Auditory biofeedback substitutes for loss of sensory information in maintaining stance.
Artikel i vetenskaplig tidskrift, 2007

The importance of sensory feedback for postural control in stance is evident from the balance improvements occurring when sensory information from the vestibular, somatosensory, and visual systems is available. However, the extent to which also audio-biofeedback (ABF) information can improve balance has not been determined. It is also unknown why additional artificial sensory feedback is more effective for some subjects than others and in some environmental contexts than others. The aim of this study was to determine the relative effectiveness of an ABF system to reduce postural sway in stance in healthy control subjects and in subjects with bilateral vestibular loss, under conditions of reduced vestibular, visual, and somatosensory inputs. This ABF system used a threshold region and non-linear scaling parameters customized for each individual, to provide subjects with pitch and volume coding of their body sway. ABF had the largest effect on reducing the body sway of the subjects with bilateral vestibular loss when the environment provided limited visual and somatosensory information; it had the smallest effect on reducing the sway of subjects with bilateral vestibular loss, when the environment provided full somatosensory information. The extent that all subjects substituted ABF information for their loss of sensory information was related to the extent that each subject was visually dependent or somatosensory-dependent for their postural control. Comparison of postural sway under a variety of sensory conditions suggests that patients with profound bilateral loss of vestibular function show larger than normal information redundancy among the remaining senses and ABF of trunk sway. The results support the hypothesis that the nervous system uses augmented sensory information differently depending both on the environment and on individual proclivities to rely on vestibular, somatosensory or visual information to control sway.

Somatosensory Disorders

Male

Feedback

Cues

physiology

Recovery of Function

Auditory Perception

physiology

Adaptation

Low

Aged

physiology

Postural Balance

physiology

Middle Aged

physiopathology

Female

physiopathology

physiology

Vestibular Diseases

physiopathology

Space Perception

Physiological

Sensory Deprivation

Humans

Vision

physiology

Adult

physiology

Författare

Marco Dozza

Vehicle and Traffic Safety Centre at Chalmers

Chalmers, Tillämpad mekanik, Fordonssäkerhet

Fay B Horak

Lorenzo Chiari

Experimental Brain Research

0014-4819 (ISSN) 1432-1106 (eISSN)

Vol. 178 1 37-48

Ämneskategorier

Medicinteknik

Annan medicin och hälsovetenskap

Annan naturvetenskap

DOI

10.1007/s00221-006-0709-y

PubMed

17021893

Mer information

Skapat

2017-10-08