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Autores principales: Cerrone, D., Riccobelli, D., Gazzoni, S., Vitullo, P., Ballarin, F., Falco, J., Acerbi, F., Manzoni, A., Zunino, P., Ciarletta, P.
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2412.05330
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author Cerrone, D.
Riccobelli, D.
Gazzoni, S.
Vitullo, P.
Ballarin, F.
Falco, J.
Acerbi, F.
Manzoni, A.
Zunino, P.
Ciarletta, P.
author_facet Cerrone, D.
Riccobelli, D.
Gazzoni, S.
Vitullo, P.
Ballarin, F.
Falco, J.
Acerbi, F.
Manzoni, A.
Zunino, P.
Ciarletta, P.
contents Glioblastoma is among the most aggressive brain tumors in adults, characterized by patient-specific invasion patterns driven by the underlying brain microstructure. In this work, we present a proof-of-concept for a mathematical model of GBL growth, enabling real-time prediction and patient-specific parameter identification from longitudinal neuroimaging data. The framework exploits a diffuse-interface mathematical model to describe the tumor evolution and a reduced-order modeling strategy, relying on proper orthogonal decomposition, trained on synthetic data derived from patient-specific brain anatomies reconstructed from magnetic resonance imaging and diffusion tensor imaging. A neural network surrogate learns the inverse mapping from tumor evolution to model parameters, achieving significant computational speed-up while preserving high accuracy. To ensure robustness and interpretability, we perform both global and local sensitivity analyses, identifying the key biophysical parameters governing tumor dynamics and assessing the stability of the inverse problem solution. These results establish a methodological foundation for future clinical deployment of patient-specific digital twins in neuro-oncology.
format Preprint
id arxiv_https___arxiv_org_abs_2412_05330
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Patient-specific prediction of glioblastoma growth via reduced order modeling and neural networks
Cerrone, D.
Riccobelli, D.
Gazzoni, S.
Vitullo, P.
Ballarin, F.
Falco, J.
Acerbi, F.
Manzoni, A.
Zunino, P.
Ciarletta, P.
Image and Video Processing
Machine Learning
Numerical Analysis
Biological Physics
Tissues and Organs
Glioblastoma is among the most aggressive brain tumors in adults, characterized by patient-specific invasion patterns driven by the underlying brain microstructure. In this work, we present a proof-of-concept for a mathematical model of GBL growth, enabling real-time prediction and patient-specific parameter identification from longitudinal neuroimaging data. The framework exploits a diffuse-interface mathematical model to describe the tumor evolution and a reduced-order modeling strategy, relying on proper orthogonal decomposition, trained on synthetic data derived from patient-specific brain anatomies reconstructed from magnetic resonance imaging and diffusion tensor imaging. A neural network surrogate learns the inverse mapping from tumor evolution to model parameters, achieving significant computational speed-up while preserving high accuracy. To ensure robustness and interpretability, we perform both global and local sensitivity analyses, identifying the key biophysical parameters governing tumor dynamics and assessing the stability of the inverse problem solution. These results establish a methodological foundation for future clinical deployment of patient-specific digital twins in neuro-oncology.
title Patient-specific prediction of glioblastoma growth via reduced order modeling and neural networks
topic Image and Video Processing
Machine Learning
Numerical Analysis
Biological Physics
Tissues and Organs
url https://arxiv.org/abs/2412.05330