Department of Trauma, Hand and Reconstructive Surgery, University of Muenster, Albert-Schweitzer Campus 1, 48149 Münster, Germany.
J Biomech. 2012 May 11;45(8):1457-62. doi: 10.1016/j.jbiomech.2012.02.013. Epub 2012 Mar 3.
Mono- and multi-segmental testing methods are required to identify segmental motion patterns and evaluate the biomechanical behaviour of the spine. This study aimed to evaluate a new testing system for multisegmental specimens using a robot combined with an optical motion analysis system. After validation of the robotic system for accuracy, two groups of calf specimens (six monosegmental vs. six multisegmental) were mounted and the functional unit L3-4 was observed. Using rigid body markers, range of motion (ROM), elastic zone (EZ) and neutral zone (NZ), as well as stiffness properties of each functional spine unit (FSU) was acquired by an optical motion capture system. Finite helical axes (FHA) were calculated to analyse segmental movements. Both groups were tested in flexion and extension. A pure torque of 7.5 Nm was applied. Statistical analyses were performed using the Mann-Whitney U-test. Repeatability of robot positioning was -0.001±0.018 mm and -0.025±0.023° for translations and rotations, respectively. The accuracy of the optical system for the proposed set-up was 0.001±0.034 mm for translations and 0.075±0.12° for rotations. No significant differences in mean values and standard deviations of ROM for L3-4 compared to literature data were found. A robot-based facility for testing multisegmental spine units combined with a motion analysis system was proposed and the reliability and reproducibility of all system components were evaluated and validated. The proposed set-up delivered ROM results for mono- and multi-segmental testing that agreed with those reported in the literature. Representing the FHA via piercing points determined from ROM was the first attempt showing a relationship between ROM and FHA, which could facilitate the interpretation of spine motion patterns in the future.
单节段和多节段测试方法都需要识别节段运动模式并评估脊柱的生物力学行为。本研究旨在评估一种新的多节段标本测试系统,该系统使用机器人结合光学运动分析系统。在验证机器人系统的准确性后,将两组小牛标本(六组单节段与六组多节段)安装并观察 L3-4 功能单位。使用刚体标记,通过光学运动捕捉系统获取每个功能脊柱单位(FSU)的运动范围(ROM)、弹性区(EZ)和中性区(NZ)以及刚度特性。计算有限螺旋轴(FHA)以分析节段运动。两组均在屈伸运动中进行测试。施加 7.5 Nm 的纯扭矩。使用曼-惠特尼 U 检验进行统计分析。机器人定位的重复性为 0.001±0.018 毫米和 0.025±0.023°,分别用于平移和旋转。对于所提出的设置,光学系统的精度为 0.001±0.034 毫米用于平移和 0.075±0.12°用于旋转。与文献数据相比,L3-4 的 ROM 平均值和标准偏差没有显著差异。提出了一种用于测试多节段脊柱单元的基于机器人的设备,结合运动分析系统,并评估和验证了所有系统组件的可靠性和可重复性。所提出的设置提供了用于单节段和多节段测试的 ROM 结果,与文献报道的结果一致。通过从 ROM 确定的穿刺点表示 FHA 是首次尝试,显示了 ROM 和 FHA 之间的关系,这可能有助于未来解释脊柱运动模式。
