[用于椎管重建的修复性椎板成形术中微型钢板固定系统的生物力学分析]
[Biomechanical analysis of miniplate fixation systems in restorative laminoplasty for spinal canal reconstruction].
作者信息
Chen J, Liu G, Bao T, Bai T, Zhang E, Zhao J
机构信息
Department of Orthopedics, Jinling Hospital of Nanjing Medical University, Nanjing 210002, China.
Xiamen Medical Device Testing and Research Co., Ltd, Xiamen 361022, China.
出版信息
Nan Fang Yi Ke Da Xue Xue Bao. 2023 Mar 20;43(3):331-339. doi: 10.12122/j.issn.1673-4254.2023.03.01.
OBJECTIVE
To investigate the biomechanical properties of H-shaped and L-shaped miniplate fixation systems (H-MFS and L-MFS, respectively) in restorative laminoplasty for spinal canal reconstruction (RL-SCR).
METHODS
Laminectomy was performed in a 3D printed L4 vertebral model followed by RL-SCR using H-MFS or L-MFS, and the biomechanical properties of the reconstructed models were evaluated using static and dynamic compression tests. Biomechanical analyses of RL-SCR were also conducted in finite element models of the L3-L5 vertebrae with normal assignment (NA), laminectomy, or fixation with H-MFS or L-MFS, and the range of motion (ROM) of L3-L4 and L4-L5 was evaluated.
RESULTS
In static compression test, the sustained yield load, compression stiffness, yield displacement and axial displacement- axial load were all significantly greater in H-MFS group ( < 0.05). Door closing, lamina collapse and plate breakage occurred in all the models in L-MFS group, and only some models in H-MFS group showed plate cracks and screw loosening. In dynamic compression tests, the peak load in H-MFS group reached 873 N (which was 95% of the average yield load in static compression), significantly greater than that in L-MFS group ( < 0.05). The ultimate load in L-MFS group was only 46.59% of that in H-MFS group (>0.05). In finite element analysis, the ROM of the L3-L4 and L4- L5 segments were significantly smaller in NA, H-MFS and L-MFS groups than in laminectomy group. Compared with NA group, H-MFS group showed a greater ROM during extension, and L-MFS group showed greater ROM in flexion, extension, bending, and rotation; The overall ROM of the vertebral segments decreased in the order of laminectomy group, L-MFS group, H-MFS group, and NA group.
CONCLUSION
Laminectomy causes structural destruction of the posterior column of the spine to affect its biomechanical stability. RL-SCR can effectively maintain the biomechanical stability of the spine, and H-MFS is superior to L-MFS in maintaining the integrity and biomechanical properties of the reconstructed spinal canal.
目的
探讨H形和L形微型钢板固定系统(分别为H-MFS和L-MFS)在椎管重建的恢复性椎板成形术(RL-SCR)中的生物力学特性。
方法
在3D打印的L4椎体模型上进行椎板切除术,然后使用H-MFS或L-MFS进行RL-SCR,并通过静态和动态压缩试验评估重建模型的生物力学特性。还在L3-L5椎体的有限元模型中进行了RL-SCR的生物力学分析,这些模型具有正常赋值(NA)、椎板切除术或用H-MFS或L-MFS固定,并评估了L3-L4和L4-L5的活动范围(ROM)。
结果
在静态压缩试验中,H-MFS组的持续屈服载荷、压缩刚度、屈服位移和轴向位移-轴向载荷均显著更大(<0.05)。L-MFS组的所有模型均出现关门、椎板塌陷和钢板断裂,而H-MFS组只有部分模型出现钢板裂纹和螺钉松动。在动态压缩试验中,H-MFS组的峰值载荷达到873 N(为静态压缩平均屈服载荷的95%),显著大于L-MFS组(<0.05)。L-MFS组的极限载荷仅为H-MFS组的46.59%(>0.05)。在有限元分析中,NA、H-MFS和L-MFS组中L3-L4和L4-L5节段的ROM显著小于椎板切除组。与NA组相比,H-MFS组在伸展时的ROM更大,而L-MFS组在屈曲、伸展、侧弯和旋转时的ROM更大;椎体节段的总体ROM按椎板切除组、L-MFS组、H-MFS组和NA组的顺序降低。
结论
椎板切除术会导致脊柱后柱结构破坏,影响其生物力学稳定性。RL-SCR可有效维持脊柱的生物力学稳定性,且H-MFS在维持重建椎管的完整性和生物力学特性方面优于L-MFS。
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