Finite element analysis of the Femoral neck system for different placement positions in the fixation of Pauwels type Ⅲ femoral neck fractures

IF 2.2 3区医学 Q3 CRITICAL CARE MEDICINE

Injury-International Journal of the Care of the Injured Pub Date : 2025-02-28 DOI:10.1016/j.injury.2025.112218

YongJia Zhu , Shuai Wu , JiaPeng Yan , Wenhong Wang , Xiao Huang , HongFei Zhang

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引用次数: 0

Abstract

Objective

This study aimed to identify the optimal position for the femoral neck system (FNS) device when fixing Pauwels III #NOF, by analyzing the mechanical stability and stress distribution of FNS at different screw placement positions for the fixation of Pauwels III femoral neck fractures.

Methods

We employed finite element analysis to create a 3D model of a Pauwels type III femoral neck fracture. Six models were designed, each with varied FNS screw placement positions. Axial stresses of 600 N, 1200 N, and 1800 N were applied to simulate physiological loads during different activities: standing on two legs, standing on one leg, and walking. The mechanical properties of these screw placements were assessed by comparing stress distribution, displacement, and fracture stability across models under varying load conditions.

Results

Model 1, with the power rod aligned along the femoral neck axis, showed the best stability, with 42.40 % lower maximum VMS and 18.49 % less femoral displacement, compared to the worst model. Displacement of the internal fixation and fracture surface decreased by 21.72 % and 19.16 %, respectively. It also had superior results for internal fixation VMS and fracture surface compressive stress. Model 2, with the head screw centered axially, demonstrated good stability but had higher stress concentrations under 1800 N load. The displacement of the fracture surface and femur in model 2 increased by 18.37 % and 17.26 %, respectively, compared to model 1. Models 5 and 6, with the FNS nail near the lateral femoral cortex, showed significant stress concentrations, with compressive and shear forces rising by about 33 %. Model 5′s maximum VMS increased by 46.68 %, and model 6′s maximum compressive stress of the fracture surface increased by 46.37 %, compared to model 1. Models 3 and 4, with the power rod shifted up or down, displayed moderate stability, reducing displacement in some tests.

Conclusion

This finite element analysis highlights that centring the FNS power rod along the femoral neck axis significantly enhances fracture stability and minimises postoperative displacement. Conversely, poor screw placement may result in mechanical stress concentration, raising the risk of nonunion or malunion. Clinicians should prioritise screw placements with more excellent mechanical stability to optimise treatment outcomes.

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不同放置位置股骨颈系统固定Pauwels型Ⅲ股骨颈骨折的有限元分析

目的通过分析FNS在不同螺钉放置位置固定Pauwels III型股骨颈骨折时的力学稳定性和应力分布，确定FNS固定Pauwels III #NOF的最佳位置。方法采用有限元方法建立Pauwels III型股骨颈骨折的三维模型。设计了6个模型，每个模型都有不同的FNS螺钉放置位置。分别施加600、1200和1800 N的轴向应力，模拟两腿站立、单腿站立和行走时的生理负荷。通过比较不同载荷条件下不同模型的应力分布、位移和断裂稳定性来评估这些螺钉放置的力学性能。结果与最差模型相比，动力棒沿股骨颈轴排列的模型1稳定性最好，最大VMS降低42.40%，股骨移位减少18.49%。内固定和骨折面位移分别减少21.72%和19.16%。对内固定VMS和骨折面压应力也有较好的效果。模型2在1800 N载荷下稳定性较好，但应力集中较高。与模型1相比，模型2的骨折面和股骨位移分别增加了18.37%和17.26%。模型5和模型6中，FNS钉靠近股外侧皮质，出现了明显的应力集中，压缩和剪切力增加了约33%。与模型1相比，模型5的最大VMS增加了46.68%，模型6的裂缝表面最大压应力增加了46.37%。当动力杆向上或向下移动时，模型3和模型4表现出适度的稳定性，在一些测试中减少了位移。结论本有限元分析强调沿股骨颈轴将FNS动力棒居中可显著提高骨折稳定性并减少术后移位。相反，螺钉放置不良可能导致机械应力集中，增加不愈合或不愈合的风险。临床医生应优先选择机械稳定性更好的螺钉置入，以优化治疗效果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Injury-International Journal of the Care of the Injured 医学-急救医学

CiteScore

4.00

自引率

8.00%

发文量

699

审稿时长

96 days

期刊介绍： Injury was founded in 1969 and is an international journal dealing with all aspects of trauma care and accident surgery. Our primary aim is to facilitate the exchange of ideas, techniques and information among all members of the trauma team.