Abstract
Currently, there are no clinically available tools or applications which could predict osteoarthritis development. Some computational models have been presented to simulate cartilage degeneration, but they are not clinically feasible due to time required to build subject-specific knee models. Therefore, the objective of this study was to develop a template-based modeling method for rapid prediction of knee joint cartilage degeneration. Knee joint models for 21 subjects were constructed with two different template approaches (multiple templates and one template) based on the MRI data. Geometries were also generated by manual segmentation. Evaluated volumes of cartilage degeneration for each subject, as assessed with the degeneration algorithm, were compared with experimentally observed 4 year follow up Kellgren-Lawrence (KL) grades. Furthermore, the effect of meniscus was tested by generating models with subject-specific meniscal supporting forces and those with the average meniscal supporting force from all models. All tested models were able to predict most severe cartilage degeneration to those subjects who had the highest KL grade after 4 year follow up. Surprisingly, in terms of statistical significance, the best result was obtained with one template approach and average meniscal support. This model was fully able to categorize all subjects to their experimentally defined groups (KL0, KL2 and KL3) based on the 4 year follow-up data. The results suggest that a template- or population-based approach, which is much faster than fully subject-specific, could be applied as a clinical prediction tool for osteoarthritis.
Highlights
Computational finite element (FE) models of the knee joint are able to offer a quantitative estimation about risks for the onset and development of knee osteoarthritis (OA) based on mechanical signals experienced by tissues
All FE simulations were performed with Abaqus FE package (v6.13-3, Dassault Systemes, Providence, RI, USA) using UMAT subroutine to implement fibril reinforced poroviscoelastic (FRPVE) material properties for cartilage tissues
Before comparing patient-specific and template approaches, volumetric degeneration predictions based on the Eqs. [1], [2] and [10] were compared with each other, because that parameter has been shown to correlate well with the predicted level of OA.26
Summary
Computational finite element (FE) models of the knee joint are able to offer a quantitative estimation about risks for the onset and development of knee osteoarthritis (OA) based on mechanical signals experienced by tissues. They can be used to assess the feasibility of different rehabilitation and surgical protocols. Computational finite element (FE) models of the knee joint are able to offer a quantitative estimation about risks for the onset and development of knee osteoarthritis (OA) based on mechanical signals experienced by tissues.. Computational finite element (FE) models of the knee joint are able to offer a quantitative estimation about risks for the onset and development of knee osteoarthritis (OA) based on mechanical signals experienced by tissues.18,19,40 They can be used to assess the feasibility of different rehabilitation and surgical protocols. Automated segmentation methods may cause inaccuracies (roughness) in contacting surfaces. This leads to difficulties in generation of proper FE meshes and causes convergence problems
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