A robotic treadmill system to mimic overground walking training with body weight support

A robotic treadmill system to mimic overground walking training with body weight support

Body weight support overground walking training (BWSOWT) is widely used in gait rehabilitation. However, existing systems require large workspace, complex structure, and substantial installation cost for the actuator, which make those systems inappropriate for the clinical environment. For wide clin...

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Bibliographic Details
Published in:Frontiers in neurorobotics Vol. 17; p. 1089377
Main Authors: Kim, Jongbum, Oh, Seunghue, Jo, Yongjin, Moon, James Hyungsup, Kim, Jonghyun
Format: Journal Article
Language:English
Published: Switzerland Frontiers Research Foundation 09-06-2023
Frontiers Media S.A
Subjects:
Body weight
body weight support
Fitness equipment
Gait
gait rehabilitation
Motion capture
Neuroscience
overground walking training
Rehabilitation
treadmill
Walking
Wire
wire mechanism
overground walking training
body weight support
gait rehabilitation
treadmill
wire mechanism
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Summary:Body weight support overground walking training (BWSOWT) is widely used in gait rehabilitation. However, existing systems require large workspace, complex structure, and substantial installation cost for the actuator, which make those systems inappropriate for the clinical environment. For wide clinical use, the proposed system is based on a self-paced treadmill, and uses an optimized body weight support with frame-based two-wire mechanism. The Interactive treadmill was used to mimic overground walking. We opted the conventional DC motors to partially unload the body weight and modified pelvic type harness to allow natural pelvic motion. The performance of the proposed system on the measurement of anterior/posterior position, force control, and pelvic motion was evaluated with 8 healthy subjects during walking training. We verified that the proposed system was the cost/space-effective and showed the more accurate anterior/posterior position than motion sensor, comparable force control performance, and natural pelvic motion. The proposed system is cost/space effective, and able to mimic overground walking training with body weight support. In future work, we will improve the force control performance and optimize the training protocol for wide clinical use.
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Edited by: Francesca Cordella, Campus Bio-Medico University, Italy
Reviewed by: Bjoern Braunstein, Centre for Health and Integrative Physiology in Space (CHIPS), Germany; Kenneth J. Hunt, Bern University of Applied Sciences, Switzerland
ISSN:1662-5218
1662-5218
DOI:10.3389/fnbot.2023.1089377