| RESEARCH ARTICLE |
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| Year : 2023 | Volume
: 2
| Issue : 3 | Page : 63-72 |
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Impedance control and test of an automatic rotational orthosis for walking with arm swing
Juan Fang1, Bilibin Tan2, Wei Zhang2, Le Xie2, Guo-Yuan Yang2
1 School of Mechanical Engineering, Jiangnan University, Wuxi, Jiangsu Province; The Joint Lab of the Institute of Rehabilitation Center and Chejing Robotics Technology (Shanghai) Co., Ltd., Med-X Research Institute, School of Biomedical Engineering, Shanghai Jiao Tong University, Shanghai, China
2 The Joint Lab of the Institute of Rehabilitation Center and Chejing Robotics Technology (Shanghai) Co., Ltd., Med-X Research Institute, School of Biomedical Engineering, Shanghai Jiao Tong University, Shanghai, China
Correspondence Address:
Guo-Yuan Yang
The Joint Lab of the Institute of Rehabilitation Center and Chejing Robotics Technology (Shanghai) Co., Ltd., Med-X Research Institute, School of Biomedical Engineering, Shanghai Jiao Tong University, Shanghai
China
 Source of Support: None, Conflict of Interest: None
DOI: 10.4103/2773-2398.386228
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Neurological damage after stroke and spinal cord injury often results in walking impairments. The theory of interlimb neural coupling implies that synchronized arm swing should be included during gait training to improve rehabilitation outcomes. We previously developed an automatic rotational orthosis for walking with arm swing (aROWAS), which produced coordinated interlimb movement when running in passive mode. The current case-series study had three aims: to develop impedance control algorithms for generating flexible movement in the aROWAS system, to validate its technical feasibility, and to investigate interlimb muscle activity when using it. A force-free controller was developed to compensate for gravity and friction, and an impedance controller was developed to produce a flexible movement pattern. Experiments were performed on three able-bodied volunteers to evaluate the feasibility of the flexible aROWAS system and muscle activity in their upper and lower limbs was recorded. In force-free mode, the leg rig was static but easily moved by small external forces, and the subjects reported very little resistance when attempting to walk synchronously in the aROWAS system. In impedance mode, the leg rig performed the pre-defined gait pattern, but the joint trajectories were adaptable to external forces. All participants produced earlier hip extension and greater knee flexion during active walking than during passive walking. Furthermore, the arm and lower limb muscles simultaneously produced higher electromyography activity. The control algorithms enabled the aROWAS system to produce walking-like coordinated joint performance in the upper and lower limbs, and also allowed for some degree of adjustment in response to voluntary input from the users. Stronger interlimb muscle activity was produced when participants walked actively in the system. This aROWAS system has the technical potential to serve as an effective tool for investigating interlimb neural coupling and as a novel testbed for walking rehabilitation with synchronized arm swing.
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