Abstract
Lower limb robotic exoskeletons have shown the capability to enhance human locomotion for healthy individuals or to assist motion rehabilitation and daily activities for patients. Recent advances in human-in-the-loop optimization that allowed for assistance customization have demonstrated great potential for performance improvement of exoskeletons. In the optimization process, subjects need to experience multiple types of assistance patterns, thus, leading to a long evaluation time. Besides, some patterns may be uncomfortable for the wearers, thereby resulting in unpleasant optimization experiences and inaccurate outcomes. In this study, we investigated the effectiveness of a series of ankle exoskeleton assistance patterns on improving walking economy prior to optimization. We conducted experiments to systematically evaluate the wearers' biomechanical and physiological responses to different assistance patterns on a lightweight cable-driven ankle exoskeleton during walking. We designed nine patterns in the optimization parameters range which varied peak torque magnitude and peak torque timing independently. Results showed that metabolic cost of walking was reduced by 17.1 ± 7.6% under one assistance pattern. Meanwhile, soleus (SOL) muscle activity was reduced by 40.9 ± 19.8% with that pattern. Exoskeleton assistance changed maximum ankle dorsiflexion and plantarflexion angle and reduced biological ankle moment. Assistance pattern with 48% peak torque timing and 0.75 N·m·kg−1 peak torque magnitude was effective in improving walking economy and can be selected as an initial pattern in the optimization procedure. Our results provided a preliminary understanding of how humans respond to different assistances and can be used to guide the initial assistance pattern selection in the optimization.
Highlights
Advanced lower limb exoskeletons were proposed as a kind of potential device to improve walking efficiency for healthy individuals or to assist rehabilitation and daily activities for patients with motor dysfunctions (Ferris and Young, 2017; Sawicki et al, 2020; Siviy et al, 2020)
Under the M-H condition, the metabolic cost was reduced by 0.44 ± 0.30 W · kg−1 relative to the zero torque assistance (ZT) condition, which is a reduction of 17.1 ± 7.6% (P = 1.5 · 10−11)
We investigated the effectiveness of different assistance patterns on improving walking economy prior to human-in-the-loop optimization on a lightweight cable-driven ankle exoskeleton
Summary
Advanced lower limb exoskeletons were proposed as a kind of potential device to improve walking efficiency for healthy individuals or to assist rehabilitation and daily activities for patients with motor dysfunctions (Ferris and Young, 2017; Sawicki et al, 2020; Siviy et al, 2020). One lightweight untethered ankle exoskeleton for assisting cerebral palsy individuals was capable of reducing the metabolic cost of transport and soleus (SOL) muscle activity and increasing over-ground walking speed (Orekhov et al, 2020). Exoskeletons have shown the ability to effectively enhance human locomotion, the pattern of the assistance can significantly affect device performance and wearing comfortability (Lee et al, 2017; Quinlivan et al, 2017; Nuckols et al, 2021). Both have been substantially improved by humanin-the-loop optimization (HILO) which continuously updates assistance patterns to generate customized assistance.
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