Quantitative Biomechanical Evaluation for Optimal Spinal Instrumentation to Prevent Mechanical Complications in Spinal Fusion from the Lower Thoracic Spine to the Pelvis for Adult Spinal Deformity: A Finite Element Analysis.

IF 1.2 Q3 SURGERY
Takuhei Kozaki, Shunji Tsutsui, Ei Yamamoto, Akimasa Murata, Ryuichiro Nakanishi, Hiroshi Yamada
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Abstract

Introduction: Mechanical complications, such as rod fracture (RF) and proximal junctional kyphosis (PJK), commonly occur after adult spinal deformity (ASD) surgery. A rigid construct is preferred to prevent RF, whereas it is a risk factor for PJK. This controversial issue urged us to conduct a biomechanical study for seeking the optimal construct to prevent mechanical complications.

Methods: A three-dimensional nonlinear finite element model, which consisted of the lower thoracic and lumbar spine, pelvis, and femur, was created. The model was instrumented with pedicle screws (PSs), S2-alar-iliac screws, lumbar interbody fusion cages, and rods. Rod stress was measured when a forward-bending load was applied at the top of the construct to evaluate the risk of RF in constructs with or without accessory rods (ARs). In addition, fracture analysis around the uppermost instrumented vertebra (UIV) was performed to assess the risk of PJK.

Results: Changing the rod material from titanium alloy (Ti) to cobalt chrome (CoCr) decreased shearing stress at L5-S1 by 11.5%, and adding ARs decreased it by up to 34.3% (for the shortest ARs). Although the trajectory (straightforward vs. anatomical) of PSs did not affect the fracture load for UIV+1, changing the anchor from PSs to hooks at the UIV reduced it by 14.8%. Changing the rod material from Ti to CoCr did not alter the load, whereas the load decreased by up to 25.1% as the AR became longer.

Conclusions: The PSs at the UIV in the lower thoracic spine, CoCr rods as primary rods, and shorter ARs should be used in long fusion for ASD to prevent mechanical complications.

最佳脊柱内固定的定量生物力学评估,以防止成人脊柱畸形从下胸椎到骨盆脊柱融合的机械并发症:一项有限元分析。
成人脊柱畸形(ASD)手术后常见机械并发症,如棒骨折(RF)和近端关节后凸(PJK)。刚性结构是首选的预防射频,而它是PJK的一个危险因素。这个有争议的问题促使我们进行生物力学研究,以寻求最佳的结构,以防止机械并发症。方法:建立由下胸腰椎、骨盆、股骨组成的三维非线性有限元模型。采用椎弓根螺钉(PSs)、s2 -翼髂螺钉、腰椎椎体间融合器和棒固定模型。当在假体顶部施加正向弯曲载荷时,测量假体的应力,以评估有或没有辅助棒(ARs)的假体发生射频的风险。此外,对最上固定椎体(UIV)周围的骨折进行分析,以评估PJK的风险。结果:将棒材材料由钛合金(Ti)改为钴铬(CoCr)可使L5-S1处的剪应力降低11.5%,添加ARs可使L5-S1处的剪应力降低34.3%(最短ARs)。虽然PSs的轨迹(直接或解剖)不影响UIV+1的骨折负荷,但在UIV将锚从PSs改为挂钩可减少14.8%的骨折负荷。将杆材从Ti改为CoCr并没有改变负载,而随着AR变长,负载降低了25.1%。结论:在ASD的长时间融合中,应采用胸椎下段ivv处的PSs, CoCr棒作为初级棒,以及较短的ar,以防止机械并发症的发生。
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
CiteScore
1.80
自引率
0.00%
发文量
71
审稿时长
15 weeks
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