Department of Bioenvironmental Medicine, Graduate School of Medicine, Chiba University, 1-8-1 Inohana, Chou-Ku, Chiba city, Chiba, Japan.
Department of Orthopaedic Surgery, Graduate School of Medicine, Chiba University, 1-8-1 Inohana, Chou-Ku, Chiba city, Chiba, Japan.
Bone. 2020 Mar;132:115212. doi: 10.1016/j.bone.2019.115212. Epub 2019 Dec 28.
As fractures heal, immature callus formed in the hematoma is calcified by osteoblasts and altered to mature bone. Although the bone strength in the fracture-healing process cannot be objectively measured in clinical settings, bone strength can be predicted by specimen-specific finite element modeling (FEM) of quantitative computed tomography (qCT) scans. FEM predictions of callus strength would enable an objective treatment plan. The present study establishes an equation that converts material properties to bone density and proposes a specimen-specific FEM. In 10 male New Zealand white rabbits, a 10-mm long bone defect was created in the center of the femur and fixed by an external fixator. The callus formed in the defect was extracted after 3-6 weeks, and formed into a (5 × 5 × 5 mm) cube. The bone density measured by qCT was related to the Young's modulus and the yield stress measured with a mechanical tester. For validation, a 10-mm long bone defect was created in the central femurs of another six New Zealand white rabbits, and fixed by an external fixator. At 3, 4, and 5 weeks, the femur was removed and subjected to Computed tomography (CT) scanning and mechanical testing. A specimen-specific finite element model was created from the CT data. Finally, the bone strength was measured and compared with the experimental value. The bone mineral density σ was significantly and nonlinearly correlated with both the Young's modulus E and the yield stress σ. The material-property conversion equations were E = 0.2391e and ρ = 30.49σ. Moreover, the experimental bone strength was significantly linearly correlated with the prospective FEM. We demonstrated the Young's moduli and yield stresses for different bone densities, enabling a FEM of the bone-healing process. An FEM based on these material properties is expected to yield objective clinical judgment criteria.
随着骨折愈合,血肿中形成的不成熟骨痂被成骨细胞矿化并转变为成熟骨。虽然在临床环境中无法客观测量骨折愈合过程中的骨强度,但可以通过定量计算机断层扫描(qCT)扫描的特定标本有限元建模(FEM)来预测骨强度。骨痂强度的 FEM 预测将使治疗计划具有客观性。本研究建立了一个将材料特性转换为骨密度的方程,并提出了一种特定于标本的 FEM。在 10 只雄性新西兰白兔中,股骨中心处创建了一个 10mm 长的骨缺损,并通过外固定器固定。在 3-6 周后,从缺损中提取形成的骨痂,并将其制成(5×5×5mm)的立方体。qCT 测量的骨密度与机械试验机测量的杨氏模量和屈服应力相关。为了验证,在另外 6 只新西兰白兔的股骨中心处创建了一个 10mm 长的骨缺损,并通过外固定器固定。在 3、4 和 5 周时,取出股骨并进行 CT 扫描和机械测试。从 CT 数据创建特定于标本的有限元模型。最后,测量骨强度并与实验值进行比较。骨矿物质密度σ与杨氏模量 E 和屈服应力σ显著呈非线性相关。材料特性转换方程为 E=0.2391e 和 ρ=30.49σ。此外,实验骨强度与前瞻性 FEM 呈显著线性相关。我们展示了不同骨密度的杨氏模量和屈服应力,为骨愈合过程的 FEM 提供了基础。基于这些材料特性的 FEM 有望产生客观的临床判断标准。
