Sensitivity of Lumbar Total Joint Replacement to Axial and Coronal Plane Misalignment Using Computational Modeling.

IF 1.7 Q2 SURGERY

International Journal of Spine Surgery Pub Date : 2025-10-02 DOI:10.14444/8792

Steven A Rundell, Steven M Kurtz, Hannah Spece, Jeffrey A Goldstein, Scott D Hodges, Ron V Yarbrough

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引用次数: 0

Abstract

Background: During lumbar total joint replacement (LTJR), component misalignment during implantation may affect the bearing surface interaction. In this study, validated computational models of the lumbar spine were used to investigate a range of clinically relevant misalignment scenarios.

Methods: A finite element model (FEM) of the LTJR, exposed to mode I (normal wear) and mode IV (impingement) wear boundary conditions, was previously validated following the ASME V&V 40 standard. The LTJR FEM was virtually implanted into a previously validated FEM of the lumbar spine (L3-L5) at L4 to L5. The model included vertebrae, major spinal ligaments, erector muscle forces, and intervertebral discs. Misalignment was introduced by adjusting the bilateral implant axial plane convergence angle (20°-40°), anterior-posterior offset (0-4 mm), and coronal plane tilt (±20°). Analyses were conducted using LS-DYNA3D (ANSYS) under boundary conditions simulating bending at the waist. Contact pressures and von Mises stresses were evaluated for each misalignment scenario and compared with those developed during mode I and mode IV impingement scenarios.

Results: Axial plane convergence angle had minimal impact on contact stress and von Mises stress magnitude and distribution. Increasing anterior-posterior offset led to higher stresses on the anteriorly shifted component but did not significantly alter the overall stress pattern. Coronal tilt had the most substantial effect on both stress magnitude and distribution.

Conclusion: Overall, polyethylene stresses in all misalignment scenarios remained below mode IV impingement levels. Contact areas remained within the intended spherical bearing surfaces without signs of impingement. LTJR contact stresses were found to be reasonably insensitive to misalignment under boundary conditions representing bending at the waist.

Clinical relevance: This work assesses the impact of clinically relevant implant misalignment scenarios on the polyethylene stresses associated with damage and wear for a novel LTJR and offers best practice guidelines for surgeons.

Level of evidence: 5:

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腰椎全关节置换术对轴位和冠状面错位的敏感性。

背景：在腰椎全关节置换术（LTJR）中，植入过程中的构件错位可能会影响承载面相互作用。在这项研究中，验证的腰椎计算模型被用于研究一系列临床相关的错位情况。方法：采用I型（正常磨损）和IV型（撞击）磨损边界条件下的LTJR有限元模型，按照ASME v&v40标准进行验证。LTJR FEM在L4至L5位置植入先前验证的腰椎FEM （L3-L5）。该模型包括椎骨、主要脊柱韧带、竖肌力量和椎间盘。通过调整双侧种植体轴向面会聚角（20°-40°）、前后偏移（0-4 mm）和冠状面倾斜（±20°）来引入错位。采用LS-DYNA3D （ANSYS）软件在模拟腰部弯曲的边界条件下进行了分析。我们评估了每一种不对中情况下的接触压力和von Mises应力，并与I型和IV型碰撞情况下的接触压力和von Mises应力进行了比较。结果：轴向平面收敛角对接触应力和von Mises应力的大小和分布影响最小。增加前后偏移量会导致前移位部位的应力增加，但不会显著改变整体应力模式。日冕倾斜对应力大小和应力分布的影响最为显著。结论：总体而言，所有不对准情况下的聚乙烯应力保持在IV型撞击水平以下。接触区域保持在预定的球面轴承表面内，没有碰撞的迹象。在边界条件下，LTJR接触应力对代表腰部弯曲的偏差不敏感。临床相关性：本研究评估了临床相关的种植体错位对新型LTJR损伤和磨损相关聚乙烯应力的影响，并为外科医生提供了最佳实践指南。证据等级：5；

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

International Journal of Spine Surgery Medicine-Surgery

CiteScore

3.10

自引率

0.00%

发文量

162

期刊介绍： The International Journal of Spine Surgery is the official scientific journal of ISASS, the International Intradiscal Therapy Society, the Pittsburgh Spine Summit, and the Büttner-Janz Spinefoundation, and is an official partner of the Southern Neurosurgical Society. The goal of the International Journal of Spine Surgery is to promote and disseminate online the most up-to-date scientific and clinical research into innovations in motion preservation and new spinal surgery technology, including basic science, biologics, and tissue engineering. The Journal is dedicated to educating spine surgeons worldwide by reporting on the scientific basis, indications, surgical techniques, complications, outcomes, and follow-up data for promising spinal procedures.