Time-dependent biomechanical evaluation for corrective planning of scoliosis using finite element analysis – A comprehensive approach

Scoliosis is a medical condition marked by an abnormal lateral curvature of the spine, typically forming a sideways “S” or “C” shape. Mechanically, it manifests as a three-dimensional deformation of the spine, potentially leading to diverse clinical issues such as pain, diminished lung capacity, and...

Full description

Saved in:
Bibliographic Details
Published in:Heliyon 2024-03, Vol.10 (5), p.e26946-e26946, Article e26946
Main Authors: Alassaf, Ahmad, AlMohimeed, Ibrahim, Alghannam, Mohammed, Alotaibi, Saddam, Alhussaini, Khalid, Aleid, Adham, Alolayan, Salem, Sikkandar, Mohamed Yacin, Alhashim, Maryam M., Sheik, Sabarunisha Begum, Sudharsan, Natteri M.
Format: Article
Language:English
Subjects:
adolescents
biomechanics
computed tomography
deformation
FEM
finite element analysis
lungs
pain
polypropylenes
Predictive simulation
scoliosis
Shape memory response
Transient analysis
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Scoliosis is a medical condition marked by an abnormal lateral curvature of the spine, typically forming a sideways “S” or “C” shape. Mechanically, it manifests as a three-dimensional deformation of the spine, potentially leading to diverse clinical issues such as pain, diminished lung capacity, and postural abnormalities. This research specifically concentrates on the Adolescent Idiopathic Scoliosis (AIS) population, as existing literature indicates a tendency for this type of scoliosis to deteriorate over time. The principal aim of this investigation is to pinpoint the biomechanical factors contributing to the progression of scoliosis by employing Finite Element Analysis (FEA) on computed tomography (CT) data collected from adolescent patients. By accurately modeling the spinal curvature and related deformities, the stresses and strains experienced by vertebral and intervertebral structures under diverse loading conditions can be simulated and quantified. The transient simulation incorporated damping and inertial terms, along with the static stiffness matrix, to enhance comprehension of the response. The findings of this study indicate a significant reduction in the Cobb angle, halving from its initial value, decreasing from 35° to 17°. In degenerative scoliosis, failure was predicted at 109 cycles, with the Polypropylene brace deforming by 10.34 mm, while the Nitinol brace exhibited significantly less deformation at 7.734 mm. This analysis contributes to a better understanding of the biomechanical mechanisms involved in scoliosis development and can assist in the formulation of more effective treatment strategies. The FEA simulation emerges as a valuable supplementary tool for exploring various hypothetical scenarios by applying diverse loads at different locations to enhance comprehension of the effectiveness of proposed interventions.
ISSN:2405-8440
2405-8440
DOI:10.1016/j.heliyon.2024.e26946