Biomechanical Stability of Oblique Lumbar Interbody Fusion Combined With Lateral Plate Fixation Under Different Bone Conditions:a Finite Element Study
10.3969/j.issn.1009-6604.2025.09.009
- VernacularTitle:不同骨质条件下斜外侧椎间融合术联合侧方钢板固定的生物力学稳定性的有限元研究
- Author:
Zhiqiang WANG
1
;
Xin PENG
1
;
Yuanbo WANG
1
;
Chongyu WANG
1
;
Guang YANG
1
;
Hongqiang WANG
1
;
Yanzheng GAO
1
Author Information
1. 河南省人民医院 郑州大学人民医院脊柱脊髓外科,郑州 450003
- Publication Type:Journal Article
- Keywords:
Lumbar fusion;
Oblique lumbar interbody fusion;
Internal fixation;
Finite element
- From:
Chinese Journal of Minimally Invasive Surgery
2025;25(9):557-565
- CountryChina
- Language:Chinese
-
Abstract:
Objective To clarify the biomechanical properties of oblique lumbar interbody fusion(OLIF)combined with lateral plate(LP)fixation under different bone conditions by means of finite element(FE)analysis,so as to provide mechanical basis for clinical practice.Methods The three-dimensional nonlinear L3_5 FE model of the spine was constructed.Different material properties were assigned to each part of the model to establish a model of normal bone(NB),osteopenia(OS)and osteoporosis(OP)of the lumbar spine.OLIF combined with the following three internal fixation models were established.For NB,there were OLIF alone(M0),OLIF+LP fixation(M1),and OLIF+bilateral pedicle screw(BPS)fixation(M2);for OS,there were OLIF alone(N0),OLIF+LP fixation(N1),and OLIF+BPS fixation(N2);for OP,there were OLIF alone(P0),OLIF+LP fixation(P1),and OLIF+BPS fixation(P2).A 500 N load was applied on the upper surface of L3 to represent the weight of the upper body,and a 7.5 N·m moment was used to simulate the vertebral motion under six different conditions:flexion(FL),extension(EX),left bending(LB),right bending(RB),left rotation(LR)and right rotation(RR).The range of motion(ROM)of the fixed segment of NB,OS and OP models was calculated,and the overall stress of the vertebral body,the stress of the cage and the internal fixation device were recorded.Results Compared with the complete model,the stability of each surgical model increased.Compared with M0,ROM of M1 decreased,especially in the LB and RB,which was roughly equivalent to the stability of BPS but weaker than BPS in the control FL and EX direction.The situation in OS and OP model was similar to that in NB.Under the same internal fixation,L4_5 ROM gradually increased with bone deterioration.The overall intervertebral ROM of N1 in the FL direction increased by 16.1%compared with M1,P1 in the FL direction increased by 32.1%compared with M1,and P1 in the FL direction increased by 19.0%compared with N1.With the increase of posterior internal fixation,the overall stress of vertebral body,Cage and internal fixation stress showed a downward trend.Under the same internal fixation,with the loss of bone mass,the overall stress of the model gradually increased.Compared with M0,P0 increased the most in LR,reaching 56.5%.In the NB and OS models,the peak stress of the LP fixation under FL exceeded the minimum yield strength of the material by 22.7%and 33.8%,respectively,and was less than the minimum fatigue strength and yield strength of the material under the rest of the motion.In the OP,the peak stress of the internal fixation exceeded the minimum fatigue strength of the material at FL and EX,and reached 53.3%(>50%)at FL.Conclusions Under NB and OS,OLIF combined with LP fixation can significantly improve the stability of the surgical segment,especially in LB and RB directions,and the overall stability is weaker than that of BPS fixation.Under OP,FL and EX may increase the risk of internal fixation failure.Combination with BPS fixation should be considered to improve the safety of fixation.
