A Physics-based Generative Model to Synthesize Training Datasets for MRI-based Fat Quantification
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| Publicado en: | arXiv.org (Dec 11, 2024), p. n/a |
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| Autor principal: | |
| Otros Autores: | , , , |
| Publicado: |
Cornell University Library, arXiv.org
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| Materias: | |
| Acceso en línea: | Citation/Abstract Full text outside of ProQuest |
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| Resumen: | Deep learning-based techniques have potential to optimize scan and post-processing times required for MRI-based fat quantification, but they are constrained by the lack of large training datasets. Generative models are a promising tool to perform data augmentation by synthesizing realistic datasets. However no previous methods have been specifically designed to generate datasets for quantitative MRI (q-MRI) tasks, where reference quantitative maps and large variability in scanning protocols are usually required. We propose a Physics-Informed Latent Diffusion Model (PI-LDM) to synthesize quantitative parameter maps jointly with customizable MR images by incorporating the signal generation model. We assessed the quality of PI-LDM's synthesized data using metrics such as the Fréchet Inception Distance (FID), obtaining comparable scores to state-of-the-art generative methods (FID: 0.0459). We also trained a U-Net for the MRI-based fat quantification task incorporating synthetic datasets. When we used a few real (10 subjects, \(~200\) slices) and numerous synthetic samples (\(>3000\)), fat fraction at specific liver ROIs showed a low bias on data obtained using the same protocol than training data (\(0.10\%\) at \(\hbox{ROI}_1\), \(0.12\%\) at \(\hbox{ROI}_2\)) and on data acquired with an alternative protocol (\(0.14\%\) at \(\hbox{ROI}_1\), \(0.62\%\) at \(\hbox{ROI}_2\)). Future work will be to extend PI-LDM to other q-MRI applications. |
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| ISSN: | 2331-8422 |
| Fuente: | Engineering Database |