TY - JOUR
PY - 2017//
TI - Ageing does not affect the intralimb coordination elicited by slip-like perturbation of different intensities
JO - Journal of Neurophysiology
A1 - Aprigliano, Federica
A1 - Martelli, Dario
A1 - Tropea, Peppino
A1 - Pasquini, Guido
A1 - Micera, Silvestro
A1 - Monaco, Vito
SP - 1739
EP - 1748
VL - 118
IS - 3
N2 - This study was aimed at verifying whether ageing modifies intralimb coordination strategy during corrective responses elicited by unexpected slip-like perturbations delivered during steady walking on a treadmill. To this end, ten young and ten elderly subjects were asked to manage unexpected slippages of different intensities. We analyzed the planar covariation law of the lower limb segments, using the principal component analysis, in order to verify whether elevation angles of older subjects covaried along a plane, before and after the perturbation.
RESULTS showed that segments related to the perturbed limb, of both younger and older people, do not covary after all perturbations. Conversely, the planar covariation law of the unperturbed limb was systematically held for younger and older subjects. These results occurred despite differences in spatio-temporal and kinematic parameters being observed among groups and perturbation intensities. Overall, our analysis revealed that ageing does not affect intralimb coordination during corrective responses induced by slip-like perturbation, suggesting that both younger and older subjects adopt this control strategy while managing sudden and unexpected postural transitions of increasing intensities. Accordingly, results corroborate the hypothesis that balance control emerges from a governing set of biomechanical invariants, that is, suitable control schemes (e.g. planar covariation law) shared across voluntary and corrective motor behaviors, and across different sensory contexts due to different perturbation intensities, in both younger and older subjects. In this respect, our findings provide further support to investigate effects of specific task training programs to counteract the risk of fall.
Copyright © 2016, Journal of Neurophysiology. Language: en
LA - en
SN - 0022-3077
UR - http://dx.doi.org/10.1152/jn.00844.2016
ID - ref1
ER -