Effect of vehicular vibrations on L-4 lumbar vertebrae – A finite element study

IF 1.5 Q3 ORTHOPEDICS

Journal of orthopaedics Pub Date : 2024-11-01 DOI:10.1016/j.jor.2024.10.056

Y.S. Kishore , B.M. Sreedhara , A. Manoj , R.M. Raveesh , B. Rakesh , S. Bhaskar , Geetha Kuntoji , B.A. Chethan

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Abstract

Lower Back Pain (LBP) is a global health issue, with increasing prevalence, partly attributed to vehicular vibrations experienced by motorcyclists. The L4 lumbar vertebra is responsible for greater mobility and flexibility of the body, but also is the most crucial body element affected by vehicular vibrations. Anthropometric properties, types of speed humps, and vehicle types are the critical variables that impact bone health during riding, need to be studied. To understand the potential zones of injury, computational simulation can be performed under the influence of vehicle vibrations while crossing different types of speed humps at varying speeds. In the present study, finite element method (FEM) is used to evaluate stress and deformation in the bone. The L4 cortical bone is modelled by considering the CT-Scan data and assumed to be homogeneous and isotropic material. Vibration data is collected using two vehicle types (Type I and Type II) on four different humps (Trapezoidal, Bitumen Semi-circular, Rubber Semi-circular, and Rumble strip). The bone's dynamic behavior is studied using FEM simulation, which involved static structural, modal and transient dynamic analyses. The findings from static analysis indicate that the most concentrated stress is located in the lower pedicle region and is an expected commonplace for injuries because of vibrations. In transient dynamic analysis, Type I vehicle showed a 25 % higher stress than Type II.

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车辆振动对 L-4 腰椎的影响 - 有限元研究

下背痛（LBP）是一个全球性的健康问题，发病率越来越高，部分原因是摩托车驾驶员所经历的车辆振动。L4腰椎负责身体更大的活动性和灵活性，但也是受车辆振动影响最严重的身体部位。人体测量特性、减速带类型和车辆类型是骑行过程中影响骨骼健康的关键变量，需要加以研究。为了了解潜在的受伤区域，可以在不同速度穿越不同类型减速带时，在车辆振动的影响下进行计算模拟。本研究采用有限元法（FEM）评估骨骼的应力和变形。考虑到 CT 扫描数据，对 L4 皮质骨进行建模，并假定其为均质和各向同性材料。在四种不同的驼峰（梯形、沥青半圆形、橡胶半圆形和隆起条）上使用两种车辆类型（I 型和 II 型）收集振动数据。使用有限元模拟对骨的动态行为进行了研究，包括静态结构、模态和瞬态动态分析。静态分析结果表明，应力最集中的部位是下椎弓根区域，这也是由于振动造成损伤的常见原因。在瞬态动态分析中，I 型车辆的应力比 II 型车辆高 25%。

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

Journal of orthopaedics ORTHOPEDICS-

CiteScore

3.50

自引率

6.70%

发文量

202

审稿时长

56 days

期刊介绍： Journal of Orthopaedics aims to be a leading journal in orthopaedics and contribute towards the improvement of quality of orthopedic health care. The journal publishes original research work and review articles related to different aspects of orthopaedics including Arthroplasty, Arthroscopy, Sports Medicine, Trauma, Spine and Spinal deformities, Pediatric orthopaedics, limb reconstruction procedures, hand surgery, and orthopaedic oncology. It also publishes articles on continuing education, health-related information, case reports and letters to the editor. It is requested to note that the journal has an international readership and all submissions should be aimed at specifying something about the setting in which the work was conducted. Authors must also provide any specific reasons for the research and also provide an elaborate description of the results.