Methodology for the assessment of the risk of failure of metastatic vertebrae through ROM-based patient-specific simulations

The structural performance of a vertebra can be significantly undermined if it develops a tumour, that could even lead to the vertebra's structural collapse. In cancers with a high prevalence of spinal metastasis, like prostate and breast cancer, this supposes an additional problem to account f...

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Bibliographic Details
Published in:Computers & structures 2024-06, Vol.296, p.107298, Article 107298
Main Authors: Garcia-Andrés, Xavier, Nadal, Enrique, Arana, Estanislao, Gandía-Vañó, Blai, Ródenas, Juan José
Format: Article
Language:English
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Summary:The structural performance of a vertebra can be significantly undermined if it develops a tumour, that could even lead to the vertebra's structural collapse. In cancers with a high prevalence of spinal metastasis, like prostate and breast cancer, this supposes an additional problem to account for on top of the regular treatment. In this work, we propose a patient-specific methodology capable of immediately predicting the structural behaviour and risk of failure of a vertebra with a spherical tumour of arbitrary characteristics. This immediate evaluation of the results, together with the ease of use of the proposed methodology, that includes the creation of a personalized computational model from a CT scan of the patient's vertebra, makes this methodology suitable for its use in clinical practice. By running several personalized structural analyses of vertebrae with simulated tumours, using the Cartesian grid FEM (cgFEM) in combination with the Sparse Subspace Learning (SSL) technique, we generate a surrogate model of the vertebra. This model is able to predict the vertebra's behaviour for different tumour growth scenarios, and could be useful as a clinical decision support tool. •Creation of a surrogate model of the vertebrae from a patient's CT-scan by combining Cartesian grid FEM and the Sparse Subspace Learning technique.•Computation in real time of the structural behaviour of a vertebra with a tumour of any radius, density and position within the main vertebral body.•Prediction of the behaviour of the metastatic vertebra for different tumour growth scenarios in a time compatible with clinical practice.•Proof of concept of the methodology and how it would be applied to a clinical case.
ISSN:0045-7949
1879-2243
DOI:10.1016/j.compstruc.2024.107298