Finite element simulation of growth modulation during brace treatment of adolescent idiopathic scoliosis.
Aymeric GuyCarl-Éric AubinPublished in: Journal of orthopaedic research : official publication of the Orthopaedic Research Society (2023)
Adolescent idiopathic scoliosis (AIS) is a spine deformity whose progression during growth is affected by asymmetrical loads acting on the spine. The conservative brace treatment aims to limit the deformity's progression until the end of skeletal growth. This study's objective was to develop a patient-specific finite element model (FEM) simulating immediate in-brace correction and subsequent growth modulation over 2 years of treatment. Thirty-five retrospective AIS cases with documented correction over 2 years were analyzed. For each case, a patient-specific FEM was built, and in-brace correction was simulated. Vertebral growth and its modulation were modeled using simulated pressures on epiphyseal vertebral growth plates, including a compliance factor representing the recorded brace wear. The simulated Cobb angles, thoracic kyphosis, lumbar lordosis and apical vertebral rotation were compared with the actual measurements immediately in-brace and out-of-brace at the 2-year follow-up. Treatment outcomes according to simulated compliance scenarios of no brace-wear vs. full brace-wear were also computed. The average immediate in-brace difference between the simulated and actual Cobb angle was 4.9° (MT) and 3.7° (TL/L). 2-year out-of-brace, it was 5.6° (MT) and 5.4° (TL/L). The no brace-wear and full brace-wear compliance scenarios resulted respectively in 15/35 (43%) and 31/35 (89%) simulated spine deformities progressing by less than 5° over 2 years of treatment. Clinical significance: the FEM's ability to simulate the final correction with an accuracy on the order of the radiological measurements' interoperator reproducibility, combined with its sensitivity to brace-wear compliance, provides confidence in the model's predictions for a comparative context of use like improving a brace's design before its application. This article is protected by copyright. All rights reserved.