Finite element analysis of very large bone models based on micro-CT scans
Abstract
High-resolution voxel-based micro-finite element (μFE) models derived from μCT imaging enable detailed investigation of bone mechanics but remain computationally challenging at anatomically relevant scales. This study presents a comprehensive μFE framework for large-scale biomechanical analysis of an intact New Zealand White (NZW) rabbit femur, integrating advanced segmentation, scalable finite element solvers, and experimental validation using predominantly open-source libraries. Bone geometries were segmented from μCT data using the MIA clustering algorithm and converted into voxel-based μFE meshes, which were solved using the open-source MFEM library with algorithms designed for large-scale linear elasticity systems. The numerical solutions were verified by comparing with a commercial finite element solver, and by evaluating the performance of full assembly and element-by-element formulations within MFEM. Models containing over 8×108 DOFs were solved using moderate HPC resources, demonstrating the feasibility of anatomically realistic μFE simulations at this scale. Resolution effects were investigated by comparing models with voxel sizes of 20, 40, and 80 μm, revealing that 40 μm preserves boundary displacement and principal strain distributions with minimal bias while significantly reducing computational cost. Sensitivity analyses further showed that segmentation parameters influence the global mechanical response. Finally, μFE predictions were coupled with Digital Image Correlation measurements on an NZW rabbit femur under compression to calibrate effective bone material properties at the micron scale. The results demonstrate that large-scale, experimentally informed μFE modeling can be achieved using open-source tools, providing a robust foundation for preclinical assessment of bone mechanics and treatment-related risks.
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