University of Minnesota, Minneapolis, MN, USA.
J Biomech. 2011 Sep 2;44(13):2383-7. doi: 10.1016/j.jbiomech.2011.06.034. Epub 2011 Jul 20.
In vitro spine flexibility testing has been performed using a variety of laboratory-specific loading apparatuses and conditions, making test results across laboratories difficult to compare. The application of pure moments has been well established for spine flexibility testing, but to our knowledge there have been no attempts to quantify differences in range of motion (ROM) resulting from laboratory-specific loading apparatuses. Seven fresh-frozen lumbar cadaveric motion segments were tested intact at four independent laboratories. Unconstrained pure moments of 7.5 Nm were applied in each anatomic plane without an axial preload. At laboratories A and B, pure moments were applied using hydraulically actuated spinal loading fixtures with either a passive (A) or controlled (B) XY table. At laboratories C and D, pure moments were applied using a sliding (C) or fixed ring (D) cable-pulley system with a servohydraulic test frame. Three sinusoidal load-unload cycles were applied at laboratories A and B while a single quasistatic cycle was applied in 1.5 Nm increments at laboratories C and D. Non-contact motion measurement systems were used to quantify ROM. In all test directions, the ROM variability among donors was greater than single-donor ROM variability among laboratories. The maximum difference in average ROM between any two laboratories was 1.5° in flexion-extension, 1.3° in lateral bending and 1.1° in axial torsion. This was the first study to quantify ROM in a single group of spinal motion segments at four independent laboratories with varying pure moment systems. These data support our hypothesis that given a well-described test method, independent laboratories can produce similar biomechanical outcomes.
体外脊柱灵活性测试使用各种实验室专用的加载设备和条件进行,使得实验室之间的测试结果难以比较。纯力矩在脊柱灵活性测试中已经得到了很好的应用,但据我们所知,还没有人试图量化由于实验室专用加载设备而导致的运动范围 (ROM) 差异。七个新鲜冷冻的腰椎运动节段在四个独立的实验室中完整地进行了测试。在没有轴向预载的情况下,每个解剖平面施加 7.5Nm 的无约束纯力矩。在实验室 A 和 B,纯力矩使用液压驱动的脊柱加载夹具施加,夹具带有被动(A)或受控(B)XY 工作台。在实验室 C 和 D,纯力矩使用滑动(C)或固定环(D)电缆滑轮系统施加,系统带有伺服液压测试框架。在实验室 A 和 B 施加了三个正弦加载-卸载循环,而在实验室 C 和 D 以 1.5Nm 的增量施加了一个准静态循环。使用非接触式运动测量系统来量化 ROM。在所有测试方向上,供体之间的 ROM 变异性大于单个供体在实验室之间的 ROM 变异性。任何两个实验室之间平均 ROM 的最大差异在屈伸方向为 1.5°,在侧屈方向为 1.3°,在轴向扭转方向为 1.1°。这是第一项在四个具有不同纯力矩系统的独立实验室中对一组单一脊柱运动节段的 ROM 进行量化的研究。这些数据支持我们的假设,即给定一个描述良好的测试方法,独立的实验室可以产生类似的生物力学结果。
