Papers
Topics
Authors
Recent
Search
2000 character limit reached

Equivariant Multiscale Learned Invertible Reconstruction for Cone Beam CT

Published 20 Jan 2024 in physics.med-ph and cs.CV | (2401.11256v1)

Abstract: Cone Beam CT (CBCT) is an essential imaging modality nowadays, but the image quality of CBCT still lags behind the high quality standards established by the conventional Computed Tomography. We propose LIRE+, a learned iterative scheme for fast and memory-efficient CBCT reconstruction, which is a substantially faster and more parameter-efficient alternative to the recently proposed LIRE method. LIRE+ is a rotationally-equivariant multiscale learned invertible primal-dual iterative scheme for CBCT reconstruction. Memory usage is optimized by relying on simple reversible residual networks in primal/dual cells and patch-wise computations inside the cells during forward and backward passes, while increased inference speed is achieved by making the primal-dual scheme multiscale so that the reconstruction process starts at low resolution and with low resolution primal/dual latent vectors. A LIRE+ model was trained and validated on a set of 260 + 22 thorax CT scans and tested using a set of 142 thorax CT scans with additional evaluation with and without finetuning on an out-of-distribution set of 79 Head and Neck (HN) CT scans. Our method surpasses classical and deep learning baselines, including LIRE, on the thorax test set. For a similar inference time and with only 37 % of the parameter budget, LIRE+ achieves a +0.2 dB PSNR improvement over LIRE, while being able to match the performance of LIRE in 45 % less inference time and with 28 % of the parameter budget. Rotational equivariance ensures robustness of LIRE+ to patient orientation, while LIRE and other deep learning baselines suffer from substantial performance degradation when patient orientation is unusual. On the HN dataset in the absence of finetuning, LIRE+ is generally comparable to LIRE in performance apart from a few outlier cases, whereas after identical finetuning LIRE+ demonstates a +1.02 dB PSNR improvement over LIRE.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (33)
  1. Cone-beam-CT guided radiation therapy: technical implementation, Radiother Oncol 75, 279–286 (2005).
  2. C-arm cone-beam computed tomography in interventional oncology: technical aspects and clinical applications, La Radiologia medica 119, 521–532 (2014).
  3. Cone beam CT in dental practice, Br Dent J 207, 23–28 (2009).
  4. Flat-panel cone-beam computed tomography for image-guided radiation therapy, Int J Radiat Oncol Biol Phys 53, 1337–1349 (2002).
  5. Comparing short scan CT reconstruction algorithms regarding cone-beam artifact performance, in IEEE Nuclear Science Symposuim Medical Imaging Conference, pages 2188–2193, 2010.
  6. H. K. Tuy, An Inversion Formula for Cone-Beam Reconstruction, SIAM Journal on Applied Mathematics 43, 546–552 (1983).
  7. Adaptive Radiotherapy for Anatomical Changes, Semin Radiat Oncol 29, 245–257 (2019).
  8. M. J. Muckley et al., Results of the 2020 fastMRI Challenge for Machine Learning MR Image Reconstruction, arXiv e-prints , arXiv:2012.06318 (2020).
  9. Multi-channel MR Reconstruction (MC-MRRec) Challenge – Comparing Accelerated MR Reconstruction Models and Assessing Their Genereralizability to Datasets Collected with Different Coils, 2020.
  10. Deep Convolutional Neural Network for Inverse Problems in Imaging, IEEE Transactions on Image Processing 26, 4509–4522 (2017).
  11. CycN-Net: A Convolutional Neural Network Specialized for 4D CBCT Images Refinement, IEEE Transactions on Medical Imaging 40, 3054–3064 (2021).
  12. J. Adler and O. Öktem, Learned Primal-Dual Reconstruction, IEEE Transactions on Medical Imaging 37, 1322–1332 (2018).
  13. A. Chambolle and T. Pock, A First-Order Primal-Dual Algorithm for Convex Problems with Applications to Imaging, J. Math. Imaging Vis. 40, 120–145 (2011).
  14. Deep learning reconstruction of digital breast tomosynthesis images for accurate breast density and patient-specific radiation dose estimation, Medical Image Analysis 71, 102061 (2021).
  15. Benchmarking MRI Reconstruction Neural Networks on Large Public Datasets, Applied Sciences (2020), A short version of this work has been accepted to the 17th International Symposium on Biomedical Imaging (ISBI 2020), April 3-7 2020, Iowa City, IO, USA.
  16. AirNet: Fused analytical and iterative reconstruction with deep neural network regularization for sparse-data CT, Medical Physics 47, 2916–2930 (2020).
  17. Recurrent Variational Network: A Deep Learning Inverse Problem Solver Applied to the Task of Accelerated MRI Reconstruction, in Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), pages 732–741, 2022.
  18. Multi-Scale Learned Iterative Reconstruction, IEEE Transactions on Computational Imaging 6, 843–856 (2020).
  19. Invertible Learned Primal-Dual, 2021.
  20. 3D helical CT reconstruction with memory efficient invertible Learned Primal-Dual method, 2022.
  21. End-to-end memory-efficient reconstruction for cone beam CT, Medical Physics 50, 7579–7593 (2023).
  22. D. P. Kingma and P. Dhariwal, Glow: Generative Flow with Invertible 1x1 Convolutions, in Advances in Neural Information Processing Systems, edited by S. Bengio, H. Wallach, H. Larochelle, K. Grauman, N. Cesa-Bianchi, and R. Garnett, volume 31, Curran Associates, Inc., 2018.
  23. T. Cohen and M. Welling, Group Equivariant Convolutional Networks, in Proceedings of The 33rd International Conference on Machine Learning, edited by M. F. Balcan and K. Q. Weinberger, volume 48 of Proceedings of Machine Learning Research, pages 2990–2999, New York, New York, USA, 2016, PMLR.
  24. Equivariant neural networks for inverse problems, Inverse Problems 37, 085006 (2021).
  25. J. Kaipio and E. Somersalo, Statistical and Computational Inverse Problems, volume 160 of Applied Mathematical Sciences, Springer-Verlag, New York, 2005.
  26. Practical cone-beam algorithm, J. Opt. Soc. Am. A 1, 612–619 (1984).
  27. 3D U-Net: Learning Dense Volumetric Segmentation from Sparse Annotation, in Medical Image Computing and Computer-Assisted Intervention – MICCAI 2016, edited by S. Ourselin, L. Joskowicz, M. R. Sabuncu, G. Unal, and W. Wells, pages 424–432, Cham, 2016, Springer International Publishing.
  28. Uformer: A General U-Shaped Transformer for Image Restoration, in Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), pages 17683–17693, 2022.
  29. Deep learning framework to improve the quality of cone-beam computed tomography for radiotherapy scenarios, Medical Physics 50, 7641–7653 (2023).
  30. A more effective CT synthesizer using transformers for cone-beam CT-guided adaptive radiotherapy, Frontiers in Oncology 12 (2022).
  31. D. P. Kingma and J. Ba, Adam: A Method for Stochastic Optimization, arXiv e-prints , arXiv:1412.6980 (2014).
  32. A. Paszke et al., PyTorch: An Imperative Style, High-Performance Deep Learning Library, in Advances in Neural Information Processing Systems 32, edited by H. Wallach, H. Larochelle, A. Beygelzimer, F. d'Alché-Buc, E. Fox, and R. Garnett, pages 8024–8035, Curran Associates, Inc., 2019.
  33. Centered Weight Normalization in Accelerating Training of Deep Neural Networks, in 2017 IEEE International Conference on Computer Vision (ICCV), pages 2822–2830, 2017.

Summary

No one has generated a summary of this paper yet.

Sign Up to Summarize

Paper to Video (Beta)

No one has generated a video about this paper yet.

Sign Up to Generate All Videos Subscribe on YouTube

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Sign Up to Generate

Open Problems

We found no open problems mentioned in this paper.

Continue Learning

We haven't generated follow-up questions for this paper yet.

Generate Now

Collections

Sign up for free to add this paper to one or more collections.

Sign Up

Tweets

Sign up for free to view the 1 tweet with 4 likes about this paper.

Sign Up for Free