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Original Articles

Shape parametrization of bio-mechanical finite element models based on medical images

ORCID Icon, , , , , & show all
Pages 480-489 | Received 15 Dec 2017, Accepted 28 Feb 2018, Published online: 22 Mar 2018
 

Abstract

The main objective of this study is to combine the statistical shape analysis with a morphing procedure in order to generate shape-parametric finite element models of tissues and organs and to explore the reliability and the limitations of this approach when applied to databases of real medical images. As classical statistical shape models are not always adapted to the morphing procedure, a new registration method was developed in order to maximize the morphing efficiency. The method was compared to the traditional iterative thin plate spline (iTPS). Two data sets of 33 proximal femora shapes and 385 liver shapes were used for the comparison. The principal component analysis was used to get the principal morphing modes. In terms of anatomical shape reconstruction (evaluated through the criteria of generalization, compactness and specificity), our approach compared fairly well to the iTPS method, while performing remarkably better in terms of mesh quality, since it was less prone to generate invalid meshes in the interior. This was particularly true in the liver case. Such methodology offers a potential application for the generation of automated finite element (FE) models from medical images. Parametrized anatomical models can also be used to assess the influence of inter-patient variability on the biomechanical response of the tissues. Indeed, thanks to the shape parametrization the user would easily have access to a valid FE model for any shape belonging to the parameters subspace.

Notes

No potential conflict of interest was reported by the authors.

Additional information

Funding

This work was performed by using HPC resources of the Centrale Nantes Supercomputing Centre on the cluster Liger, granted by the High Performance Computing Institute (ICI) (https://ici.ec-nantes.fr/). This research was financially supported by BPI France through 3D-Surg, a project of the ‘Programme d’Investissements d’Avenir – PIA’ of the French Government. (http://www.3d-surg.eu/).

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