Talus Fracture - a Pathomechanical Study Using Finite Element Analysis.

Q3 Medicine

Ortopedia, traumatologia, rehabilitacja Pub Date : 2025-04-30 DOI:10.5604/01.3001.0055.2408

Mongkol Kaewbumrung, Chayanin Angthong, Prasit Rajbhandari, Naruebade Rungrattanawilai

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引用次数: 0

Abstract

Background: The talus is a peculiar bone in the human body that plays a key role in load transfer due to its unique shape and characteristics. Fractures involve challenging treatment and potential complications. We aimed to simulate the talus using real-world data and analyze its biomechanical responses to potential forces that might cause its fracture.

Material and methods: We retrieved a three-dimensional (3D) file of the intact talus, submitted it to a 3D finite element analysis (FEA) using software (ANSYS Mechanical V2023R2), and then set the elastic modulus or Young's modulus values of the talus based on a previous study. To analyze talar fractures, we employed both positive and negative force directions to examine fracture behavior. The talar configurations were 0 , 15, 30, and 45 cases. Force applied in the y-direction compressed the top of the talus. The bottom surface of the talus, subjected to compression, supports the boundary conditions that mimic realistic talus motion mechanics.

Results: FEA demonstrated that the neck of the talus exhibited the highest magnitude of total deformation, suggesting susceptibility to crack initiation. A sudden increase in force in the positive direction increased the likelihood of a talar fracture. Stress analysis depicted the maximum equivalent (von Mises) stress on the talus, indicating that the highest stress occurred when the force was applied in the positive direction, particularly at 15 (posterosuperior to the anteroinferior direction). Our analysis underscores that the angle of force is the primary contributor to talar fractures.

Conclusion: Our 3D FEA study concluded that the talar neck area was the most vulnerable to fracture in the axial force simulation, especially in the 15 force direction. Safety measures should be implemented for people performing risky activities related to axial force injuries.

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距骨骨折-应用有限元分析的病理力学研究。

背景：距骨是人体中一种特殊的骨骼，由于其独特的形状和特征，在负荷传递中起着关键作用。骨折包括具有挑战性的治疗和潜在的并发症。我们的目的是利用真实世界的数据模拟距骨，并分析其对可能导致其骨折的潜在力的生物力学反应。材料和方法：检索完整距骨的三维（3D）文件，使用ANSYS Mechanical V2023R2软件进行三维有限元分析（FEA），然后根据前人的研究设置距骨的弹性模量或杨氏模量值。为了分析距骨骨折，我们采用正、负两个方向的力来检查骨折行为。talar构型分别为0、15、30、45例。施加在y方向的力压缩了距骨的顶部。受到压缩的距骨的底面支持模拟真实距骨运动力学的边界条件。结果：有限元分析表明，距骨颈部的总变形幅度最大，表明对裂纹萌生的敏感性。正向力的突然增加增加距骨骨折的可能性。应力分析描述了距骨上的最大等效应力（von Mises），表明在正向方向施加力时发生最大应力，特别是在15（后上而不是前下方向）。我们的分析强调，用力角度是距骨骨折的主要因素。结论：我们的三维有限元分析表明，在轴向力模拟中，距骨颈部区域最容易发生骨折，特别是在15个力方向上。对于从事与轴向力伤害有关的危险活动的人员，应采取安全措施。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Ortopedia, traumatologia, rehabilitacja Medicine-Rehabilitation

CiteScore

1.00

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0.00%

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