Influence of keel shape of Salto Talaris^TM total ankle prosthesis on the biomechanical performance on the bone-implant interface: A finite-element analysis.

IF 1.3 4区医学 Q2 Medicine

Journal of Foot & Ankle Surgery Pub Date : 2025-10-02 DOI:10.1053/j.jfas.2025.09.011

Zhang Yingdong, Li Heng, Xu Xiangyu, Wu Yong

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引用次数: 0

Abstract

Purpose: This study aimed to evaluate the effects of changing the keel shape of the tibial component of a keel-type total ankle prosthesis on its biomechanical behavior and to identify possible directions for further prosthesis selection and improvement.

Methods: Finite elements analysis was applied to analysis the influence on biomechanical effects of the shape of tibia implant keel in total ankle prostheses. CT of a male volunteer was used to develop tibia models with different prosthesis designs based on the tibia implant of Salto TalarisTM ankle prosthesis. Biomechanical properties including stress, micromotion and strain were evaluated.

Results: The peak stress and micromotion of the design with short keel and vertical holes were 85.3 MPa and 62.87 μm, respectively, which were 36.7 % and 84.4 % lower than the original design. The proportion of units with satisfactory osseointegration in the periprosthetic bone tissue reached 20.09 % in this design and was 19.1 % more than the original design.

Conclusion: Reducing the length of keel of the tibia prosthesis to the underlying support structure and reorienting the lateral holes to the vertical direction could improve the stability of the prosthesis by reducing possible sterile loosening through the improvement of the mechanical effects mentioned above. But this may require further experiments for verification.

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Salto TalarisTM全踝关节假体龙骨形状对骨-种植体界面生物力学性能影响的有限元分析

目的：本研究旨在评估改变龙骨型全踝假体胫骨部分龙骨形状对其生物力学行为的影响，并确定进一步选择和改进假体的可能方向。方法：采用有限元方法分析全踝关节假体胫骨龙骨形状对生物力学效应的影响。在Salto TalarisTM踝关节假体胫骨植入物的基础上，利用男性志愿者的CT建立不同假体设计的胫骨模型。生物力学性能包括应力、微动和应变。结果：短龙骨和垂直孔设计的峰值应力和微动分别为85.3 MPa和62.87 μm，分别比原设计降低了36.7%和84.4%。在本设计中，假体周围骨组织中骨融合满意的单元比例达到20.09%，比原设计提高19.1%。结论：通过减少胫骨假体龙骨对下支撑结构的长度，将侧孔重新定位到垂直方向，可以通过改善上述力学效应，减少假体可能发生的无菌性松动，从而提高假体的稳定性。但这可能需要进一步的实验来验证。

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

Journal of Foot & Ankle Surgery ORTHOPEDICS-SURGERY

CiteScore

2.30

自引率

7.70%

发文量

234

审稿时长

29.8 weeks

期刊介绍： The Journal of Foot & Ankle Surgery is the leading source for original, clinically-focused articles on the surgical and medical management of the foot and ankle. Each bi-monthly, peer-reviewed issue addresses relevant topics to the profession, such as: adult reconstruction of the forefoot; adult reconstruction of the hindfoot and ankle; diabetes; medicine/rheumatology; pediatrics; research; sports medicine; trauma; and tumors.