用于在行走中复制腓肠肌功能的准被动经胫双关节假体的设计与开发。

Design and Development of a Quasi-Passive Transtibial Biarticular Prosthesis to Replicate Gastrocnemius Function in Walking.

作者信息

Willson Andrea M, Richburg Chris A, Czerniecki Joseph, Steele Katherine M, Aubin Patrick M

机构信息

Department of Mechanical Engineering, University of Washington, Seattle, WA 98195; VA RR&D Center for Limb Loss and MoBility (CLiMB), VA Puget Sound Health Care System, Seattle, WA 98108.

VA RR&D Center for Limb Loss and MoBility (CLiMB), VA Puget Sound Health Care System, Seattle, WA 98108.

出版信息

J Med Device. 2020 Jun 1;14(2):0250011-250016. doi: 10.1115/1.4045879. Epub 2020 Feb 18.

DOI:10.1115/1.4045879

PMID:32280409

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7104771/

Abstract

Lower-limb amputees experience many gait impairments and limitations. Some of these impairments can be attributed to the lack of a functioning biarticular gastrocnemius (GAS) muscle. We propose a transtibial prosthesis that implements a quasi-passive spring mechanism to replicate GAS function. A prototype biarticular prosthesis (BP) was designed, built, and tested on one subject with a transtibial amputation. They walked on an instrumented treadmill with motion capture under three different biarticular spring stiffness conditions. A custom-developed OpenSim musculoskeletal model, which included the BP, was used to calculate the work performed and torque applied by the BP spring on the knee and ankle joints. The BP functioned as expected, generating forces with similar timing to GAS. Work transfer occurred from the ankle to the knee, with stiffer springs transferring more energy. Driven mostly by kinematics, the quasi-passive design of the BP consumed very low power (5.15 W average) and could lend itself well to future lightweight, low-power designs.

摘要

下肢截肢者存在许多步态障碍和限制。其中一些障碍可归因于缺乏起作用的双关节腓肠肌（GAS）。我们提出了一种经胫骨假肢，该假肢采用准被动弹簧机制来复制GAS的功能。设计、制造了一种双关节假肢原型（BP），并在一名经胫骨截肢患者身上进行了测试。他们在装有仪器的跑步机上行走，在三种不同的双关节弹簧刚度条件下进行动作捕捉。使用一个定制开发的包含BP的OpenSim肌肉骨骼模型，来计算BP弹簧在膝关节和踝关节上所做的功以及施加的扭矩。BP按预期发挥作用，产生的力在时间上与GAS相似。功从踝关节转移到膝关节，弹簧越硬，转移的能量越多。主要由运动学驱动，BP的准被动设计消耗的功率非常低（平均5.15瓦），并且很适合未来的轻量化、低功率设计。

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本文引用的文献

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