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Imaging Transformer for MRI Denoising: a Scalable Model Architecture that enables SNR << 1 Imaging

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arxiv 2504.10534 v1 pith:R5DS34N3 submitted 2025-04-13 eess.IV eess.SPphysics.med-ph

Imaging Transformer for MRI Denoising: a Scalable Model Architecture that enables SNR << 1 Imaging

classification eess.IV eess.SPphysics.med-ph
keywords modelimagingmodelstransformerwerecompareddenoisingground-truth
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Purpose: To propose a flexible and scalable imaging transformer (IT) architecture with three attention modules for multi-dimensional imaging data and apply it to MRI denoising with very low input SNR. Methods: Three independent attention modules were developed: spatial local, spatial global, and frame attentions. They capture long-range signal correlation and bring back the locality of information in images. An attention-cell-block design processes 5D tensors ([B, C, F, H, W]) for 2D, 2D+T, and 3D image data. A High Resolution (HRNet) backbone was built to hold IT blocks. Training dataset consists of 206,677 cine series and test datasets had 7,267 series. Ten input SNR levels from 0.05 to 8.0 were tested. IT models were compared to seven convolutional and transformer baselines. To test scalability, four IT models 27m to 218m parameters were trained. Two senior cardiologists reviewed IT model outputs from which the EF was measured and compared against the ground-truth. Results: IT models significantly outperformed other models over the tested SNR levels. The performance gap was most prominent at low SNR levels. The IT-218m model had the highest SSIM and PSNR, restoring good image quality and anatomical details even at SNR 0.2. Two experts agreed at this SNR or above, the IT model output gave the same clinical interpretation as the ground-truth. The model produced images that had accurate EF measurements compared to ground-truth values. Conclusions: Imaging transformer model offers strong performance, scalability, and versatility for MR denoising. It recovers image quality suitable for confident clinical reading and accurate EF measurement, even at very low input SNR of 0.2.

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  1. High-resolution ultra-low-field MRI with SNRAware denoising

    physics.med-ph 2026-04 unverdicted novelty 4.0

    SNRAware-trained DL denoising consistently raises effective SNR in ULF MRI, enabling nominal resolutions comparable to clinical 3 T protocols across varied acquisition parameters.