Research ArticleOpen Access

Arbitrary Scale Super-Resolution for Medical Images

Jin Zhu

Department of Computer Science and Technology, University of Cambridge, Cambridge, CB3 0FD, UK

E-mail Address: jin.zhu@cl.cam.ac.uk

Corresponding author.

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Chuan Tan

Department of Computer Science and Technology, University of Cambridge, Cambridge, CB3 0FD, UK

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Junwei Yang

Department of Computer Science and Technology, University of Cambridge, Cambridge, CB3 0FD, UK

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Guang Yang

Cardiovascular Research Centre, Royal Brompton Hospital, London, SW3 6NP, UK

National Heart and Lung Institute, Imperial College London, London, SW7 2AZ, UK

E-mail Address: g.yang@imperial.ac.uk

Corresponding author.

Guang Yang and Pietro Lio’ are senior and last co-authors contributed equally for this study.

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, and

Pietro Lio’

Department of Computer Science and Technology, University of Cambridge, Cambridge, CB3 0FD, UK

Guang Yang and Pietro Lio’ are senior and last co-authors contributed equally for this study.

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https://doi.org/10.1142/S0129065721500374Cited by:36 (Source: Crossref)

Abstract

Single image super-resolution (SISR) aims to obtain a high-resolution output from one low-resolution image. Currently, deep learning-based SISR approaches have been widely discussed in medical image processing, because of their potential to achieve high-quality, high spatial resolution images without the cost of additional scans. However, most existing methods are designed for scale-specific SR tasks and are unable to generalize over magnification scales. In this paper, we propose an approach for medical image arbitrary-scale super-resolution (MIASSR), in which we couple meta-learning with generative adversarial networks (GANs) to super-resolve medical images at any scale of magnification in $(1, 4]$ . Compared to state-of-the-art SISR algorithms on single-modal magnetic resonance (MR) brain images (OASIS-brains) and multi-modal MR brain images (BraTS), MIASSR achieves comparable fidelity performance and the best perceptual quality with the smallest model size. We also employ transfer learning to enable MIASSR to tackle SR tasks of new medical modalities, such as cardiac MR images (ACDC) and chest computed tomography images (COVID-CT). The source code of our work is also public. Thus, MIASSR has the potential to become a new foundational pre-/post-processing step in clinical image analysis tasks such as reconstruction, image quality enhancement, and segmentation.

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References

1. G. Mirzaei, A. Adeli and H. Adeli , Imaging and machine learning techniques for diagnosis of alzheimer’s disease, Rev. Neurosci. 27(8) (2016) 857–870. Crossref, Medline, Web of Science, Google Scholar
2. G. Mirzaei and H. Adeli , Resting state functional magnetic resonance imaging processing techniques in stroke studies, Rev. Neurosci. 27(8) (2016) 871–885. Crossref, Medline, Web of Science, Google Scholar
3. M. Leming, J. M. Górriz and J. Suckling , Ensemble deep learning on large, mixed-site FMRI datasets in autism and other tasks, Int. J. Neural Syst. 30(7) (2020) 2050012. Link, Web of Science, Google Scholar
4. D. Castillo-Barnes, F. J. Martinez-Murcia, A. Ortiz, D. Salas-Gonzalez, J. RamÍrez and J. M. Górriz , Morphological characterization of functional brain imaging by isosurface analysis in Parkinson’s disease, Int. J. Neural Syst. 30(9) (2020) 2050044. Link, Web of Science, Google Scholar
5. Y. Li, B. Sixou and F. Peyrin , A review of the deep learning methods for medical images super resolution problems, IRBM 42 (2020) 120–133. Crossref, Web of Science, Google Scholar
6. L. Schermelleh, R. Heintzmann and H. Leonhardt , A guide to super-resolution fluorescence microscopy, J. Cell Biol. 190(2) (2010) 165–175. Crossref, Medline, Web of Science, Google Scholar
7. W. Yang, X. Zhang, Y. Tian, W. Wang, J.-H. Xue and Q. Liao , Deep learning for single image super-resolution: A brief review, IEEE Trans. Multimedia 21 (2019) 3106–3121. Crossref, Web of Science, Google Scholar
8. Z. Wang, J. Chen and S. C. Hoi , Deep learning for image super-resolution: A survey, IEEE Trans. Pattern Anal. Mach. Intell. (2020), https://doi.org/10.1109/TPAMI.2020.2982166. Web of Science, Google Scholar
9. X. Wang and W. Q. Yan , Human gait recognition based on frame-by-frame gait energy images and convolutional long short-term memory, Int. J. Neural Syst. 30(1) (2020) 1950027. Link, Web of Science, Google Scholar
10. P. Mishra, C. Piciarelli and G. L. Foresti , A neural network for image anomaly detection with deep pyramidal representations and dynamic routing, Int. J. Neural Syst. 30(10) (2020) 2050060. Link, Web of Science, Google Scholar
11. J. Zhu, G. Yang and P. Lio, Lesion focused super-resolution, arXiv:1810.06693. Google Scholar
12. J. Zhu, G. Yang and P. Lio , How can we make GAN perform better in single medical image super-resolution? a lesion focused multi-scale approach, 2019 IEEE 16th Int. Symp. Biomedical Imaging (ISBI 2019) (IEEE, 2019). Crossref, Google Scholar
13. C. You, G. Li, Y. Zhang, X. Zhang, H. Shan, M. Li, S. Ju, Z. Zhao, Z. Zhang, W. Cong et al., CT super-resolution GAN constrained by the identical, residual, and cycle learning ensemble (GAN-circle), IEEE Trans. Med. Imaging 39(1) (2019) 188–203. Crossref, Medline, Web of Science, Google Scholar
14. J. Park, D. Hwang, K. Y. Kim, S. K. Kang, Y. K. Kim and J. S. Lee , Computed tomography super-resolution using deep convolutional neural network, Phys. Med. Biol. 63(14) (2018) 145011. Crossref, Medline, Web of Science, Google Scholar
15. R. Keys , Cubic convolution interpolation for digital image processing, IEEE Trans. Acoust. Speech Signal Process. 29(6) (1981) 1153–1160. Crossref, Google Scholar
16. H. Ji and C. Fermüller , Wavelet-based super-resolution reconstruction: Theory and algorithm, Computer Vision – ECCV 2006 (Springer, Berlin Heidelberg, Berlin, Heidelberg, 2006), pp. 295–307. Crossref, Google Scholar
17. R. Timofte, V. De Smet and L. Van Gool , A+: Adjusted anchored neighborhood regression for fast super-resolution, Asian Conf. Computer Vision, (Springer International Publishing, 2014), pp. 111–126. Google Scholar
18. R. Zeyde, M. Elad and M. Protter , On single image scale-up using sparse-representations, Int. Conf. Curves and Surfaces (Springer Berlin Heidelberg, 2010), pp. 711–730. Google Scholar
19. C. Dong, C. C. Loy, K. He and X. Tang , Image super-resolution using deep convolutional networks, IEEE Trans. Pattern Anal. Mach. Intell. 38(2) (2015) 295–307. Crossref, Web of Science, Google Scholar
20. K. He, X. Zhang, S. Ren and J. Sun, Deep residual learning for image recognition, arXiv:1512.03385. Google Scholar
21. J. Kim, J. Kwon Lee and K. Mu Lee , Accurate image super-resolution using very deep convolutional networks, in Proc. IEEE Conf. Computer Vision and Pattern Recognition (IEEE, 2016), pp. 1646–1654. Crossref, Google Scholar
22. M. D. Zeiler and R. Fergus, Visualizing and understanding convolutional networks, arXiv:1311.2901. Google Scholar
23. W. Shi, J. Caballero, F. Huszar, J. Totz, A. P. Aitken, R. Bishop, D. Rueckert and Z. Wang, Real-time single image and video super-resolution using an efficient sub-pixel convolutional neural network, arXiv:1609.05158. Google Scholar
24. T. Tong, G. Li, X. Liu and Q. Gao , Image super-resolution using dense skip connections, in Proc. IEEE Int. Conf. Computer Vision (IEEE, 2017), pp. 4799–4807. Crossref, Google Scholar
25. Y. Zhang, Y. Tian, Y. Kong, B. Zhong and Y. Fu , Residual dense network for image super-resolution, in Proc. IEEE Conf. Computer Vision and Pattern Recognition (IEEE, 2018), pp. 2472–2481. Crossref, Google Scholar
26. C. Ledig, L. Theis, F. Huszar, J. Caballero, A. Cunningham, A. Acosta, A. Aitken, A. Tejani, J. Totz, Z. Wang and W. Shi, Photo-realistic single image super-resolution using a generative adversarial network, arXiv:1609.04802. Google Scholar
27. K. Simonyan and A. Zisserman, Very deep convolutional networks for large-scale image recognition, arXiv:1409.1556. Google Scholar
28. J. Johnson, A. Alahi and L. Fei-Fei, Perceptual losses for real-time style transfer and super-resolution, arXiv:1603.08155. Google Scholar
29. I. J. Goodfellow, J. Pouget-Abadie, M. Mirza, B. Xu, D. Warde-Farley, S. Ozair, A. Courville and Y. Bengio, Generative adversarial networks, arXiv:1406.2661. Google Scholar
30. X. Wang, K. Yu, S. Wu, J. Gu, Y. Liu, C. Dong, Y. Qiao and C. Change Loy , ESRGAN: Enhanced super-resolution generative adversarial networks, in Proc. European Conf. Computer Vision (ECCV), (Springer Science Business Media, 2018). Google Scholar
31. A. Jolicoeur-Martineau, The relativistic discriminator: A key element missing from standard GAN, arXiv:1807.00734. Google Scholar
32. Y. Zhang, K. Li, K. Li, L. Wang, B. Zhong and Y. Fu, Image super-resolution using very deep residual channel attention networks, arXiv:1807.02758. Google Scholar
33. A. Shocher, N. Cohen and M. Irani, “zero-shot” super-resolution using deep internal learning, arXiv:1712.06087. Google Scholar
34. M. Haris, G. Shakhnarovich and N. Ukita, Deep back-projection networks for super-resolution, arXiv:1803.02735. Google Scholar
35. X. Hu, H. Mu, X. Zhang, Z. Wang, T. Tan and J. Sun , Meta-SR: A magnification-arbitrary network for super-resolution, in Proc. IEEE Conf. Computer Vision and Pattern Recognition (IEEE, 2019), pp. 1575–1584. Crossref, Google Scholar
36. O. Ronneberger, P. Fischer and T. Brox, U-net: Convolutional networks for biomedical image segmentation, arXiv:1505.04597. Google Scholar
37. J.-Y. Zhu, T. Park, P. Isola and A. A. Efros, Unpaired image-to-image translation using cycle-consistent adversarial networks, arXiv:1703.10593. Google Scholar
38. Y. Chen, F. Shi, A. G. Christodoulou, Z. Zhou, Y. Xie and D. Li, Efficient and accurate MRI super-resolution using a generative adversarial network and 3D multi-level densely connected network, arXiv:1803.01417. Google Scholar
39. O. Oktay, E. Ferrante, K. Kamnitsas, M. Heinrich, W. Bai, J. Caballero, S. A. Cook, A. De Marvao, T. Dawes, D. P. O’Regan et al., Anatomically constrained neural networks (ACNNS): Application to cardiac image enhancement and segmentation, IEEE Trans. Med. Imaging 37(2) (2017) 384–395. Crossref, Medline, Web of Science, Google Scholar
40. B. Lim, S. Son, H. Kim, S. Nah and K. M. Lee, Enhanced deep residual networks for single image super-resolution, arXiv:1707.02921. Google Scholar
41. M. Arjovsky, S. Chintala and L. Bottou, Wasserstein GAN, arXiv:1701.07875. Google Scholar
42. I. Gulrajani, F. Ahmed, M. Arjovsky, V. Dumoulin and A. C. Courville , Improved training of Wasserstein GANs, Adv. Neural Inf. Process. Syst. 30 (2017) 5767–5777. Google Scholar
43. M. Heusel, H. Ramsauer, T. Unterthiner, B. Nessler and S. Hochreiter, GANs trained by a two time-scale update rule converge to a local nash equilibrium, arXiv:1706.08500. Google Scholar
44. D. S. Marcus, T. H. Wang, J. Parker, J. G. Csernansky, J. C. Morris and R. L. Buckner , Open access series of imaging studies (OASIS): Cross-sectional MRI data in young, middle aged, nondemented, and demented older adults, J. Cognit. Neurosci. 19(9) (2007) 1498–1507. Crossref, Medline, Web of Science, Google Scholar
45. B. H. Menze, A. Jakab, S. Bauer, J. Kalpathy-Cramer, K. Farahani, J. Kirby et al., The multimodal brain tumor image segmentation benchmark (BRATS), IEEE Trans. Med. Imaging 34 (2015) 1993–2024. Crossref, Medline, Web of Science, Google Scholar
46. S. Bakas, H. Akbari, A. Sotiras, M. Bilello, M. Rozycki, J. Kirby et al., Advancing the cancer genome atlas glioma MRI collections with expert segmentation labels and radiomic features, Sci. Data 4 (2017) 170117. Crossref, Medline, Web of Science, Google Scholar
47. S. Bakas, M. Reyes, A. Jakab, S. Bauer, M. Rempfler, A. Crimi et al., Identifying the best machine learning algorithms for brain tumor segmentation, progression assessment, and overall survival prediction in the BRATS challenge, arXiv:1811.02629. Google Scholar
48. O. Bernard, A. Lalande, C. Zotti, F. Cervenansky, X. Yang, P.-A. Heng, I. Cetin, K. Lekadir, O. Camara, M. A. G. Ballester et al., Deep learning techniques for automatic MRI cardiac multi-structures segmentation and diagnosis: Is the problem solved?, IEEE Trans. Medical Imaging 37(11) (2018) 2514–2525. Crossref, Medline, Web of Science, Google Scholar
49. P. An, S. Xu, S. Harmon, E. Turkbey, T. Sanford, A. Amalou, M. Kassin, N. Varble, M. Blain, V. Anderson, F. Patella, G. Carrafiello, B. Turkbey and B. Wood , CT images in COVID-19 [data set], Cancer Imaging Arch. (2020), https://doi.org/10.7937/TCIA.2020.GQRY-NC81. Google Scholar
50. C. Szegedy, V. Vanhoucke, S. Ioffe, J. Shlens and Z. Wojna, Rethinking the inception architecture for computer vision, arXiv:1512.00567. Google Scholar
51. Y. Blau and T. Michaeli , The perception-distortion tradeoff, 2018 IEEE/CVF Conf. Computer Vision and Pattern Recognition (IEEE, 2018). Crossref, Google Scholar
52. A. Radford, L. Metz and S. Chintala, Unsupervised representation learning with deep convolutional generative adversarial networks, arXiv:1511.06434. Google Scholar
53. K. He, X. Zhang, S. Ren and J. Sun, Delving deep into rectifiers: Surpassing human-level performance on imagenet classification, arXiv:1502.01852. Google Scholar
54. D. P. Kingma and J. Ba, Adam: A method for stochastic optimization, arXiv:1412.6980. Google Scholar
55. S. Bell, P. Upchurch, N. Snavely and K. Bala, Material recognition in the wild with the materials in context database, arXiv:1412.0623. Google Scholar
56. M. Chessa and F. Solari , A computational model for the neural representation and estimation of the binocular vector disparity from convergent stereo image pairs, Int. J. Neural Syst. 29(5) (2019) 1850029. Link, Web of Science, Google Scholar
57. P. Gaur, K. McCreadie, R. B. Pachori, H. Wang and G. Prasad , Tangent space features-based transfer learning classification model for two-class motor imagery brain–computer interface, Int. J. Neural Syst. 29(10) (2019) 1950025. Link, Web of Science, Google Scholar
58. S. Ioffe and C. Szegedy, Batch normalization: Accelerating deep network training by reducing internal covariate shift, arXiv:1502.03167. Google Scholar
59. A. Ortiz, J. Munilla, F. J. Martínez-Murcia, J. M. Górriz and J. Ramírez , Empirical functional PCA for 3D image feature extraction through fractal sampling, Int. J. Neural Syst. 29(2) (2019) 1850040. Link, Web of Science, Google Scholar
60. Y. Liang, F. He and X. Zeng , 3D mesh simplification with feature preservation based on whale optimization algorithm and differential evolution, Integr. Comput.-Aided Eng. 27 (2020) 1–19. Crossref, Web of Science, Google Scholar
61. Y. Wu, F. He, D. Zhang and X. Li , Service-oriented feature-based data exchange for cloud-based design and manufacturing, IEEE Trans. Serv. Comput. 11(2) (2015) 341–353. Crossref, Web of Science, Google Scholar
62. O. M. Manzanera, S. K. Meles, K. L. Leenders, R. J. Renken, M. Pagani, D. Arnaldi, F. Nobili, J. Obeso, M. R. Oroz, S. Morbelli et al., Scaled subprofile modeling and convolutional neural networks for the identification of Parkinson’s disease in 3D nuclear imaging data, Int. J. Neural Syst. 29(9) (2019) 1950010. Link, Web of Science, Google Scholar

Vol. 31, No. 10

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History

Received 11 June 2021

Accepted 12 June 2021

Published: 24 July 2021

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This is an Open Access article published by World Scientific Publishing Company. It is distributed under the terms of the Creative Commons Attribution 4.0 (CC BY) License which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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Arbitrary Scale Super-Resolution for Medical Images

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