[具有时变刚度的骨折内固定植入物的结构设计和骨重塑效果评估]。

Q4 Medicine
Hao Sun, Xiaohong Ding, Shipeng Xu, Pengyun Duan, Min Xiong, Heng Zhang
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引用次数: 0

摘要

理想的骨折内固定植入物的刚度应具有随时间变化的性能,从而使骨折在不同愈合阶段都能产生合理的机械刺激,而生物降解材料就能满足这一性能。考虑到材料随时间变化的降解过程,提出了一种具有时变刚度的骨折内固定植入物复合结构的拓扑优化设计方法。利用相对密度和降解残余率来描述两种具有不同降解率和弹性模量的材料的分布和降解状态,建立了降解模拟力学分析的耦合数学模型。基于变密度法设计的生物材料复合结构表现出随时间变化的刚度特性。以治疗胫骨骨折的骨板为例,利用所提出的方法设计了具有时变刚度特性的复合结构骨板。优化结果表明,高刚度材料 1 形成了柱状支撑结构,而低刚度材料 2 分布在退化边界和内部。利用骨重塑模拟模型,对优化后的骨板进行了评估。经过11个月的重塑后,使用可降解时变刚度骨板、钛合金骨板和不锈钢骨板的胼胝体平均弹性模量分别为8 634兆帕、8 521兆帕和8 412兆帕,这表明使用可降解时变刚度骨板会对胼胝体产生更好的重塑效果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
[Structural design and evaluation of bone remodeling effect of fracture internal fixation implants with time-varying stiffness].

The stiffness of an ideal fracture internal fixation implant should have a time-varying performance, so that the fracture can generate reasonable mechanical stimulation at different healing stages, and biodegradable materials meet this performance. A topology optimization design method for composite structures of fracture internal fixation implants with time-varying stiffness is proposed, considering the time-dependent degradation process of materials. Using relative density and degradation residual rate to describe the distribution and degradation state of two materials with different degradation rates and elastic modulus, a coupled mathematical model of degradation simulation mechanical analysis was established. Biomaterial composite structures were designed based on variable density method to exhibit time-varying stiffness characteristics. Taking the bone plate used for the treatment of tibial fractures as an example, a composite structure bone plate with time-varying stiffness characteristics was designed using the proposed method. The optimization results showed that material 1 with high stiffness formed a columnar support structure, while material 2 with low stiffness was distributed at the degradation boundary and inside. Using a bone remodeling simulation model, the optimized bone plates were evaluated. After 11 months of remodeling, the average elastic modulus of callus using degradable time-varying stiffness plates, titanium alloy plates, and stainless steel plates were 8 634 MPa, 8 521 MPa, and 8 412 MPa, respectively, indicating that the use of degradable time-varying stiffness plates would result in better remodeling effects on the callus.

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来源期刊
生物医学工程学杂志
生物医学工程学杂志 Medicine-Medicine (all)
CiteScore
0.80
自引率
0.00%
发文量
4868
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