Instantaneous interjoint rescaling and adaptation to balance perturbation under muscular fatigue

Instantaneous interjoint rescaling and adaptation to balance perturbation under muscular fatigue

Adaptation of automatic postural responses (APR) to balance perturbations might be thought to be impaired by muscle fatigue, given the associated proprioceptive and effector deficits. In this investigation, we aimed to evaluate the effect of muscular fatigue on APR adaptation over repetitive balance...

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Veröffentlicht in:The European journal of neuroscience 2020-03, Vol.51 (6), p.1478-1490
Hauptverfasser: Rinaldin, Carla Daniele Pacheco, Ávila de Oliveira, Júlia, Coelho, Daniel Boari, Scheeren, Eduardo Mendonça, Teixeira, Luis Augusto
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aftereffect
automatic postural responses
Balance
Fatigue
first trial
Hip
Life Sciences & Biomedicine
Muscle contraction
muscle fatigue
Neurosciences
Neurosciences & Neurology
perturbed balance
Posture
Proprioception
Scaling
Science & Technology
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container_end_page 1490
container_issue 6
container_start_page 1478
container_title The European journal of neuroscience
container_volume 51
creator Rinaldin, Carla Daniele Pacheco
Ávila de Oliveira, Júlia
Coelho, Daniel Boari
Scheeren, Eduardo Mendonça
Teixeira, Luis Augusto
description Adaptation of automatic postural responses (APR) to balance perturbations might be thought to be impaired by muscle fatigue, given the associated proprioceptive and effector deficits. In this investigation, we aimed to evaluate the effect of muscular fatigue on APR adaptation over repetitive balance perturbations through support base backward translations. APR adaptation was evaluated in three epochs: (a) pre‐fatigue; (b) post‐fatigue, immediately following fatigue of the plantiflexor muscles through isometric contractions and (c) post‐recovery, 30 min after the end of fatiguing activity. Results showed the following: (a) Decreasing amplitudes of joints' maximum excursion over repetitive perturbations in the three fatigue‐related epochs. (b) Modulation of joints' excursion was observed in the first trial in the post‐fatigue epoch. (c) In the post‐fatigue epoch, we found interjoint rescaling, with greater amplitude of hip rotation associated with reduced amplitude of ankles' rotation. (d) Amplitudes of ankles' rotation were similar between the post‐fatigue and post‐recovery epochs. These findings lead to the conclusions that adaptation of automatic postural responses over repetitive trials was effective under focal muscular fatigue; modulation of the postural response took place in the first perturbation under fatigue, and generalization of response characteristics from post‐fatigue to post‐recovery suggests that feedforward processes in APRs generation are affected by the recent history of postural responses to stance perturbations. Adaptation of automatic postural responses was found over repetitive trials under focal muscular fatigue. Modulation of postural responses took place in the first perturbation under muscular fatigue. Generalization of response characteristics from fatigued to fatigue‐recovered states suggests that feedforward processes in APRs generation are affected by the recent history of postural responses to stance perturbations.
doi_str_mv 10.1111/ejn.14606
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subjects aftereffect
automatic postural responses
Balance
Fatigue
first trial
Hip
Life Sciences & Biomedicine
Muscle contraction
muscle fatigue
Neurosciences
Neurosciences & Neurology
perturbed balance
Posture
Proprioception
Scaling
Science & Technology
title Instantaneous interjoint rescaling and adaptation to balance perturbation under muscular fatigue
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