Biomechanical Study of Symmetric Bending and Lifting Behavior in Weightlifter with Lumbar L4-L5 Disc Herniation and Physiological Straightening Using Finite Element Simulation.

IF 3.8 3区医学 Q2 ENGINEERING, BIOMEDICAL

Bioengineering Pub Date : 2024-08-12 DOI:10.3390/bioengineering11080825

Caiting Zhang, Yang Song, Qiaolin Zhang, Ee-Chon Teo, Wei Liu

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引用次数: 0

Abstract

Background: Physiological curvature changes of the lumbar spine and disc herniation can cause abnormal biomechanical responses of the lumbar spine. Finite element (FE) studies on special weightlifter models are limited, yet understanding stress in damaged lumbar spines is crucial for preventing and rehabilitating lumbar diseases. This study analyzes the biomechanical responses of a weightlifter with lumbar straightening and L4-L5 disc herniation during symmetric bending and lifting to optimize training and rehabilitation.

Methods: Based on the weightlifter's computed tomography (CT) data, an FE lumbar spine model (L1-L5) was established. The model included normal intervertebral discs (IVDs), vertebral endplates, ligaments, and a degenerated L4-L5 disc. The bending angle was set to 45°, and weights of 15 kg, 20 kg, and 25 kg were used. The flexion moment for lifting these weights was theoretically calculated. The model was tilted at 45° in Abaqus 2021 (Dassault Systèmes Simulia Corp., Johnston, RI, USA), with L5 constrained in all six degrees of freedom. A vertical load equivalent to the weightlifter's body mass and the calculated flexion moments were applied to L1 to simulate the weightlifter's bending and lifting behavior. Biomechanical responses within the lumbar spine were then analyzed.

Results: The displacement and range of motion (ROM) of the lumbar spine were similar under all three loading conditions. The flexion degree increased with the load, while extension remained unchanged. Right-side movement and bending showed minimal change, with slightly more right rotation. Stress distribution trends were similar across loads, primarily concentrated in the vertebral body, increasing with load. Maximum stress occurred at the anterior inferior margin of L5, with significant stress at the posterior joints, ligaments, and spinous processes. The posterior L5 and margins of L1 and L5 experienced high stress. The degenerated L4-L5 IVD showed stress concentration on its edges, with significant stress also on L3-L4 IVD. Stress distribution in the lumbar spine was uneven.

Conclusions: Our findings highlight the impact on spinal biomechanics and suggest reducing anisotropic loading and being cautious of loaded flexion positions affecting posterior joints, IVDs, and vertebrae. This study offers valuable insights for the rehabilitation and treatment of similar patients.

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利用有限元模拟对腰椎 4-L5 椎间盘突出症和生理伸直的举重运动员的对称弯曲和举重行为进行生物力学研究。

背景：腰椎的生理弯曲变化和椎间盘突出会导致腰椎的生物力学反应异常。针对特殊举重运动员模型的有限元（FE）研究非常有限，但了解受损腰椎的应力对于预防和康复腰椎疾病至关重要。本研究分析了腰椎变直和 L4-L5 椎间盘突出的举重运动员在对称弯曲和举重过程中的生物力学反应，以优化训练和康复：方法：根据举重运动员的计算机断层扫描（CT）数据，建立了一个腰椎（L1-L5）FE模型。该模型包括正常的椎间盘（IVD）、椎体终板、韧带和退化的 L4-L5 椎间盘。弯曲角度设定为 45°，重量分别为 15 千克、20 千克和 25 千克。举起这些重物的屈曲力矩是通过理论计算得出的。模型在 Abaqus 2021（Dassault Systèmes Simulia Corp., Johnston, RI, USA）中倾斜 45°，L5 在所有六个自由度上都受到约束。在 L1 上施加了相当于举重运动员体重的垂直负载和计算得出的屈曲力矩，以模拟举重运动员的弯曲和举重行为。然后对腰椎的生物力学反应进行分析：结果：在三种负载条件下，腰椎的位移和运动范围（ROM）相似。屈曲度随着负荷的增加而增加，而伸展度保持不变。右侧移动和弯曲的变化极小，右旋略有增加。各种负荷下的应力分布趋势相似，主要集中在椎体，并随着负荷的增加而增加。最大应力出现在 L5 椎体的前下缘，后关节、韧带和棘突也有很大应力。L5 后部以及 L1 和 L5 的边缘承受着较大的应力。变性的 L4-L5 IVD 显示应力集中在其边缘，L3-L4 IVD 也有很大的应力。腰椎的应力分布不均匀：我们的研究结果凸显了对脊柱生物力学的影响，并建议减少各向异性负荷，谨慎对待影响后关节、IVD 和椎体的负荷屈曲位置。这项研究为类似患者的康复和治疗提供了宝贵的见解。

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

Bioengineering Chemical Engineering-Bioengineering

CiteScore

4.00

自引率

8.70%

发文量

661

期刊介绍： Aims Bioengineering (ISSN 2306-5354) provides an advanced forum for the science and technology of bioengineering. It publishes original research papers, comprehensive reviews, communications and case reports. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. All aspects of bioengineering are welcomed from theoretical concepts to education and applications. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. There are, in addition, four key features of this Journal: ● We are introducing a new concept in scientific and technical publications “The Translational Case Report in Bioengineering”. It is a descriptive explanatory analysis of a transformative or translational event. Understanding that the goal of bioengineering scholarship is to advance towards a transformative or clinical solution to an identified transformative/clinical need, the translational case report is used to explore causation in order to find underlying principles that may guide other similar transformative/translational undertakings. ● Manuscripts regarding research proposals and research ideas will be particularly welcomed. ● Electronic files and software regarding the full details of the calculation and experimental procedure, if unable to be published in a normal way, can be deposited as supplementary material. ● We also accept manuscripts communicating to a broader audience with regard to research projects financed with public funds. Scope ● Bionics and biological cybernetics: implantology; bio–abio interfaces ● Bioelectronics: wearable electronics; implantable electronics; “more than Moore” electronics; bioelectronics devices ● Bioprocess and biosystems engineering and applications: bioprocess design; biocatalysis; bioseparation and bioreactors; bioinformatics; bioenergy; etc. ● Biomolecular, cellular and tissue engineering and applications: tissue engineering; chromosome engineering; embryo engineering; cellular, molecular and synthetic biology; metabolic engineering; bio-nanotechnology; micro/nano technologies; genetic engineering; transgenic technology ● Biomedical engineering and applications: biomechatronics; biomedical electronics; biomechanics; biomaterials; biomimetics; biomedical diagnostics; biomedical therapy; biomedical devices; sensors and circuits; biomedical imaging and medical information systems; implants and regenerative medicine; neurotechnology; clinical engineering; rehabilitation engineering ● Biochemical engineering and applications: metabolic pathway engineering; modeling and simulation ● Translational bioengineering