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Dual-Domain Self-Supervised Learning for Accelerated Non-Cartesian MRI Reconstruction

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arxiv 2302.09244 v1 pith:OXDCHBVA submitted 2023-02-18 eess.IV cs.CVcs.LG

Dual-Domain Self-Supervised Learning for Accelerated Non-Cartesian MRI Reconstruction

classification eess.IV cs.CVcs.LG
keywords reconstructiondatanon-cartesianacceleratedfullyimprovedk-spacepartitions
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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While enabling accelerated acquisition and improved reconstruction accuracy, current deep MRI reconstruction networks are typically supervised, require fully sampled data, and are limited to Cartesian sampling patterns. These factors limit their practical adoption as fully-sampled MRI is prohibitively time-consuming to acquire clinically. Further, non-Cartesian sampling patterns are particularly desirable as they are more amenable to acceleration and show improved motion robustness. To this end, we present a fully self-supervised approach for accelerated non-Cartesian MRI reconstruction which leverages self-supervision in both k-space and image domains. In training, the undersampled data are split into disjoint k-space domain partitions. For the k-space self-supervision, we train a network to reconstruct the input undersampled data from both the disjoint partitions and from itself. For the image-level self-supervision, we enforce appearance consistency obtained from the original undersampled data and the two partitions. Experimental results on our simulated multi-coil non-Cartesian MRI dataset demonstrate that DDSS can generate high-quality reconstruction that approaches the accuracy of the fully supervised reconstruction, outperforming previous baseline methods. Finally, DDSS is shown to scale to highly challenging real-world clinical MRI reconstruction acquired on a portable low-field (0.064 T) MRI scanner with no data available for supervised training while demonstrating improved image quality as compared to traditional reconstruction, as determined by a radiologist study.

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