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1. A finite element method study of the effect of vibration on the dynamic biomechanical response of the lumbar spine.

Author

Zhu, Shuai, Dong, RuiChun, Liu, Zhong, Liu, Hong, Lu, ZhuangQi, and Guo, YunQiang

Subjects

*LUMBAR vertebrae physiology, *FINITE element method, *SPINE diseases, *INTERVERTEBRAL disk, *COMPARATIVE studies, *VIBRATION (Mechanics), *LUMBAR vertebrae, *BIOMECHANICS, *BODY mass index, *PSYCHOLOGICAL stress

Abstract

Studies focusing on lumbar spine biomechanics are very limited, and the mechanism of the effect of vibration on lumbar spine biodynamics is unclear. To provide guidance and reference for lumbar spine biodynamics research and vibration safety assessment, this study aims to investigate the effects of different vibrations on lumbar spine biodynamics. A validated finite element model of the lumbosacral spine was utilized. The model incorporated a 40 kg mass on the upper side and a 400 N follower preload. As a comparison, another model without a coupled mass was also employed. A sinusoidal acceleration with an amplitude of 1 m/s2 and a frequency of 5 Hz was applied to the upper and lower sides of the model respectively. When the coupled mass point is not introduced: in the case of upper-side excitation, the lumbar spine shows a significantly larger response in the x-direction than in the z-direction, while in the case of lower-side excitation, the lumbar spine experiences rigid body displacement in the z-direction without any movement, deformation, rotation, or stress changes in the x-direction. When the coupled mass point is introduced: both upper and lower-side excitations result in significant differences in z-directional displacement, with relatively small differences in vertebral rotation angle, disc deformation, and stress. Under upper excitation, low-frequency oscillations occur in the x-direction. In both types of excitations, the anterior-posterior deformation of the L2-L3 and L4-L5 intervertebral discs is greater than the vertical deformation. The peak (maximum) disc stress exceeds the average stress and stress amplitude across the entire disc. Regardless of the excitation type, the stress distribution within the disc at the moment of peak displacement remains nearly identical, with the maximum stress consistently localized on the anterior side of the L4-L5 disc. Accurately simulating lumbar spine biodynamics requires the inclusion of the upper body mass in the lumbosacral spine model. The physiological curvature of the lumbar spine could escalate the risk of lumbar spine vibration injuries. It is more instructive to apply local high stress in the disc as a lumbar spine vibration safety evaluation parameter. • A three-dimensional finite element model of the lumbosacral spine was developed and validated. • The dynamic response characteristics of the lumbar spine under different excitations were studied. • Human upper body mass has a significant impact on lumbar spine biodynamics. • Physiological bending of lumbar spine leads to complex alternating deformations under vibration. • Apply local high stress as a lumbar spine vibration safety evaluation parameter is more instructive. [ABSTRACT FROM AUTHOR]

Published

2024