A Biologically Inspired Cross-Type Ankle–Foot Exotendon: Assisting Plantarflexion Moment and Movement Stability

Cable-driven ankle–foot exoskeletons have attracted numerous researchers over the previous decade. The assistive forces of most exoskeletons pulled the back bottom of the shoes, across talocrural and subtalar joints. The talocrural joint is inherently mediolateral unstable at the plantarflexion posi...

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Published in	Journal of bionics engineering Vol. 20; no. 6; pp. 2633 - 2645
Main Authors	Liu, Yuyao, Sun, Ronglei, Li, Ying, Zhang, Miao, Zou, Kaijie
Format	Journal Article
Language	English
Published	Singapore Springer Nature Singapore 01.11.2023
Subjects	Artificial Intelligence Biochemical Engineering Bioinformatics Biomaterials Biomedical Engineering and Bioengineering Biomedical Engineering/Biotechnology Engineering Research Article Cross-type double-cable-driven Exoskeleton Ankle–foot exotendon Bionic design Muscle arrangement
Online Access	Get full text
ISSN	1672-6529 2543-2141
DOI	10.1007/s42235-023-00398-y

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Abstract	Cable-driven ankle–foot exoskeletons have attracted numerous researchers over the previous decade. The assistive forces of most exoskeletons pulled the back bottom of the shoes, across talocrural and subtalar joints. The talocrural joint is inherently mediolateral unstable at the plantarflexion position due to its sliding mortise structure, while the subtalar joint allows inversion/eversion. In this paper, a biologically inspired cross-type double-cable-driven ankle–foot exotendon was proposed to assist not only the plantarflexion moment but also the movement stability. The novel structure was bio-inspired by the behind-calf anatomically symmetric layout and under-foot cross-configuration of the ankle–foot muscles. To examine the combined functions, we conducted a forward pelvis perturbed standing experiment on five subjects without and with exotendon assistance and recorded the biomechanical data. Compared to the unpowered condition, the biological ankle plantarflexion moment was reduced by 39 % with 0.1 Nm/kg exotendon assistance for one leg. Besides, the forward margin of stability was increased by 17 % during the late perturbation period, which indicated the improvement of balance in the sagittal plane. In addition, the standard deviation of the lateral CoP and three-dimensional marker trajectories for the ankle condylar and heel all descended, which provided evidence for ankle–foot stability improvement. The results suggested that the proposed biological exotendon can provide the compound ankle–foot assistance, reducing plantarflexion moment and improving movement stability.
AbstractList	Cable-driven ankle–foot exoskeletons have attracted numerous researchers over the previous decade. The assistive forces of most exoskeletons pulled the back bottom of the shoes, across talocrural and subtalar joints. The talocrural joint is inherently mediolateral unstable at the plantarflexion position due to its sliding mortise structure, while the subtalar joint allows inversion/eversion. In this paper, a biologically inspired cross-type double-cable-driven ankle–foot exotendon was proposed to assist not only the plantarflexion moment but also the movement stability. The novel structure was bio-inspired by the behind-calf anatomically symmetric layout and under-foot cross-configuration of the ankle–foot muscles. To examine the combined functions, we conducted a forward pelvis perturbed standing experiment on five subjects without and with exotendon assistance and recorded the biomechanical data. Compared to the unpowered condition, the biological ankle plantarflexion moment was reduced by 39 % with 0.1 Nm/kg exotendon assistance for one leg. Besides, the forward margin of stability was increased by 17 % during the late perturbation period, which indicated the improvement of balance in the sagittal plane. In addition, the standard deviation of the lateral CoP and three-dimensional marker trajectories for the ankle condylar and heel all descended, which provided evidence for ankle–foot stability improvement. The results suggested that the proposed biological exotendon can provide the compound ankle–foot assistance, reducing plantarflexion moment and improving movement stability.
Author	Zhang, Miao Li, Ying Zou, Kaijie Liu, Yuyao Sun, Ronglei
Author_xml	– sequence: 1 givenname: Yuyao surname: Liu fullname: Liu, Yuyao organization: State Key Laboratory of Intelligent Manufacturing Equipment and Technology, School of Mechanical Science and Engineering, Huazhong University of Science and Technology – sequence: 2 givenname: Ronglei surname: Sun fullname: Sun, Ronglei email: ronglei@hust.edu.cn organization: State Key Laboratory of Intelligent Manufacturing Equipment and Technology, School of Mechanical Science and Engineering, Huazhong University of Science and Technology – sequence: 3 givenname: Ying surname: Li fullname: Li, Ying organization: State Key Laboratory of Intelligent Manufacturing Equipment and Technology, School of Mechanical Science and Engineering, Huazhong University of Science and Technology – sequence: 4 givenname: Miao surname: Zhang fullname: Zhang, Miao organization: State Key Laboratory of Intelligent Manufacturing Equipment and Technology, School of Mechanical Science and Engineering, Huazhong University of Science and Technology – sequence: 5 givenname: Kaijie surname: Zou fullname: Zou, Kaijie organization: State Key Laboratory of Intelligent Manufacturing Equipment and Technology, School of Mechanical Science and Engineering, Huazhong University of Science and Technology
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Title	A Biologically Inspired Cross-Type Ankle–Foot Exotendon: Assisting Plantarflexion Moment and Movement Stability
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