Abstract
Assistive devices may aid motor recovery after a stroke, but access to such devices is limited. Exosuits can aid human movement and may be more accessible alternatives to current devices, but we know little about how they might assist post-stroke upper extremity movement. Here, we designed an exosuit actuator to support shoulder abduction, which we call an “exomuscle” and is based on a form of growing robot called a pneumatic-reel actuator. We also assembled a ceiling-mounted support for a positive control. We verified that both supports reduce the activity of shoulder abductor muscles and do not impede range of motion in healthy participants (n=4). Then, we measured reachable workspace area in stroke survivors (n=6) with both supports and without support. Our exomuscle increased workspace area in four participants (180±90 cm2) while the ceiling support increased workspace area in five participants (792±540 cm2). Design decisions that reduce exomuscle complexity, such as leaving the forearm free, likely contribute to performance differences between the two supports. Heterogeneity amongst stroke survivors’ abilities likely contribute to high variability in our results. Though both supports performed similarly for healthy participants, performance differences in stroke survivors highlight the need to validate assistive devices in the target population.
- Exosuit
- stroke
- assistance
- workspace
- flexor synergy
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
This work was supported in part by Stanford’s Stroke Collaborative Action Network, the Wu Tsai Neurosciences Institute at Stanford University, the National Science Foundation Graduate Research Fellowship Program, and National Science Foundation grants 1637446 and 1830163.