Adjacent segments biomechanics following lumbar fusion surgery: a musculoskeletal finite element model study

Mahdi Ebrahimkhani; Navid Arjmand; Aboulfazl Shirazi-Adl

doi:10.1007/s00586-022-07262-3

Adjacent segments biomechanics following lumbar fusion surgery: a musculoskeletal finite element model study

Eur Spine J. 2022 Jul;31(7):1630-1639. doi: 10.1007/s00586-022-07262-3. Epub 2022 May 28.

Authors

Mahdi Ebrahimkhani¹, Navid Arjmand², Aboulfazl Shirazi-Adl³

Affiliations

¹ Department of Mechanical Engineering, Sharif University of Technology, Tehran, 11155-9567, Iran.
² Department of Mechanical Engineering, Sharif University of Technology, Tehran, 11155-9567, Iran. navid.arjmand@polymtl.ca.
³ Division of Applied Mechanics, Department of Mechanical Engineering, Polytechnique, Montréal, QC, Canada.

PMID: 35633382
DOI: 10.1007/s00586-022-07262-3

Abstract

Purpose: This study exploits a novel musculoskeletal finite element (MS-FE) spine model to evaluate the post-fusion (L4-L5) alterations in adjacent segment kinetics.

Methods: Unlike the existing MS models with idealized representation of spinal joints, this model predicts stress/strain distributions in all passive tissues while organically coupled to a MS model. This generic (in terms of musculature and material properties) model uses population-based in vivo vertebral sagittal rotations, gravity loads, and an optimization algorithm to calculate muscle forces. Simulations represent individuals with an intact L4-L5, a preoperative severely degenerated L4-L5 (by reducing the disc height by ~ 60% and removing the nucleus incompressibility), and a postoperative fused L4-L5 segment with either a fixed or an altered lumbopelvic rhythm with respect to the intact condition (based on clinical observations). Changes in spine kinematics and back muscle cross-sectional areas (due to intraoperative injuries) are considered based on in vivo data while simulating three activities in upright/flexed postures.

Results: Postoperative changes in some adjacent segment kinetics were found considerable (i.e., larger than 25%) that depended on the postoperative lumbopelvic kinematics and preoperative L4-L5 disc condition. Postoperative alterations in adjacent disc shear, facet/ligament forces, and annulus stresses/strains were greater (> 25%) than those found in intradiscal pressure and compression (< 25%). Kinetics of the lower (L5-S1) and upper (L3-L4) adjacent segments were altered to different degrees.

Conclusion: Alterations in segmental rotations mainly affected adjacent disc shear forces, facet/ligament forces, and annulus/collagen fibers stresses/strains. An altered lumbopelvic rhythm (increased pelvis rotation) tends to mitigate some of these surgically induced changes.

Keywords: Adjacent segments; Kinematics; Lumbar fusion surgery; Musculoskeletal finite element model; Spine loads.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Biomechanical Phenomena
Finite Element Analysis
Humans
Intervertebral Disc* / surgery
Lumbar Vertebrae / physiology
Lumbar Vertebrae / surgery
Range of Motion, Articular / physiology
Spinal Fusion* / methods