Damage Tolerance and Toughness of Elderly Human Femora

S. Martelli, M. Giorgi, Enrico Dall' Ara, E. Perilli
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引用次数: 8

Abstract

Observations of elastic instability of trabecular bone cores supported the analysis of cortical thickness for predicting bone fragility of the hip in people over 60 years of age. Here, we falsified the hypothesis that elastic instability causes minimal energy fracture by analyzing with a micrometric resolution the deformation and fracture behavior of entire femora. Femur specimens were obtained from elderly women aged between 66 - 80 years. Microstructural images of the proximal femur where obtained under 3 - 5 progressively increased loading steps and after fracture. Bone displacements, strain, load bearing and energy absorption capacity were analyzed. Elastic instability of the cortex appeared at early loading stages in regions of peak compression. No elastic instability of trabecular bone was observed. The subchondral bone displayed local crushing in compression at early loading steps and progressed to 8 - 16% compression before fracture. The energy absorption capacity was proportional to the displacement. Stiffness decreased to near-zero values before fracture. Three-fourth of the fracture energy (10.2 - 20.2 J) was dissipated in the final 25% force increment. Fracture occurred in regions of peak tension and shear, adjacent to the location of peak compression, appearing immediately before fracture. Minimal permanent deformation was visible along the fracture surface. Elastic instability modulates the interaction between cortical and trabecular bone promoting an elastically stable fracture behavior of the femur organ, load bearing capacity, toughness, and damage tolerance. These findings will advance current methods for predicting hip fragility.
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老年人股骨的损伤容忍度和韧性
对骨小梁核心弹性不稳定性的观察支持了皮质厚度预测60岁以上人群髋部骨脆弱性的分析。在这里,我们通过微观分辨率分析整个股骨的变形和骨折行为,证伪了弹性不稳定性导致最小能量骨折的假设。股骨标本取自66 - 80岁的老年妇女。股骨近端显微结构图像是在3 - 5加载步骤逐渐增加和骨折后获得的。分析了骨位移、应变、承载和能量吸收能力。皮质弹性失稳出现在加载初期的峰值压缩区。未见骨小梁弹性失稳。软骨下骨在早期加载阶段表现为局部挤压,并在骨折前发展到8 - 16%的压缩。能量吸收能力与位移成正比。断裂前刚度降至接近零值。四分之三的断裂能(10.2 - 20.2 J)在最后25%的力增量中耗散。断裂发生在张力和剪切峰值区域,与压缩峰值位置相邻,在断裂前立即出现。沿断裂面可见最小的永久变形。弹性不稳定性调节皮质骨和骨小梁之间的相互作用,促进股骨器官的弹性稳定骨折行为、承载能力、韧性和损伤容忍度。这些发现将推动目前预测髋关节脆弱性的方法。
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