RT Journal Article
SR Electronic
T1 Which lower-limb joints compensate for destabilising energy during walking in humans?
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 2022.01.11.475955
DO 10.1101/2022.01.11.475955
A1 Pawel R. Golyski
A1 Gregory S. Sawicki
YR 2022
UL http://biorxiv.org/content/early/2022/01/12/2022.01.11.475955.abstract
AB Maintaining stability during perturbed locomotion requires coordinated responses across multiple levels of organization (e.g., legs, joints, muscle-tendon units). However, current approaches to investigating such responses lack a “common currency” that is both shared across scales and can be directly related to perturbation demands. We used mechanical energetics to investigate the demands imposed on a leg by a transient increase in unilateral treadmill belt speed targeted to either early or late stance. We collected full body kinematics and kinetics from 7 healthy participants during 222 total perturbations. From across-subject means, we found early stance perturbations elicited no change in net work exchanged between the perturbed leg and the treadmill but net positive work at the overall leg level, and late stance perturbations elicited positive work at the leg/treadmill interface but no change in net work at the overall leg level. Across all perturbations, changes in ankle and knee work from steady state best reflected changes in overall leg work on the perturbed and contralateral sides, respectively. Broadening this paradigm to include joint level (vs. leg level) perturbations and including muscle-tendon unit mechanical energetics may reveal neuromechanical responses used in destabilizing environments which could inform design of balance-assisting devices and interventions.Subject Areas biomechanics, biomedical engineering, bioengineeringCompeting Interest StatementThe authors have declared no competing interest.