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颈椎前路椎间盘切除融合术中不同形态颈椎椎间融合器的生物力学评估:有限元分析

Biomechanical Evaluation of Cervical Interbody Fusion Cages for Anterior Cervical Discectomy and Fusion With Variations in Morphology: A Finite Element Analysis.

作者信息

Manickam Pechimuthu Susai, Dhason Raja, Bock Ryan, Bal Sonny, Roy Sandipan, Datta Shubhabrata

机构信息

Centre for Biomechanics, Department of Mechanical Engineering, College of Engineering and Technology, SRM Institute of Science and Technology, Kattankulathur, Tamil Nadu, India.

Centre for Composites and Advanced Materials, Department of Mechanical Engineering, College of Engineering and Technology, SRM Institute of Science and Technology, Kattankulathur, Tamil Nadu, India.

出版信息

Biomed Eng Comput Biol. 2025 Mar 17;16:11795972251321307. doi: 10.1177/11795972251321307. eCollection 2025.

DOI:10.1177/11795972251321307
PMID:40104840
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11915299/
Abstract

The spinal diseases commonly faced by people in the 19th century included intervertebral disc degeneration, tuberculosis and congenital defects that resulted in neurological impairment and global disability. To address these issues, cervical spine surgery was performed. Modern techniques currently used in spine surgery include interbody devices, pedicle screws, artificial discs and bone grafts. The postoperative complications clinically reported during follow-up include nonunion and implant subsidence, which remain significant drawbacks. The objective of this study is to develop a 3-dimensional finite element model of the C2-C7 cervical spine and validate it against existing experimental studies. The loading conditions considered for this study include a compressive preload of 50 N and a 1 Nm moment applied to the C2 vertebra, with the C7 vertebra fixed at the bottom. In this study, the biomechanical alterations of 4 different cage morphologies were analysed using finite element analysis. Valeo cages with 4 distinct designs were implanted at the C5-C6 level, and physiological motion at the surgical site was studied. Cage subsidence and migration, which can lead to adjacent segment disc degeneration, were also examined. Subsidence was primarily attributed to higher stress encountered in the cage, so stress distribution within the cages was evaluated. Additionally, stress distribution in the anterior plate and screws was analysed. The study concludes that introducing anterior plate and screw fixation helps prevent cage subsidence. Physiological motion at the surgical level was reduced compared to the intact model. Adjacent disc stress was also evaluated and found to be lower than in the intact model.

摘要

19世纪人们常见的脊柱疾病包括椎间盘退变、结核病以及导致神经功能障碍和全身残疾的先天性缺陷。为解决这些问题,人们进行了颈椎手术。目前脊柱手术中使用的现代技术包括椎间融合器、椎弓根螺钉、人工椎间盘和骨移植。随访期间临床报告的术后并发症包括骨不连和植入物下沉,这些仍然是严重的缺点。本研究的目的是建立一个C2 - C7颈椎的三维有限元模型,并根据现有的实验研究对其进行验证。本研究考虑的加载条件包括对C2椎体施加50 N的压缩预载荷和1 Nm的力矩,C7椎体在底部固定。在本研究中,使用有限元分析来分析4种不同椎间融合器形态的生物力学改变。将4种不同设计的法雷奥椎间融合器植入C5 - C6节段,并研究手术部位的生理运动。还检查了可能导致相邻节段椎间盘退变的椎间融合器下沉和移位情况。下沉主要归因于椎间融合器中遇到的较高应力,因此评估了椎间融合器内的应力分布。此外,还分析了前路钢板和螺钉中的应力分布。研究得出结论,引入前路钢板和螺钉固定有助于防止椎间融合器下沉。与完整模型相比,手术节段的生理运动减少。还评估了相邻椎间盘的应力,发现其低于完整模型。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a91e/11915299/3b0f8ce7120a/10.1177_11795972251321307-fig10.jpg
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