Denoising Diffusion Probabilistic Models for Magnetic Resonance Fingerprinting
Magnetic Resonance Fingerprinting (MRF) is a time-efficient approach to quantitative MRI, enabling the mapping of multiple tissue properties from a single, accelerated scan. However, achieving accurate reconstructions remains challenging, particularly in highly accelerated and undersampled acquisiti...
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| creator | Mayo, Perla Pirkl, Carolin M Achim, Alin Menze, Bjoern H Golbabaee, Mohammad |
| description | Magnetic Resonance Fingerprinting (MRF) is a time-efficient approach to
quantitative MRI, enabling the mapping of multiple tissue properties from a
single, accelerated scan. However, achieving accurate reconstructions remains
challenging, particularly in highly accelerated and undersampled acquisitions,
which are crucial for reducing scan times. While deep learning techniques have
advanced image reconstruction, the recent introduction of diffusion models
offers new possibilities for imaging tasks, though their application in the
medical field is still emerging. Notably, diffusion models have not yet been
explored for the MRF problem. In this work, we propose for the first time a
conditional diffusion probabilistic model for MRF image reconstruction.
Qualitative and quantitative comparisons on in-vivo brain scan data demonstrate
that the proposed approach can outperform established deep learning and
compressed sensing algorithms for MRF reconstruction. Extensive ablation
studies also explore strategies to improve computational efficiency of our
approach. |
| doi_str_mv | 10.48550/arxiv.2410.23318 |
| format | Article |
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quantitative MRI, enabling the mapping of multiple tissue properties from a
single, accelerated scan. However, achieving accurate reconstructions remains
challenging, particularly in highly accelerated and undersampled acquisitions,
which are crucial for reducing scan times. While deep learning techniques have
advanced image reconstruction, the recent introduction of diffusion models
offers new possibilities for imaging tasks, though their application in the
medical field is still emerging. Notably, diffusion models have not yet been
explored for the MRF problem. In this work, we propose for the first time a
conditional diffusion probabilistic model for MRF image reconstruction.
Qualitative and quantitative comparisons on in-vivo brain scan data demonstrate
that the proposed approach can outperform established deep learning and
compressed sensing algorithms for MRF reconstruction. Extensive ablation
studies also explore strategies to improve computational efficiency of our
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quantitative MRI, enabling the mapping of multiple tissue properties from a
single, accelerated scan. However, achieving accurate reconstructions remains
challenging, particularly in highly accelerated and undersampled acquisitions,
which are crucial for reducing scan times. While deep learning techniques have
advanced image reconstruction, the recent introduction of diffusion models
offers new possibilities for imaging tasks, though their application in the
medical field is still emerging. Notably, diffusion models have not yet been
explored for the MRF problem. In this work, we propose for the first time a
conditional diffusion probabilistic model for MRF image reconstruction.
Qualitative and quantitative comparisons on in-vivo brain scan data demonstrate
that the proposed approach can outperform established deep learning and
compressed sensing algorithms for MRF reconstruction. Extensive ablation
studies also explore strategies to improve computational efficiency of our
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quantitative MRI, enabling the mapping of multiple tissue properties from a
single, accelerated scan. However, achieving accurate reconstructions remains
challenging, particularly in highly accelerated and undersampled acquisitions,
which are crucial for reducing scan times. While deep learning techniques have
advanced image reconstruction, the recent introduction of diffusion models
offers new possibilities for imaging tasks, though their application in the
medical field is still emerging. Notably, diffusion models have not yet been
explored for the MRF problem. In this work, we propose for the first time a
conditional diffusion probabilistic model for MRF image reconstruction.
Qualitative and quantitative comparisons on in-vivo brain scan data demonstrate
that the proposed approach can outperform established deep learning and
compressed sensing algorithms for MRF reconstruction. Extensive ablation
studies also explore strategies to improve computational efficiency of our
approach.</abstract><doi>10.48550/arxiv.2410.23318</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Computer Vision and Pattern Recognition Computer Science - Learning |
| title | Denoising Diffusion Probabilistic Models for Magnetic Resonance Fingerprinting |
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