Effect of different designs of interspinous process devices on the instrumented and adjacent levels after double-level lumbar decompression surgery: A finite element analysis.

Hao-Ju Lo,Yi-Jie Kuo,Sai-Wei Yang,Hung-Ming Chen,Osama Farouk

doi:10.1371/journal.pone.0244571

Abstract

Recently, various designs and material manufactured interspinous process devices (IPDs) are on the market in managing symptomatic lumbar spinal stenosis (LSS). However, atraumatic fracture of the intervening spinous process has been reported in patients, particularly, double or multiple level lumbar decompression surgery with IPDs. This study aimed to biomechanically investigate the effects of few commercial IPDs, namely DIAMTM, CoflexTM, and M-PEEK, which were implanted into the L2-3, L3-4 double-level lumbar spinal processes. A validated finite element model of musculoskeletal intact lumbar spinal column was modified to accommodate the numerical analysis of different implants. The range of motion (ROM) between each vertebra, stiffness of the implanted level, intra stress on the intervertebral discs and facet joints, and the contact forces on spinous processes were compared. Among the three implants, the Coflex system showed the largest ROM restriction in extension and caused the highest stress over the disc annulus at the adjacent levels, as well as the sandwich phenomenon on the spinous process at the instrumented levels. Further, the DIAM device provided a superior loading-sharing between the two bridge supports, and the M-PEEK system offered a superior load-sharing from the superior spinous process to the lower pedicle screw. The limited motion at the instrumented segments were compensated by the upper and lower adjacent functional units, however, this increasing ROM and stress would accelerate the degeneration of un-instrumented segments.

Highlights

Lumbar spinal stenosis (LSS) is defined as a narrowing of the spinal canal and can cause considerable pain or numbness in the legs
Compared to the intact model in axial rotation, the range of motion (ROM) of instrumented and adjacent levels was very similar in the DIAM and M-PEEK models
The ROM differences in all instrumented models were less than 1% for each segment as compared to the intact model; for the Coflex model, the ROM was more variation as compared to the intact model, as depicted in Fig 2 and Table 2

Summary

Objectives

This study aimed to biomechanically investigate the effects of few commercial IPDs, namely DIAMTM, CoflexTM, and M-PEEK, which were implanted into the L2-3, L3-4 double-level lumbar spinal processes. The goal of this work was to look into alterations in the biomechanical characteristics of the lumbar spine after implanting three different designed IPDs across two adjacent levels and the efficacy of stress relief as well as the ROM. The goal of this work was to look into alterations in the biomechanical characteristics of the lumbar spine after implanting an IPD across two adjacent levels and to compare the significance with a single-level instrumented model

Methods

Results

Discussion

Conclusion