Department of Rehabilitative Sciences, East Tennessee State University, Johnson City, TN 37614, USA.
Orthotics and Prosthetics Unit, Kennesaw State University, Kennesaw, GA 30144-5591, USA.
Clin Biomech (Bristol). 2021 Feb;82:105285. doi: 10.1016/j.clinbiomech.2021.105285. Epub 2021 Jan 30.
This study, the first of its kind, originated with the need for a brace (an ankle foot orthosis), to constrain ankle plantarflexion and dorsiflexion within a motion threshold of <5°. A conventional thermoplastic, solid brace failed during a quasi-static loading study, informing the investigation and development of an experimental carbon composite brace, maximizing stiffness and proximity of shank and foot cylindrical shells to provide the required degree of control.
Two experiments were conducted: a quasi-static loading study, using cadaveric limbs (n = 2), and a gait study with healthy subjects (n = 14). Conditions tested were STOP, FREE, and CONTROL. Data for all studies were collected using six motion-capture cameras (Vicon, Oxford, UK; 120 Hz) tracking bone-anchored markers (cadaveric limbs) and skin-anchored markers (subjects). In the quasi-static loading study, loading conditions were congruent with the gait study. Study 1 involved a quasi-static loading analysis using cadaveric limbs, compared motion data from a conventional thermoplastic solid brace and the experimental brace. Study 2 involved quantifying ankle plantarflexion and dorsiflexion in subjects during treadmill walking, in brace STOP, FREE, and CONTROL conditions.
The experimental brace in STOP condition consistently constrained ankle plantarflexion and dorsiflexion below the motion threshold of <5°, across all studies.
Collectively, these findings demonstrate (1) that a conventional thermoplastic, solid brace was ineffective for clinical applications that required significant motion control, and (2) that ankle motion control is most effective when considered as a relationship between the brace, the ankle-foot complex, and the external forces that affect them both.
本研究是首例需要矫形器(踝足矫形器)的研究,该矫形器需要将踝关节的跖屈和背屈运动限制在<5°的运动阈值内。在准静态加载研究中,传统的热塑性整体支具失效,这促使我们对一种实验性的碳纤维复合材料支具进行研究和开发,该支具最大限度地提高了刚度,并使小腿和足部的圆柱壳尽可能接近,以提供所需的控制程度。
进行了两项实验:一项是使用尸体肢体(n=2)的准静态加载研究,另一项是使用健康受试者(n=14)的步态研究。测试的条件是 STOP、FREE 和 CONTROL。所有研究的数据均使用六台运动捕捉摄像机(英国牛津的 Vicon;120Hz)收集,这些摄像机跟踪骨锚定标记(尸体肢体)和皮肤锚定标记(受试者)。在准静态加载研究中,加载条件与步态研究一致。研究 1 涉及使用尸体肢体的准静态加载分析,比较了传统热塑性整体支具和实验支具的运动数据。研究 2 涉及在跑步机行走过程中,定量测量受试者在支具 STOP、FREE 和 CONTROL 条件下的踝关节跖屈和背屈。
在所有研究中,在 STOP 条件下,实验支具始终将踝关节的跖屈和背屈限制在<5°的运动阈值以下。
这些发现共同表明:(1)对于需要进行显著运动控制的临床应用,传统的热塑性整体支具效果不佳;(2)当将踝关节运动控制视为支具、踝足复合体以及影响它们的外力之间的关系时,其效果最佳。
