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Residual Back Projection With Untrained Neural Networks (2210.14416v3)

Published 26 Oct 2022 in eess.IV, cs.CV, and cs.LG

Abstract: Background and Objective: The success of neural networks in a number of image processing tasks has motivated their application in image reconstruction problems in computed tomography (CT). While progress has been made in this area, the lack of stability and theoretical guarantees for accuracy, together with the scarcity of high-quality training data for specific imaging domains pose challenges for many CT applications. In this paper, we present a framework for iterative reconstruction (IR) in CT that leverages the hierarchical structure of neural networks, without the need for training. Our framework incorporates this structural information as a deep image prior (DIP), and uses a novel residual back projection (RBP) connection that forms the basis for our iterations. Methods: We propose using an untrained U-net in conjunction with a novel residual back projection to minimize an objective function and achieve high-accuracy reconstruction. In each iteration, the weights of the untrained U-net are optimized, and the output of the U-net in the current iteration is used to update the input of the U-net in the next iteration through the aforementioned RBP connection. Results: Experimental results demonstrate that the RBP-DIP framework offers improvements over other state-of-the-art conventional IR methods, as well as pre-trained and untrained models with similar network structures under multiple conditions. These improvements are particularly significant in the few-view, limited-angle, and low-dose imaging configurations. Conclusions: Applying to both parallel and fan beam X-ray imaging, our framework shows significant improvement under multiple conditions. Furthermore, the proposed framework requires no training data and can be adjusted on-demand to adapt to different conditions (e.g. noise level, geometry, and imaged object).

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References (46)
  1. Improving limited angle ct reconstruction with a robust gan prior. arXiv preprint arXiv:1910.01634 .
  2. On instabilities of deep learning in image reconstruction and the potential costs of ai. Proceedings of the National Academy of Sciences 117, 30088–30095.
  3. The lung image database consortium (lidc) and image database resource initiative (idri): a completed reference database of lung nodules on ct scans. Medical physics 38, 915–931.
  4. Computed tomography reconstruction using deep image prior and learned reconstruction methods. Inverse Problems 36, 094004.
  5. Chest pathology detection using deep learning with non-medical training, in: 2015 IEEE 12th international symposium on biomedical imaging (ISBI), IEEE. pp. 294–297.
  6. On hallucinations in tomographic image reconstruction. IEEE transactions on medical imaging 40, 3249–3260.
  7. A generalized gaussian image model for edge-preserving map estimation. IEEE Transactions on image processing 2, 296–310.
  8. Low-dose ct denoising with convolutional neural network, in: 2017 IEEE 14th International Symposium on Biomedical Imaging (ISBI 2017), IEEE. pp. 143–146.
  9. Automatic classification of pulmonary peri-fissural nodules in computed tomography using an ensemble of 2d views and a convolutional neural network out-of-the-box. Medical image analysis 26, 195–202.
  10. Comprehensive Biomedical Physics, Vol. 2. Elsevier. chapter Fundamentals of CT reconstruction in 2D and 3D. pp. 263–95.
  11. Self-guided limited-angle computed tomography reconstruction based on anisotropic relative total variation. IEEE Access 8, 70465–70476.
  12. Pet image reconstruction using deep image prior. IEEE transactions on medical imaging 38, 1655–1665.
  13. The troublesome kernel – on hallucinations, no free lunches and the accuracy-stability trade-off in inverse problems. arXiv:2001.01258.
  14. Special: single-shot projection error correction integrated adversarial learning for limited-angle ct. IEEE Transactions on Computational Imaging 7, 734--746.
  15. Deep convolutional neural network for inverse problems in imaging. IEEE Transactions on Image Processing 26, 4509--4522.
  16. Anisotropic total variation for limited-angle ct reconstruction, in: IEEE Nuclear Science Symposuim & Medical Imaging Conference, IEEE. pp. 2232--2238.
  17. Model-based ct reconstruction from sparse views, in: Second International Conference on Image Formation in X-Ray Computed Tomography, pp. 444--447.
  18. Deep-neural-network-based sinogram synthesis for sparse-view ct image reconstruction. IEEE Transactions on Radiation and Plasma Medical Sciences 3, 109--119.
  19. Image restoration using total variation regularized deep image prior, in: ICASSP 2019-2019 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), Ieee. pp. 7715--7719.
  20. Low-dose ct image denoising using a generative adversarial network with a hybrid loss function for noise learning. IEEE Access 8, 67519--67529.
  21. Deepred: Deep image prior powered by red, in: Proceedings of the IEEE/CVF International Conference on Computer Vision Workshops, pp. 0--0.
  22. Solving linear inverse problems using gan priors: An algorithm with provable guarantees, in: 2018 IEEE international conference on acoustics, speech and signal processing (ICASSP), IEEE. pp. 4609--4613.
  23. Low-dose ct reconstruction assisted by a global ct image manifold prior, in: 15th International Meeting on Fully Three-Dimensional Image Reconstruction in Radiology and Nuclear Medicine, International Society for Optics and Photonics. p. 1107205.
  24. Gram filtering and sinogram interpolation for pixel-basis in parallel-beam x-ray ct reconstruction, in: 2020 IEEE 17th International Symposium on Biomedical Imaging (ISBI), IEEE. pp. 624--628.
  25. Exact gram filtering and efficient backprojection for iterative ct reconstruction. Medical Physics 49, 3080--3092.
  26. Sparse-view and limited-angle ct reconstruction with untrained networks and deep image prior. Computer Methods and Programs in Biomedicine 226, 107167. URL: https://www.sciencedirect.com/science/article/pii/S016926072200548X, doi:https://doi.org/10.1016/j.cmpb.2022.107167.
  27. Accurate image reconstruction from few-views and limited-angle data in divergent-beam ct. Journal of X-ray Science and Technology 14, 119--139.
  28. Image reconstruction in circular cone-beam computed tomography by constrained, total-variation minimization. Physics in Medicine & Biology 53, 4777.
  29. Deep image prior, in: Proceedings of the IEEE conference on computer vision and pattern recognition, pp. 9446--9454.
  30. The astra toolbox: A platform for advanced algorithm development in electron tomography. Ultramicroscopy 157, 35--47.
  31. Off-the-shelf convolutional neural network features for pulmonary nodule detection in computed tomography scans, in: 2015 IEEE 12th International symposium on biomedical imaging (ISBI), IEEE. pp. 286--289.
  32. Compressed sensing with deep image prior and learned regularization. arXiv:1806.06438.
  33. Image reconstruction is a new frontier of machine learning. IEEE transactions on medical imaging 37, 1289--1296.
  34. Reweighted anisotropic total variation minimization for limited-angle ct reconstruction. IEEE Transactions on Nuclear Science 64, 2742--2760.
  35. The evolution of image reconstruction for ct?from filtered back projection to artificial intelligence. European radiology 29, 2185--2195.
  36. Deep efficient end-to-end reconstruction (deer) network for few-view breast ct image reconstruction. IEEE Access 8, 196633--196646.
  37. Deep back projection for sparse-view ct reconstruction, in: 2018 IEEE Global Conference on Signal and Information Processing (GlobalSIP), IEEE. pp. 1--5.
  38. Domain progressive 3d residual convolution network to improve low-dose ct imaging. IEEE transactions on medical imaging 38, 2903--2913.
  39. Image prediction for limited-angle tomography via deep learning with convolutional neural network. arXiv:1607.08707.
  40. A convolutional forward and back-projection model for fan-beam geometry. arXiv preprint arXiv:1907.10526 .
  41. Pet image reconstruction using a cascading back-projection neural network. IEEE Journal of Selected Topics in Signal Processing 14, 1100--1111.
  42. Gaussian mixture markov random field for image denoising and reconstruction, in: 2013 IEEE Global Conference on Signal and Information Processing, IEEE. pp. 1089--1092.
  43. Clear: comprehensive learning enabled adversarial reconstruction for subtle structure enhanced low-dose ct imaging. IEEE Transactions on Medical Imaging 40, 3089--3101.
  44. Road extraction by deep residual u-net. IEEE Geoscience and Remote Sensing Letters 15, 749--753.
  45. Unet++: A nested u-net architecture for medical image segmentation, in: Deep learning in medical image analysis and multimodal learning for clinical decision support. Springer, pp. 3--11.
  46. Image reconstruction by domain-transform manifold learning. Nature 555, 487--492.
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