Zhang Teng, Ren Xiaodan, Feng Xiaoren, Diwan Ashish, Luk Keith Dip Kei, Lu William Weijia, Wong Tak-Man, Li Chentian, Cheung Jason Pui Yin
Department of Orthopaedics and Traumatology, Li Ka Shing Faculty of Medicine, The University of Hong Kong, Hong Kong.
Department of Civil Engineering, Faculty of Engineering, Tongji University, Shanghai, China.
J Mech Behav Biomed Mater. 2020 Apr;104:103646. doi: 10.1016/j.jmbbm.2020.103646. Epub 2020 Jan 18.
Cadaveric biomechanical with imaging analysis.
This study aims to compare the fixation failure between pedicel screws (PS) and cortical screws (CS), thus to investigate their failure mechanisms under vertical migration.
Due to their minimal invasive nature, CS are gaining popularity. However, contradictions exist in the literature regarding whether CS may have superior fixation failure resistance compared to PS under vertical migration.
Human vertebral specimens were examined under Dual-energy X-ray. For each specimen, PS were inserted on the left and CS on the right with rods secured. Vertical force-displacement tests were applied to rods. MicroCT images were taken pre and post-MTS® for microstructural analysis.
The average T-scores of the specimens were -4±0.25. Three phases of force-displacement behaviour featuring different PS and CS failure-resistance were discovered. For phase I, the force required to migrate PS tended to be slightly higher than CS. However, during phase II, a fixation instability occurred for PS and the CS fixation strength was superior. For phase III under large displacement, CS did not require increased force to displace, whereas PS re-stabilised and revealed improved displacement resistance. Both force analysis and microstructural analysis indicated that PS migrated along the direction of the vertical loading, whereas CS had a force component in the longitudinal axis of the screw.
Different failure mechanisms underlay PS and CS under large vertical displacement. PS fail with trabecular bone compaction possibly altering the initial material property surround the screw. CS fail with screw cut-out due to the force component along the screw axis.
尸体生物力学与影像学分析。
本研究旨在比较椎弓根螺钉(PS)和皮质骨螺钉(CS)的固定失败情况,从而研究它们在垂直移位下的失败机制。
由于其微创性,皮质骨螺钉越来越受欢迎。然而,关于在垂直移位情况下皮质骨螺钉与椎弓根螺钉相比是否具有更好的抗固定失败能力,文献中存在矛盾观点。
在双能X射线下检查人体椎体标本。对每个标本,在左侧插入椎弓根螺钉,右侧插入皮质骨螺钉并固定棒材。对棒材施加垂直力-位移测试。在MTS测试前后拍摄MicroCT图像用于微观结构分析。
标本的平均T值为-4±0.25。发现了力-位移行为的三个阶段,其特征为不同的椎弓根螺钉和皮质骨螺钉抗失败能力。在第一阶段,使椎弓根螺钉移位所需的力往往略高于皮质骨螺钉。然而,在第二阶段,椎弓根螺钉出现固定不稳定,而皮质骨螺钉的固定强度更高。在第三阶段大位移情况下,皮质骨螺钉移位不需要增加力,而椎弓根螺钉重新稳定并显示出更好的抗位移能力。力分析和微观结构分析均表明,椎弓根螺钉沿垂直加载方向移位,而皮质骨螺钉在螺钉纵轴上有一个力分量。
在大垂直位移下,椎弓根螺钉和皮质骨螺钉有不同的失败机制。椎弓根螺钉因松质骨压实而失败,这可能改变了螺钉周围的初始材料特性。皮质骨螺钉因沿螺钉轴的力分量导致螺钉穿出而失败。
