Recovering from missing data in population imaging – Cardiac MR image imputation via conditional generative adversarial nets

Accurate ventricular volume measurements are the primary indicators of normal/abnor- mal cardiac function and are dependent on the Cardiac Magnetic Resonance (CMR) volumes being complete. However, missing or unusable slices owing to the presence of image artefacts such as respiratory or motion ghosting, aliasing, ringing and signal loss in CMR sequences, significantly hinder accuracy of anatomical and functional cardiac quantification, and recovering from those is insufficiently addressed in population imaging. In this work, we propose a new robust approach, coined Image Imputation Generative Adversarial Network (I2-GAN), to learn key features of cardiac short axis (SAX) slices near missing information, and use them as conditional variables to infer missing slices in the query volumes. In I2-GAN, the slices are first mapped to latent vectors with position features through a regression net. The latent vector corresponding to the desired position is then projected onto the slice manifold, conditioned on intensity features through a generator net. The generator comprises residual blocks with normalisation layers that are modulated with auxiliary slice information, enabling propagation of fine details through the network. In addition, a multi-scale discriminator was implemented, along with a discriminator-based feature matching loss, to further enhance performance and encourage the synthesis of visually realistic slices. Experimental results show that our method achieves significant improvements over the state-of-the-art, in missing slice imputation for CMR, with an average SSIM of 0.872. Linear regression analysis yields good agreement between reference and imputed CMR images for all cardiac measurements, with correlation coefficients of 0.991 for left ventricular volume, 0.977 for left ventricular mass and 0.961 for right ventricular volume.

Cardiac MRI, Conditional batch normalisation, Conditional generative adversarial net, Data imputation, Deep learning, Multi-scale discriminator

10.1016/j.media.2020.101812

1361-8415

Xia, Yan

e6c0b611-427b-4871-86f1-406efee13bb5

Zhang, Le

1dc1ba6f-92bc-46cc-a73f-a16f21fb8e54

Ravikumar, Nishant

e31cd3f7-b112-4078-b5fc-0cfc005a061a

Attar, Rahman

f5efd538-042a-4647-9d46-1370d3049b72

Piechnik, Stefan K.

7de3d548-ca5a-40cb-a52b-c53d2dd2278a

Neubauer, Stefan

c8a34156-a4ed-4dfe-97cb-4f47627d927d

Petersen, Steffen E.

04f2ce88-790d-48dc-baac-cbe0946dd928

Frangi, Alejandro F.

35127be7-3586-4fff-a4a2-bb79cc228141

1 January 2021

Xia, Yan

e6c0b611-427b-4871-86f1-406efee13bb5

Zhang, Le

1dc1ba6f-92bc-46cc-a73f-a16f21fb8e54

Ravikumar, Nishant

e31cd3f7-b112-4078-b5fc-0cfc005a061a

Attar, Rahman

f5efd538-042a-4647-9d46-1370d3049b72

Piechnik, Stefan K.

7de3d548-ca5a-40cb-a52b-c53d2dd2278a

Neubauer, Stefan

c8a34156-a4ed-4dfe-97cb-4f47627d927d

Petersen, Steffen E.

04f2ce88-790d-48dc-baac-cbe0946dd928

Frangi, Alejandro F.

35127be7-3586-4fff-a4a2-bb79cc228141

Xia, Yan, Zhang, Le, Ravikumar, Nishant, Attar, Rahman, Piechnik, Stefan K., Neubauer, Stefan, Petersen, Steffen E. and Frangi, Alejandro F. (2021) Recovering from missing data in population imaging – Cardiac MR image imputation via conditional generative adversarial nets. Medical Image Analysis, 67, [101812]. (doi:10.1016/j.media.2020.101812).

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Accepted/In Press date: 19 August 2020

e-pub ahead of print date: 2 October 2020

Published date: 1 January 2021

Additional Information: Funding Information: This research has been conducted using the UK Biobank Resource under Applications 11,350 and 2964. The CMR images presented in Figs. 1 ,2, 4, 5, 7–9 and 15 in the manuscript were reproduced with the permission of UK Biobank©. The authors are grateful to all UK Biobank participants and staff. AFF acknowledges support from the Royal Academy of Engineering Chair in Emerging Technologies Scheme (CiET1819/19), EPSRC-funded Grow MedTech CardioX (POC041), and the MedIAN Network (EP/N026993/1) funded by the Engineering and Physical Sciences Research Council (EPSRC). SKP and SN acknowledge the National Institute for Health Research (NIHR) Oxford Biomedical Research Centre based at The Oxford University Hospitals Trust at the University of Oxford, and the British Heart Foundation Centre of Research Excellence. SEP acknowledges support from the NIHR Barts Biomedical Research Centre and from the SmartHeart EPSRC Programme Grant (EP/P0010 09/1). Funding Information: This research has been conducted using the UK Biobank Resource under Applications 11,350 and 2964. The CMR images presented in Figs. 1,2, 4, 5, 7?9 and 15 in the manuscript were reproduced with the permission of UK Biobank?. The authors are grateful to all UK Biobank participants and staff. AFF acknowledges support from the Royal Academy of Engineering Chair in Emerging Technologies Scheme (CiET1819/19), EPSRC-funded Grow MedTech CardioX (POC041), and the MedIAN Network (EP/N026993/1) funded by the Engineering and Physical Sciences Research Council (EPSRC). SKP and SN acknowledge the National Institute for Health Research (NIHR) Oxford Biomedical Research Centre based at The Oxford University Hospitals Trust at the University of Oxford, and the British Heart Foundation Centre of Research Excellence. SEP acknowledges support from the NIHR Barts Biomedical Research Centre and from the SmartHeart EPSRC Programme Grant (EP/P0010 09/1). Publisher Copyright: © 2020 The Authors

Keywords: Cardiac MRI, Conditional batch normalisation, Conditional generative adversarial net, Data imputation, Deep learning, Multi-scale discriminator

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