Abstract
BackgroundAdjacent segment disease (ASD) is a well-known complication after interbody fusion. Pedicle screw-rod revision possesses sufficient strength and rigidity. However, is a surgical segment with rigid fixation necessary for ASD reoperation? This study aimed to investigate the biomechanical effect of different instrumentation on lateral lumbar interbody fusion (LLIF) for ASD treatment.MethodsA validated L2~5 finite element (FE) model was modified for simulation. ASD was considered the level cranial to the upper-instrumented segment (L3/4). Bone graft fusion in LLIF with bilateral pedicle screw (BPS) fixation occurred at L4/5. The ASD segment for each group underwent a) LLIF + posterior extension of BPS, b) PLIF + posterior extension of BPS, c) LLIF + lateral screw, and d) stand-alone LLIF. The L3/4 range of motion (ROM), interbody cage stress and strain, screw-bone interface stress, cage-endplate interface stress, and L2/3 nucleus pulposus of intradiscal pressure (NP-IDP) analysis were calculated for comparisons among the four models.ResultsAll reconstructive models displayed decreased motion at L3/4. Under each loading condition, the difference was not significant between models a and b, which provided the maximum ROM reduction (73.8 to 97.7% and 68.3 to 98.4%, respectively). Model c also provided a significant ROM reduction (64.9 to 77.5%). Model d provided a minimal restriction of the ROM (18.3 to 90.1%), which exceeded that of model a by 13.1 times for flexion-extension, 10.3 times for lateral bending and 4.8 times for rotation. Model b generated greater cage stress than other models, particularly for flexion. The maximum displacement of the cage and the peak stress of the cage-endplate interface were found to be the highest in model d under all loading conditions. For the screw-bone interface, the stress was much greater with lateral instrumentation than with posterior instrumentation.ConclusionsStand-alone LLIF is likely to have limited stability, particularly for lateral bending and axial rotation. Posterior extension of BPS can provide reliable stability and excellent protective effects on instrumentation and endplates. However, LLIF with the use of an in situ screw may be an alternative for ASD reoperation.
Highlights
Adjacent segment disease (ASD) is a well-known complication after interbody fusion
The maximum range of motion (ROM) occurred at L4– 5, and the maximum ROM for extension and bending was observed at L3–4 and L4-L5, respectively
The ROM discrepancy was within the acceptable range of error
Summary
Adjacent segment disease (ASD) is a well-known complication after interbody fusion. This study aimed to investigate the biomechanical effect of different instrumentation on lateral lumbar interbody fusion (LLIF) for ASD treatment. Interbody fusion surgery for unstable spinal segments involved in LDD is currently the gold-standard operative treatment. As pedicle screw-rod instrumentation becomes more widespread, spine surgeons are inevitably faced with a growing number of patients presenting with symptomatic adjacent segment degeneration (ASD) [2,3,4,5]. In 2014, Kyaw et al utilized 10 cadaveric boar spines at the L2–L5 levels and evaluated the biomechanical impact of pedicle screws on ASD in the lumbar spine [8]. Extension revision surgery requires reopening the previous scar and replacing the rods, leading to a longer operative time and a greater technical challenge. The conflict of ASD revision has sparked vigorous debate among spine surgeons, and it is a pressing clinical issue that needs to be addressed
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