Citation

Sawers A, Pai YC, Bhatt T, Ting LH. J. Neurophysiol. 2016; 117(2): 509-522.

Affiliation

Emory University and Georgia Institute of Technology.

Copyright

(Copyright © 2016, American Physiological Society)

DOI

10.1152/jn.00699.2016

PMID

27832608

Abstract

How does the robust control of walking and balance break down during a fall? As a first step in identifying the neuromuscular determinants of falls, we tested the hypothesis that falls and recoveries are characterized by differences in neuromuscular responses. Using muscle synergy analysis, conventional onset latencies, and peak activity, we identified differences in muscle coordination between older adults who fell and those who recovered from a laboratory-induced slip. We found that subjects who fell recruited fewer muscle synergies than those who recovered, suggesting a smaller motor repertoire. During slip trials subjects who fell had delayed knee flexor and extensor onset times in the leading/slip leg, as well as different muscle synergy structure involving those muscles. Therefore, the ability to coordinate muscle activity around the knee in a timely manner may be critical to avoiding falls from slips. Unique to subjects who fell during slip trials were greater bilateral muscle activation, and the recruitment of a muscle synergy with excessive co-activation. These differences in muscle coordination between subjects who fell and those who recovered could not be explained by differences in gait-related variables at slip onset (i.e. initial motion state) nor variations in slip difficulty. This suggests that differences in muscle coordination likely reflected differences in the neural control of movement rather than biomechanical constraints imposed by perturbation or walking mechanics. These results are the first step in determining the causation of falls from the perspective of muscle coordination. They suggest that there may be a neuromuscular basis for falls.

Copyright © 2016, Journal of Neurophysiology.

Language: en