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Deep Unfolding Network with Spatial Alignment for multi-modal MRI reconstruction (2312.16998v1)

Published 28 Dec 2023 in eess.IV and cs.CV

Abstract: Multi-modal Magnetic Resonance Imaging (MRI) offers complementary diagnostic information, but some modalities are limited by the long scanning time. To accelerate the whole acquisition process, MRI reconstruction of one modality from highly undersampled k-space data with another fully-sampled reference modality is an efficient solution. However, the misalignment between modalities, which is common in clinic practice, can negatively affect reconstruction quality. Existing deep learning-based methods that account for inter-modality misalignment perform better, but still share two main common limitations: (1) The spatial alignment task is not adaptively integrated with the reconstruction process, resulting in insufficient complementarity between the two tasks; (2) the entire framework has weak interpretability. In this paper, we construct a novel Deep Unfolding Network with Spatial Alignment, termed DUN-SA, to appropriately embed the spatial alignment task into the reconstruction process. Concretely, we derive a novel joint alignment-reconstruction model with a specially designed cross-modal spatial alignment term. By relaxing the model into cross-modal spatial alignment and multi-modal reconstruction tasks, we propose an effective algorithm to solve this model alternatively. Then, we unfold the iterative steps of the proposed algorithm and design corresponding network modules to build DUN-SA with interpretability. Through end-to-end training, we effectively compensate for spatial misalignment using only reconstruction loss, and utilize the progressively aligned reference modality to provide inter-modality prior to improve the reconstruction of the target modality. Comprehensive experiments on three real datasets demonstrate that our method exhibits superior reconstruction performance compared to state-of-the-art methods.

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References (48)
  1. MoDL: Model-based deep learning architecture for inverse problems. IEEE Transactions on Medical Imaging 38, 394–405.
  2. A learnable variational model for joint multimodal MRI reconstruction and synthesis, in: International Conference on Medical Image Computing and Computer-Assisted Intervention, Springer. pp. 354–364.
  3. Prior-guided image reconstruction for accelerated multi-contrast MRI via generative adversarial networks. IEEE Journal of Selected Topics in Signal Processing 14, 1072–1087.
  4. MRI banding removal via adversarial training, in: Advances in Neural Information Processing Systems, pp. 7660–7670.
  5. Multicontrast MRI reconstruction with structure-guided total variation. SIAM Journal on Imaging Sciences 9, 1084–1106.
  6. Decoupled algorithm for MRI reconstruction using nonlocal block matching model: BM3D-MRI. Journal of Mathematical Imaging and Vision 56, 430–440.
  7. KIKI-net: cross-domain convolutional neural networks for reconstructing undersampled magnetic resonance images. Magnetic Resonance in Medicine 80, 2188–2201.
  8. Multimodal transformer for accelerated MR imaging. IEEE Transactions on Medical Imaging 42, 2804–2816.
  9. Constrained restoration and the recovery of discontinuities. IEEE Transactions on Pattern Analysis & Machine Intelligence 14, 367–383.
  10. Deep residual learning for image recognition, in: 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR), pp. 770–778.
  11. Half-quadratic-based iterative minimization for robust sparse representation. IEEE transactions on pattern analysis and machine intelligence 36, 261–275.
  12. Self-supervised deep unrolled reconstruction using regularization by denoising. IEEE Transactions on Medical Imaging , 1–1.
  13. Deep low-rank plus sparse network for dynamic MR imaging. Medical Image Analysis 73, 102190.
  14. GA-HQS: MRI reconstruction via a generically accelerated unfolding approach, in: 2023 IEEE International Conference on Multimedia and Expo (ICME), IEEE. pp. 186–191.
  15. Latent-space unfolding for MRI reconstruction, in: Proceedings of the 31st ACM International Conference on Multimedia, pp. 1294–1302.
  16. Image reconstruction of compressed sensing MRI using graph-based redundant wavelet transform. Medical Image Analysis 27, 93–104.
  17. Sparse MRI reconstruction using multi-contrast image guided graph representation. Magnetic Resonance Imaging 43, 95–104.
  18. Deep unfolding convolutional dictionary model for multi-contrast MRI super-resolution and reconstruction, in: Elkind, E. (Ed.), Proceedings of the Thirty-Second International Joint Conference on Artificial Intelligence, IJCAI-23, International Joint Conferences on Artificial Intelligence Organization. pp. 1008–1016. Main Track.
  19. Deep unregistered multi-contrast MRI reconstruction. Magnetic Resonance Imaging 81, 33–41.
  20. Sparse MRI: The application of compressed sensing for rapid MR imaging. Magnetic Resonance in Medicine: An Official Journal of the International Society for Magnetic Resonance in Medicine 58, 1182–1195.
  21. Magnetic resonance image reconstruction from undersampled measurements using a patch-based nonlocal operator. Medical Image Analysis 18, 843–856.
  22. MD-Recon-Net: A parallel dual-domain convolutional neural network for compressed sensing MRI. IEEE Transactions on Radiation and Plasma Medical Sciences 5, 120–135.
  23. MR image reconstruction from highly undersampled k-space data by dictionary learning. IEEE Transactions on Medical Imaging 30, 1028–1041.
  24. U-Net: Convolutional networks for biomedical image segmentation, in: Navab, N., Hornegger, J., Wells, W.M., Frangi, A.F. (Eds.), Medical Image Computing and Computer-Assisted Intervention – MICCAI 2015, Springer International Publishing, Cham. pp. 234–241.
  25. Subsampled brain MRI reconstruction by generative adversarial neural networks. Medical Image Analysis 65, 101747.
  26. Coupled dictionary learning for multi-contrast MRI reconstruction. IEEE Transactions on Medical Imaging 39, 621–633.
  27. End-to-end variational networks for accelerated MRI reconstruction, in: Martel, A.L., Abolmaesumi, P., Stoyanov, D., Mateus, D., Zuluaga, M.A., Zhou, S.K., Racoceanu, D., Joskowicz, L. (Eds.), Medical Image Computing and Computer Assisted Intervention – MICCAI 2020, Springer International Publishing, Cham. pp. 64–73.
  28. A deep information sharing network for multi-contrast compressed sensing MRI reconstruction. IEEE Transactions on Image Processing 28, 6141–6153.
  29. InDuDoNet: An interpretable dual domain network for CT metal artifact reduction, in: de Bruijne, M., Cattin, P.C., Cotin, S., Padoy, N., Speidel, S., Zheng, Y., Essert, C. (Eds.), Medical Image Computing and Computer Assisted Intervention – MICCAI 2021, Springer International Publishing, Cham. pp. 107–118.
  30. InDuDoNet+: A deep unfolding dual domain network for metal artifact reduction in CT images. Medical Image Analysis 85, 102729.
  31. Accelerating magnetic resonance imaging via deep learning, in: 2016 IEEE 13th international symposium on biomedical imaging (ISBI), IEEE. pp. 514–517.
  32. IKWI-net: A cross-domain convolutional neural network for undersampled magnetic resonance image reconstruction. Magnetic Resonance Imaging 73, 1–10.
  33. Reference-based MRI. Medical Physics 43, 5357–5369.
  34. Ultra-fast T2-Weighted MR reconstruction using complementary T1-Weighted information, in: Frangi, A.F., Schnabel, J.A., Davatzikos, C., Alberola-López, C., Fichtinger, G. (Eds.), Medical Image Computing and Computer Assisted Intervention – MICCAI 2018, Springer International Publishing, Cham. pp. 215–223.
  35. Deep-learning-based multi-modal fusion for fast MR reconstruction. IEEE Transactions on Biomedical Engineering 66, 2105–2114.
  36. Learned half-quadratic splitting network for MR image reconstruction, in: Konukoglu, E., Menze, B., Venkataraman, A., Baumgartner, C., Dou, Q., Albarqouni, S. (Eds.), Proceedings of The 5th International Conference on Medical Imaging with Deep Learning, PMLR. pp. 1403–1412.
  37. Multimodal MRI reconstruction assisted with spatial alignment network. IEEE Transactions on Medical Imaging 41, 2499–2509.
  38. DAGAN: Deep de-aliasing generative adversarial networks for fast compressed sensing MRI reconstruction. IEEE Transactions on Medical Imaging 37, 1310–1321.
  39. MGDUN: An interpretable network for multi-contrast MRI image super-resolution reconstruction. Computers in Biology and Medicine 167, 107605.
  40. Model-guided multi-contrast deep unfolding network for MRI super-resolution reconstruction, in: Proceedings of the 30th ACM International Conference on Multimedia, Association for Computing Machinery. p. 3974–3982.
  41. Compressed sensing MRI via two-stage reconstruction. IEEE Transactions on Biomedical Engineering 62, 110–118.
  42. ADMM-CSNet: A deep learning approach for image compressive sensing. IEEE Transactions on Pattern Analysis and Machine Intelligence 42, 521–538.
  43. Model-driven deep attention network for ultra-fast compressive sensing MRI guided by cross-contrast MR image, in: Martel, A.L., Abolmaesumi, P., Stoyanov, D., Mateus, D., Zuluaga, M.A., Zhou, S.K., Racoceanu, D., Joskowicz, L. (Eds.), Medical Image Computing and Computer Assisted Intervention – MICCAI 2020, Springer International Publishing, Cham. pp. 188–198.
  44. Fast multiclass dictionaries learning with geometrical directions in MRI reconstruction. IEEE Transactions on Biomedical Engineering 63, 1850–1861.
  45. High-throughput deep unfolding network for compressive sensing MRI. IEEE Journal of Selected Topics in Signal Processing 16, 750–761.
  46. Dual-domain convolutional neural networks for improving structural information in 3 T MRI. Magnetic Resonance Imaging 64, 90–100.
  47. DuDoRNet: Learning a dual-domain recurrent network for fast MRI reconstruction with deep t1 prior, in: Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), pp. 4272–4281.
  48. Image reconstruction by domain-transform manifold learning. Nature 555, 487–492.
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Authors (5)
  1. Hao Zhang (948 papers)
  2. Qi Wang (561 papers)
  3. Jun Shi (85 papers)
  4. Shihui Ying (22 papers)
  5. Zhijie Wen (5 papers)

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