Rafhael M. Andrade, Stefano Sapienza, Abolfazl Mohebbi, Eric E. Fabara et Paolo Bonato
Article de revue (2024)
Document en libre accès dans PolyPublie et chez l'éditeur officiel |
|
Libre accès au plein texte de ce document Version officielle de l'éditeur Conditions d'utilisation: Creative Commons: Attribution-Pas d'utilisation commerciale-Pas de modification (CC BY-NC-ND) Télécharger (2MB) |
Abstract
Lower-limb gait training (GT) exoskeletons have been successfully used in rehabilitation programs to overcome the burden of locomotor impairment. However, providing suitable net interaction torques to assist patient movements is still a challenge. Previous transparent operation approaches have been tested in treadmill-based GT exoskeletons to improve user-robot interaction. However, it is not yet clear how a transparent lower-limb GT system affects user’s gait kinematics during overground walking, which unlike treadmill-based systems, requires active participation of the subjects to maintain stability. In this study, we implemented a transparent operation strategy on the ExoRoboWalker, an overground GT exoskeleton, to investigate its effect on the user’s gait. The approach employs a feedback zero-torque controller with feedforward compensation for the exoskeleton’s dynamics and actuators’ impedance. We analyzed the data of five healthy subjects walking overground with the exoskeleton in transparent mode (ExoTransp) and non-transparent mode (ExoOff) and walking without exoskeleton (NoExo). The transparent controller reduced the user-robot interaction torque and improved the user’s gait kinematics relative to ExoOff. No significant difference in stride length is observed between ExoTransp and NoExo (p = 0.129). However, the subjects showed a significant difference in cadence between ExoTransp (50.9± 1.1 steps/min) and NoExo (93.7 ± 8.7 steps/min) (p = 0.015), but not between ExoTransp and ExoOff (p = 0.644). Results suggest that subjects wearing the exoskeleton adjust their gait as in an attention-demanding task changing the spatiotemporal gait characteristics likely to improve gait balance.
Mots clés
lower-limb exoskeleton; gait training; transparent control; gait kinematics
Sujet(s): |
1900 Génie biomédical > 1900 Génie biomédical 1900 Génie biomédical > 1901 Technologie biomédicale 2100 Génie mécanique > 2100 Génie mécanique |
---|---|
Département: | Département de génie mécanique |
Organismes subventionnaires: | Fundação de Amparo à Pesquisa e Inovação do Espírito Santo (FAPES), Nacional de Desenvolvimento Científico e Tecnológico (FNDCT) - Financiadora de Estudos e Projetos (FINEP), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), Peabody Foundation |
Numéro de subvention: | Project 151/2021, Project 2021-8GJZ6, Project 460/2021, Project 2021-L7SZ4, Project 414/2022, Project 2022-SX1VM, Project 565/2023, Project 2023-BQK22, Project 946/2023, Project 2023-F0GWQ, Grant 2784/20 |
URL de PolyPublie: | https://publications.polymtl.ca/57263/ |
Titre de la revue: | IEEE Journal of Translational Engineering in Health and Medicine (vol. 12) |
Maison d'édition: | IEEE |
DOI: | 10.1109/jtehm.2023.3323381 |
URL officielle: | https://doi.org/10.1109/jtehm.2023.3323381 |
Date du dépôt: | 29 janv. 2024 14:38 |
Dernière modification: | 29 sept. 2024 03:35 |
Citer en APA 7: | Andrade, R. M., Sapienza, S., Mohebbi, A., Fabara, E. E., & Bonato, P. (2024). Overground walking with a transparent exoskeleton shows changes in spatiotemporal gait parameters. IEEE Journal of Translational Engineering in Health and Medicine, 12, 182-193. https://doi.org/10.1109/jtehm.2023.3323381 |
---|---|
Statistiques
Total des téléchargements à partir de PolyPublie
Téléchargements par année
Provenance des téléchargements
Dimensions