Eswaran Senthil K, Bevill Grant, Nagarathnam Prem, Allen Matthew R, Burr David B, Keaveny Tony M
Orthopaedic Biomechanics Laboratory, Department of Mechanical Engineering, University of California, Berkeley, CA 94720, USA.
J Biomech. 2009 Mar 11;42(4):517-23. doi: 10.1016/j.jbiomech.2008.11.023. Epub 2009 Jan 31.
The relative biomechanical effects of antiresorptive treatment on cortical thickness vs. trabecular bone microarchitecture in the spine are not well understood. To address this, T-10 vertebral bodies were analyzed from skeletally mature female beagle dogs that had been treated with oral saline (n=8 control) or a high dose of oral risedronate (0.5mg/kg/day, n=9 RIS-suppressed) for 1 year. Two linearly elastic finite element models (36-mum voxel size) were generated for each vertebral body-a whole-vertebra model and a trabecular-compartment model-and subjected to uniform compressive loading. Tissue-level material properties were kept constant to isolate the effects of changes in microstructure alone. Suppression of bone turnover resulted in increased stiffness of the whole vertebra (20.9%, p=0.02) and the trabecular compartment (26.0%, p=0.01), while the computed stiffness of the cortical shell (difference between whole-vertebra and trabecular-compartment stiffnesses, 11.7%, p=0.15) was statistically unaltered. Regression analyses indicated subtle but significant changes in the relative structural roles of the cortical shell and the trabecular compartment. Despite higher average cortical shell thickness in RIS-suppressed vertebrae (23.1%, p=0.002), the maximum load taken by the shell for a given value of shell mass fraction was lower (p=0.005) for the RIS-suppressed group. Taken together, our results suggest that-in this canine model-the overall changes in the compressive stiffness of the vertebral body due to suppression of bone turnover were attributable more to the changes in the trabecular compartment than in the cortical shell. Such biomechanical studies provide an unique insight into higher-scale effects such as the biomechanical responses of the whole vertebra.
抗吸收治疗对脊柱皮质厚度与小梁骨微结构的相对生物力学影响尚未完全明确。为解决这一问题,对1年中接受口服生理盐水(n = 8只对照)或高剂量口服利塞膦酸盐(0.5mg/kg/天,n = 9只RIS抑制组)治疗的骨骼成熟雌性比格犬的T-10椎体进行分析。为每个椎体生成两个线性弹性有限元模型(体素大小为36μm)——一个全椎体模型和一个小梁腔模型——并对其施加均匀压缩载荷。组织水平的材料属性保持不变,以单独分离微观结构变化的影响。骨转换的抑制导致全椎体(20.9%,p = 0.02)和小梁腔(26.0%,p = 0.01)的刚度增加,而皮质壳的计算刚度(全椎体和小梁腔刚度之间的差异,11.7%,p = 0.15)在统计学上未改变。回归分析表明皮质壳和小梁腔的相对结构作用发生了细微但显著的变化。尽管RIS抑制组椎体的平均皮质壳厚度更高(23.1%,p = 0.002),但对于给定的壳质量分数值,该组皮质壳承受的最大载荷更低(p = 0.005)。综上所述,我们的结果表明——在这个犬类模型中——由于骨转换抑制导致的椎体压缩刚度的总体变化更多地归因于小梁腔的变化而非皮质壳的变化。此类生物力学研究为诸如全椎体生物力学反应等更高尺度的效应提供了独特的见解。