to a rotating support surface (SS) when their eyes are closed, rather than to gravitational vertical (Peterka, 2002). Currently it is unknown the extent to which postural compensation for UVL depends on increasing reliance upon alternative sensory sources of orientation information

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