Sagittal and transverse ankle angle coupling can influence prosthetic socket transverse plane moments

IF 1.3 Q3 REHABILITATION
G. Klute, Connor W. Mulcahy
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Abstract

Introduction The intact foot and ankle comprise a complex set of joints that allow rotation in multiple planes of motion. Some of these motions are coupled, meaning rotation in one plane induces motion in another. One such coupling is between the sagittal and transverse planes. For every step, plantar- and dorsi-flexion motion is coupled with external and internal rotation of the shank relative to the foot, respectively. There is no prosthetic foot available for prescription that mimics this natural coupling. The purpose of this study was to determine if a sagittal:transverse ankle angle coupling ratio exists that minimizes the peak transverse plane moment during prosthetic limb stance. Methods A novel, torsionally active prosthesis (TAP) was used to couple sagittal and transverse plane motions using a 60-watt motor. An embedded controller generated transverse plane rotation trajectories proportional to sagittal plane ankle angles corresponding to sagittal:transverse coupling ratios of 1:0 (rigid coupling analogous to the standard-of-care), 6:1, 4:1, 3:1, and 2:1. Individuals with unilateral transtibial amputation were block randomized to walk in a straight line and in both directions around a 2 m circle at their self-selected speed with the TAP set at randomized coupling ratios. The primary outcome was the peak transverse plane moment, normalized to body mass, during prosthetic limb stance. Secondary outcomes included gait biomechanic metrics and a measure of satisfaction. Results Eleven individuals with unilateral transtibial amputations participated in the study. The 6:1 coupling ratio resulted in reduced peak transverse plane moments in pairwise comparisons with 3:1 and 2:1 coupling ratios while walking in a straight line and with the prosthesis on the outside of the circle (p < .05). Coupling ratio had no effect on gait biomechanic metrics or satisfaction. Discussion The general pattern of results suggests a quadratic relationship between the peak transverse plane moment and coupling ratio with a minimum at the 6:1 coupling ratio. The coupling ratio did not appear to adversely affect propulsion or body support. Subjects indicated they found all coupling ratios to be comfortable. While a mechatronic prosthesis like the TAP may have limited commercial potential, our future work includes testing a robust, passive prosthetic foot with a fixed coupling ratio.
踝关节矢状角和横向角耦合会影响假体插座横向平面力矩
引言 完整的足和踝关节由一组复杂的关节组成,可在多个运动平面内旋转。其中一些运动是耦合的,即一个平面的旋转会引起另一个平面的运动。矢状面和横向面之间的耦合就是其中之一。每走一步,跖屈和背屈运动分别与小腿相对于足部的外旋和内旋运动相耦合。目前还没有可以模拟这种自然耦合的义足。本研究的目的是确定踝关节矢状角与横向角的耦合比是否能使假肢站立时的横向平面力矩峰值最小化。方法 采用一种新型扭转主动假肢(TAP),使用 60 瓦电机将矢状面和横向平面运动耦合在一起。嵌入式控制器可生成与矢状面踝关节角度成比例的横向平面旋转轨迹,矢状面与横向平面的耦合比分别为 1:0(与护理标准类似的刚性耦合)、6:1、4:1、3:1 和 2:1。对单侧经胫截肢者进行分块随机分组,让他们以自选速度绕 2 米圆圈直线和双向行走,TAP 设置为随机耦合比。主要结果是假肢站立时的横向平面力矩峰值,以体重为标准。次要结果包括步态生物力学指标和满意度测量。结果 11 名单侧经胫截肢者参加了研究。与 3:1 和 2:1 的耦合比相比,6:1 的耦合比在直线行走时和假肢位于圆圈外侧时可降低横向平面力矩峰值(p < .05)。耦合比对步态生物力学指标或满意度没有影响。讨论 结果的一般模式表明,横向平面力矩峰值与耦合比之间存在二次关系,在耦合比为 6:1 时最小。耦合比似乎不会对推进力或身体支撑力产生不利影响。受试者表示,他们认为所有耦合比都很舒适。虽然像 TAP 这样的机电一体化假肢的商业潜力可能有限,但我们未来的工作包括测试一种具有固定耦合比的坚固、被动式假足。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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