Institute of Lightweight Design and Structural Biomechanics, Vienna University of Technology, Austria.
J Biomech. 2012 Jun 1;45(9):1733-8. doi: 10.1016/j.jbiomech.2012.03.019. Epub 2012 Apr 13.
Every year, 500,000 osteoporotic vertebral compression fractures occur in Europe. Quantitative computed tomography (QCT)-based finite element (FE) voxel models predict ultimate force whether they simulate vertebral bodies embedded in polymethylmethacrylate (PMMA) or vertebral sections with both endplates removed. To assess the effect of endplate removal in those predictions, non-linear FE analyses of QCT-based voxel models of human vertebral bodies were performed. High resolution pQCT images of 11 human lumbar vertebrae without posterior elements were coarsened to clinical resolution and bone volume fraction was used to determine the elastic, plastic and damage behavior of bone tissue. Three model boundary conditions (BCs) were chosen: the endplates were cropped (BC1, BC2) or voxel layers were added on the intact vertebrae to mimic embedding (BC3). For BC1 and BC3, the bottom nodes were fully constrained and the top nodes were constrained transversely while both node sets were freed transversely for BC2. Axial displacement was prescribed to the top nodes. In each model, we compared ultimate force and damage distribution during post-yield loading. The results showed that ultimate forces obtained with BC3 correlated perfectly with those computed with BC1 (R(2)=0.9988) and BC2 (R(2)=0.9987), but were in average 3.4% lower and 6% higher respectively. Moreover, good correlation of damage distribution calculated for BC3 was found with those of BC1 (R(2)=0.92) and BC2 (R(2)=0.73). This study demonstrated that voxel models of vertebral sections provide the same ultimate forces and damage distributions as embedded vertebral bodies, but with less preprocessing and computing time required.
每年,欧洲有 50 万例骨质疏松性椎体压缩性骨折发生。基于定量计算机断层扫描(QCT)的有限元(FE)体素模型可以预测极限力,无论它们模拟的是嵌入聚甲基丙烯酸甲酯(PMMA)中的椎体还是去除了终板的椎体节段。为了评估终板去除对这些预测的影响,对基于 QCT 的人体椎体体素模型进行了非线性 FE 分析。11 个人体腰椎椎体的高分辨率 pQCT 图像没有后元素,被粗化到临床分辨率,骨体积分数用于确定骨组织的弹性、塑性和损伤行为。选择了三种模型边界条件(BC):终板被裁剪(BC1、BC2)或在完整的椎体上添加体素层以模拟嵌入(BC3)。对于 BC1 和 BC3,底部节点被完全约束,顶部节点被横向约束,而两个节点集都被横向释放,对于 BC2。顶部节点被规定轴向位移。在每个模型中,我们比较了屈服后加载过程中的极限力和损伤分布。结果表明,BC3 获得的极限力与 BC1(R²=0.9988)和 BC2(R²=0.9987)计算的极限力完全相关,但平均分别低 3.4%和高 6%。此外,还发现 BC3 计算的损伤分布与 BC1(R²=0.92)和 BC2(R²=0.73)的损伤分布有很好的相关性。本研究表明,椎体节段的体素模型可以提供与嵌入椎体相同的极限力和损伤分布,但所需的预处理和计算时间更少。
