Citation

Miyake T, Tsukune M, Kobayashi Y, Sugano S, Fujie MG, Miyake T, Tsukune M, Kobayashi Y, Sugano S, Fujie MG, Sugano S, Miyake T, Fujie MG, Kobayashi Y, Tsukune M. Conf. Proc. IEEE Eng. Med. Biol. Soc. 2016; 2016: 6154-6157.

Copyright

(Copyright © 2016, IEEE (Institute of Electrical and Electronics Engineers))

DOI

10.1109/EMBC.2016.7592133

PMID

28227915

Abstract

Elderly people are at risk of tripping because of their narrow range of articular motion. To avoid tripping, gait training that improves their range of articular motion would be beneficial. In this study we propose a gait-training robot that applies a torque during the pre-swing phase to achieve this goal. We investigated the relationship between magnitude of applied torque and change in the range of knee-articular motion while walking before and after the application of this torque. We developed a wearable robot and carried out an experiment on human participants in which a motor pulls a string embedded on the robotic frame, applying torque in the pre-swing phase for a period of 20 [s]. Before and after applying torque the participant walked normally for 15 [s] without interference from the robot. We found that knee flexion angle increased after applying the torque if the torque was within the range of approximately 6-8 [Nm]. Therefore, we were able to verify that a new range of knee articular motion can be learned through application of torque.

Language: en