First School of Clinical Medicine, Guangzhou University of Chinese Medicine, Guangdong, China; Department of Spinal Surgery, The First Affiliated Hospital of Guangzhou University of Chinese Medicine, Guangzhou, China.
Department of Spinal Surgery, The First Affiliated Hospital of Guangzhou University of Chinese Medicine, Guangzhou, China.
World Neurosurg. 2020 Jun;138:e530-e538. doi: 10.1016/j.wneu.2020.02.180. Epub 2020 Mar 7.
Little is known about the biomechanical performance of various fixation constructs after oblique lumbar interbody fusion (OLIF). This study aimed to explore the stability of various fixation options for OLIF by using finite element analysis based on three-dimensional scanning models.
Six validated finite element models of the L3-L5 segment were reconstructed via computed tomography images, including (1) intact model, (2) stand-alone model with no instrument, (3) lateral rod-screw model, (4) lateral rod-screw plus contralateral translaminar facet screw (LRS-CTLFS) model, (5) unilateral pedicle screw model, and (6) bilateral pedicle screw (BPS) model. Models of the OLIF cage and pedicle screw were created with three-dimensional scanning to improve the accuracy of finite element analysis. Range of motion, stress of the cage, and stress of fixation were evaluated in the different models.
Range of motion increased from least to greatest as follows: BPS, LRS-CTLFS, unilateral pedicle screw, lateral rod-screw, stand-alone. Differences in range of motion between BPS and LRS-CTLFS were not significant for all loading cases. Compared with the other 3 models, the stress of the cage was found to be lower in BPS and LRS-CTLFS under all loading conditions, especially in BPS. Stress exerted on the fixation was the greatest in LRS-CTLFS, and the stress experienced by the translaminar facet screw was concentrated in part of the facet joint.
The BPS model provided the best biomechanical stability for OLIF; the stand-alone model could not provide sufficient stability. The LRS-CTLFS procedure increases the approximate stability and reduces stress at the cage-endplate interface; however, it causes an increase in screw stress.
对于腰椎斜外侧融合术(OLIF)后各种固定结构的生物力学性能知之甚少。本研究旨在通过基于三维扫描模型的有限元分析来探讨 OLIF 各种固定选择的稳定性。
通过 CT 图像重建了 L3-L5 节段的六个经过验证的有限元模型,包括(1)完整模型,(2)无器械的独立模型,(3)侧杆螺钉模型,(4)侧杆螺钉加对侧经椎弓根关节突螺钉(LRS-CTLFS)模型,(5)单侧椎弓根螺钉模型和(6)双侧椎弓根螺钉(BPS)模型。使用三维扫描创建 OLIF 笼和椎弓根螺钉模型,以提高有限元分析的准确性。在不同模型中评估运动范围、笼的应力和固定的应力。
运动范围从最小到最大依次增加:BPS、LRS-CTLFS、单侧椎弓根螺钉、侧杆螺钉、独立。在所有加载情况下,BPS 和 LRS-CTLFS 之间的运动范围差异均不显著。与其他 3 种模型相比,在所有加载条件下,BPS 和 LRS-CTLFS 中笼的应力均较低,尤其是在 BPS 中。LRS-CTLFS 中固定的应力最大,经椎弓根关节突螺钉的应力集中在部分关节突关节。
BPS 模型为 OLIF 提供了最佳的生物力学稳定性;独立模型不能提供足够的稳定性。LRS-CTLFS 手术增加了近似稳定性并降低了笼-终板界面的应力;但是,它会导致螺钉应力增加。
