Heterogeneous material mapping methods for patient-specific finite element models of pelvic trabecular bone: A convergence study

•CT-derived elastic moduli of pelvic trabecular bone were obtained from six subjects.•The convergence of FE bone models with heterogeneous materials was investigated.•The sensitivity of FE output parameters to the material mapping method was studied.•A best material mapping method was recommended ba...

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Bibliographic Details
Published in:Medical engineering & physics 2021-10, Vol.96, p.1-12
Main Authors: Babazadeh Naseri, Ata, Dunbar, Nicholas J., Baines, Andrew J., Akin, John E., Higgs III, C. Fred, Fregly, Benjamin J.
Format: Article
Language:English
Subjects:
CT-derived elastic properties
Density-stiffness
Heterogenous material
Material mapping method
Patient-specific finite element model
Pelvic trabecular bone
Phantomless calibration
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Summary:•CT-derived elastic moduli of pelvic trabecular bone were obtained from six subjects.•The convergence of FE bone models with heterogeneous materials was investigated.•The sensitivity of FE output parameters to the material mapping method was studied.•A best material mapping method was recommended based on the FE mesh size relative to the CT voxel size.•The element size required for convergence of FE bone models was determined. Patient-specific finite element (FE) models of bone require the assignment of heterogeneous material properties extracted from the subject's computed tomography (CT) images. Though node-based (NB) and element-based (EB) material mapping methods (MMMs) have been proposed, the sensitivity and convergence of FE models to MMM for varying mesh sizes are not well understood. In this work, CT-derived and synthetic bone material data were used to evaluate the effect of MMM on results from FE analyses. Pelvic trabecular bone data was extracted from CT images of six subjects, while synthetic data were created to resemble trabecular bone properties. The numerical convergence of FE bone models using different MMMs were evaluated for strain energy, von-Mises stress, and strain. NB and EB MMMs both demonstrated good convergence regarding total strain energy, with the EB method having a slight edge over the NB. However, at the local level (e.g., maximum stress and strain), FE results were sensitive to the field type, MMM, and the FE mesh size. The EB method exhibited superior performance in finer meshes relative to the voxel size. The NB method converged better than did the EB method for coarser meshes. These findings may lead to higher-fidelity patient-specific FE bone models.
ISSN:1350-4533
1873-4030
DOI:10.1016/j.medengphy.2021.07.012