Finite Element Modeling for Biomechanical Comparisons of Multilevel Transforaminal, Posterior, and Lateral Lumbar Approaches to Interbody Fusion Augmented with Posterior Instrumentation

Finite Element Modeling for Biomechanical Comparisons of Multilevel Transforaminal, Posterior, and Lateral Lumbar Approaches to Interbody Fusion Augmented with Posterior Instrumentation

Verifying the intervertebral stability of each intervertebral fusion procedure, including transforaminal, posterior, and lateral lumbar interbody fusion (TLIF, PLIF, and LLIF, respectively), and the ratio of stress on the rods and pedicle screws during initial fixation may help select a fixation pro...

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Published in:World neurosurgery Vol. 182; pp. e463 - e470
Main Authors: Shimooki, Yutaro, Murakami, Hideki, Nishida, Norihiro, Yan, Hirotaka, Oikawa, Ryo, Hirooki, Endo, Yamabe, Daisuke, Chiba, Yusuke, Sakai, Takashi, Doita, Minoru
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-02-2024
Subjects:
Finite element method
Multi-level lumbar interbody fusion
Posterior instrumentation
ITL
ALL
ISL
Posterior instrumentation
CL
PLF
SSL
FEM
Finite element method
CT
PLL
ROM
ASD
TLIF
IVD
LF
PLIF
VMS
LLIF
Multi-level lumbar interbody fusion
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Summary:Verifying the intervertebral stability of each intervertebral fusion procedure, including transforaminal, posterior, and lateral lumbar interbody fusion (TLIF, PLIF, and LLIF, respectively), and the ratio of stress on the rods and pedicle screws during initial fixation may help select a fixation procedure that reduces the risk of mechanical complications, including rod fracture and screw loosening. Thus, we aimed to assess whether these procedures could prevent mechanical complications. Using the finite element method (FEM), we designed 4 surgical models constructed from L2-5 as follows: posterior lumbar fusion (PLF), TLIF, PLIF, and LLIF models. Bilateral rods and each pedicle screw stress were tracked and calculated as Von Mises stress (VMS) for comparison among the PLF and other 3 interbody fusion models during flexion, extension, and side-bending movements. The lowest rod VMS was LLIF, followed by PLIF, TLIF, and PLF in flexion and side bending movements. Compared with PLF, intervertebral fixation significantly reduced stress on the rods. No remarkable differences were observed in extension movements in each surgical procedure. A tendency for higher pedicle screw VMS was noted at the proximal and distal ends of the fixation ranges, including L2 and L5 screws for each procedure in all motions. Intervertebral fixation significantly reduced stress on the L2 and L5 screws, particularly in LLIF. Stress on the rods and pedicle screws in the LLIF model was the lowest compared with that induced by other intervertebral fusion procedures. Therefore, LLIF may reduce mechanical complications occurrence, including rod fracture and screw loosening.
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ISSN:1878-8750
1878-8769
1878-8769
DOI:10.1016/j.wneu.2023.11.121