Finite element model construction of thoracolumbar kyphosis in young patients with idiopathic Scheuermann's disease and analysis of biomechanical risk factors for low back pain
10.3969/j.issn.1000-6710.2025.04.002
- VernacularTitle:青年特发性休门氏病胸腰段后凸畸形的有限元模型构建及下腰痛生物力学风险因素研究
- Author:
Fang CHEN
1
;
Hongyu CHEN
;
Liang CHEN
;
Hao CHENG
;
Mingjun WANG
Author Information
1. 南京大学医学院附属泰康仙林鼓楼医院康复医学科(南京 210046)
- Publication Type:Journal Article
- Keywords:
Scheuermann's disease;
thoracolumbar kyphosis;
low back pain;
finite element analysis
- From:
Chinese Journal of Sports Medicine
2025;44(4):264-271
- CountryChina
- Language:Chinese
-
Abstract:
Objective To establish a finite element model of thoracolumbar kyphosis(TLK)for young patients with idiopathic Scheuermann's disease(SD),validate its effectiveness,and perform fi-nite element analysis to identify biomechanical factors contributing to low back pain caused by SD.Methods One TLK patient(26 years old)and one healthy(30 years old)subject were recruited.Spi-nal DICOM data were reconstructed three-dimensionally using Mimics software.Surface repair and fit-ting were performed in Geomagic Studio 2017,followed by modeling of intervertebral discs and end-plates in 3-matic software.Volume meshing and ligament construction were completed in Hypermesh 2017.Static simulations of the T8-S1 spinal segments for both groups were conducted in ANSYS.Af-ter validating the model using mechanical data,stress and strain distributions across vertebral bodies,intervertebral discs,and facet joint cartilage were calculated under identical constraints and loads.Re-sults 1)Significant differences were observed between the TLK patient and healthy subject in the me-chanical distribution of the T8-S1 segments of the spine.The healthy spine exhibited a peak strain of 1.62 mm,while the TLK patient showed a peak strain of 6.97 mm,330.2%higher than the former.Moreover,the peak stress in the TLK patient(10.51 MPa)exceeded the healthy subject(9.07 MPa)by 16.0%.2)Both groups demonstrated peak vertebral stress at the L5 level(9.07 MPa in the healthy individual vs.10.51 MPa in the TLK patient,15.8%higher).Stress distribution in the TLK patient was markedly uneven,with significant concentrations at the pedicles and laminae of L2,L3,and L4 vertebrae.3)Peak disc stress in the TLK patient was consistently higher,most notably at the L5/S1 segment(0.78 MPa in the TLK patient vs.0.16 MPa in the healthy subject,387.5%higher).4)Facet joint cartilage stress distribution in the TLK patient was abnormal.The healthy subject exhib-ited peak stress at L5/S1(1.53 MPa),whereas TLK patient showed peak stress at L1/L2(7.44 MPa),14.18 times higher than the former.Conclusion This study validates the finite element model of TLK deformity,confirming its utility for TLK-related research.Moreover,significant differences in stress-strain distribution and magnitude are observed between the TLK patient and healthy subject.Meanwhile,prolonged abnormal biomechanical loading,particularly localized stress concentrations in the L1-S1 vertebral bodies,discs,and facet joints,may accelerate degenerative changes and elevate the risk of low back pain.
