Posterior Ligamentum Complex Preservation Alleviate ASD-Related Biomechanical Deterioration in Lumbar Interbody Fusion Models: A Finite Element Analysis

IF 3.4 3区医学 Q1 ORTHOPEDICS

JOR Spine Pub Date : 2025-01-07 DOI:10.1002/jsp2.70030

Lipeng He, Tingchen Zhu, Weiye Cai, Wenhao Yang, Zan Chen, Jingchi Li

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Abstract

Background

There are differences in the extent of excision of articular processes, spinal processes and posterior ligamentum complexes (PLC) for posterior approach lumbar interbody fusion. Given that the biomechanical significance of these structures has been verified and that deterioration of the biomechanical environment is the main trigger for complications in both fused and adjacent motion segments, changes in decompression ranges may affect the potential risk of adjacent segmental disease (ASD) biomechanically; however, this topic has yet to be identified.

Methods

Posterior lumbar interbody fusion (PLIF) with different decompression strategies was simulated in a well-validated lumbosacral model. The excision and preservation of the cranial motion of the segmental PLC and the lateral articular process in the fusion segment were simulated in this model. The stress distribution in the cranial motion segment was computed under different loading conditions to determine the potential risk of ASD.

Results

Compared to complete bilateral articular process excision, preservation of the lateral two-thirds of the articular process did not alleviate stress concentration on the cranial motion segment both in PLC preserved and excised models. In contrast, preservation of the cranial segmental PLC can obviously alleviate the stress concentration tendency of the cranial intervertebral disc under flexion loading conditions.

Conclusion

Preservation of the lateral parts of the articular process cannot optimize the biomechanical environment, in contrast, PLC preservation can effectively alleviate ASD related biomechanical deterioration of the cranium segment.

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保存后韧带复合体减轻腰椎椎间融合模型中asd相关的生物力学恶化：一项有限元分析。

背景：对于后路腰椎椎体间融合术，关节突、脊柱突和后韧带复合体（PLC）的切除程度存在差异。鉴于这些结构的生物力学意义已被证实，并且生物力学环境的恶化是融合节段和相邻运动节段并发症的主要触发因素，减压范围的变化可能会影响相邻节段疾病（ASD）的生物力学潜在风险；然而，这一主题尚未确定。方法：在经过验证的腰骶模型中模拟不同减压策略的后路腰椎椎体间融合术（PLIF）。在该模型中模拟切除和保留节段PLC的颅骨运动和融合节段的外侧关节突。计算不同载荷条件下颅骨运动节段的应力分布，确定ASD的潜在风险。结果：与完全切除双侧关节突相比，在PLC保留和切除模型中，保留外侧三分之二的关节突并没有减轻颅运动节段的应力集中。相反，保留颅节段PLC可以明显缓解颅椎间盘在屈曲载荷条件下的应力集中倾向。结论：保留关节突外侧部分不能优化生物力学环境，PLC保存可有效缓解ASD相关颅骨节段生物力学恶化。

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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