Multiaxial spine testing apparatus: system characterisation by evaluation of analogue and cadaveric lumbar spines

International journal of experimental and computational biomechanics Pub Date : 2013-09-26 DOI:10.1504/IJECB.2013.056544

Zachary A. Dooley, Alexander W. L. Turner, G. Bryan Corwall

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引用次数: 6

Abstract

A custom 6 degrees-of-freedom test system was developed to collect unconstrained pure-moment biomechanical data from excised multi-segmental human spines. In this study, two characterisation methods were utilised. First, a polyethylene analogue model was created to establish test system baseline performance. Second, 22 lumbar spines (L1–L5) were tested to understand system operation under actual usage accounting for specimen stiffness and coupled motions. Each lumbar spine was tested in the anatomical planes (flexion-extension, lateral bending, and axial rotation) under two different conditions (intact and after implantation with an interbody cage at L3–L4). Specimen range of motion, neutral zone, and force/torque component errors generated by the test system were similar to previously reported data. Pure-moments were repeatable throughout the experiment in both cadaveric conditions, indicated by consistency in range of motion and neutral zone at the non-index levels. This characterisation will assist with interpretation of experimental data generated by the test system.

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多轴脊柱试验装置:通过评价模拟腰椎和尸体腰椎的系统特性

开发了自定义的6自由度测试系统，用于从切除的多节段人体脊柱中收集无约束的纯时刻生物力学数据。在本研究中，使用了两种表征方法。首先，建立了一个聚乙烯模拟模型来建立测试系统的基准性能。其次，对22根腰椎(L1-L5)进行测试，了解实际使用下的系统运行情况，考虑试件刚度和耦合运动。在两种不同的条件下(完整和在L3-L4植入椎间笼后)，对每个腰椎进行解剖平面(屈伸、侧屈和轴向旋转)测试。测试系统产生的试样运动范围、中性区和力/扭矩分量误差与先前报道的数据相似。在整个实验过程中，纯瞬间在两种尸体条件下都是可重复的，通过运动范围的一致性和非指数水平的中性区来表明。这种特性将有助于解释由测试系统产生的实验数据。

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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International journal of experimental and computational biomechanics

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