Effects of Soft Robotic Exosuit on Exercise Capacity, Biomakers of Neuroplasticity, and Motor Learning After Stroke

Prior studies of the exosuit technology have culminated in strong evidence for the gait-restorative effects of soft robotic exosuits for patients post-stroke by means of substitution for impaired paretic limb function during walking. The present study builds on this work by suggesting that an exosuit's immediate gait-restorative effects can be leveraged during high intensity gait training to produce post-training improvements in gait quality. Indeed, current rehabilitation efforts are focused on either quality or intensity. They focus on gait quality by reducing the training intensity to allow patients to achieve a more normal gait. In contrast, efforts focused on training intensity push participants without regard for the quality of their movements. The investigators posit that exosuits can uniquely enable high intensity gait training that promotes quality of movements.

Acute bouts of high intensity exercise prior to skilled task practice have been shown to enhance motor learning in neurologically intact individuals. However, the impact of high intensity exercise on motor learning in clinical populations remains largely unknown. A major limitation to studying this relationship in survivors of stroke are challenges in achieving and maintaining high intensity exercise levels (>75% max HR) during gait training for durations that are comparable to neurologically intact individuals. Exercising at a lower intensity or for a shorter duration may result in insufficient neurological "priming" for motor learning that typically follows high intensity training-which would be evidenced in reduced production of activity-dependent markers of neuroplasticity (e.g., brain-derived neurotrophic factor; BDNF). For this study, the investigators will use standardized, maximal effort tests to evaluate the ability of a soft robotic exosuit to increase a patient's capacity for high intensity gait training. The investigators will also examine the resulting effect on BDNF and the relationship between training intensity, BDNF and motor learning measures.