Deep learning-based MR-to-CT synthesis: The influence of varying gradient echo-based MR images as input channels

Publication date

2020-04

Authors

Florkow, Mateusz C
Zijlstra, Frank
Willemsen, K.ORCID 0000-0002-8237-6321
Maspero, MatteoORCID 0000-0003-0347-3375
van den Berg, CATORCID 0000-0002-5565-6889
Kerkmeijer, Linda G WISNI 0000000393809169
Castelein, RMISNI 0000000392339484
Weinans, HarrieORCID 0000-0002-2275-6170ISNI 0000000393288658
Viergever, MaxORCID 0000-0003-2582-042XISNI 0000000117491940
van Stralen, MORCID 0000-0002-3051-5000ISNI 0000000395962765

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Abstract

PURPOSE: To study the influence of gradient echo-based contrasts as input channels to a 3D patch-based neural network trained for synthetic CT (sCT) generation in canine and human populations. METHODS: Magnetic resonance images and CT scans of human and canine pelvic regions were acquired and paired using nonrigid registration. Magnitude MR images and Dixon reconstructed water, fat, in-phase and opposed-phase images were obtained from a single T1 -weighted multi-echo gradient-echo acquisition. From this set, 6 input configurations were defined, each containing 1 to 4 MR images regarded as input channels. For each configuration, a UNet-derived deep learning model was trained for synthetic CT generation. Reconstructed Hounsfield unit maps were evaluated with peak SNR, mean absolute error, and mean error. Dice similarity coefficient and surface distance maps assessed the geometric fidelity of bones. Repeatability was estimated by replicating the training up to 10 times. RESULTS: Seventeen canines and 23 human subjects were included in the study. Performance and repeatability of single-channel models were dependent on the TE-related water-fat interference with variations of up to 17% in mean absolute error, and variations of up to 28% specifically in bones. Repeatability, Dice similarity coefficient, and mean absolute error were statistically significantly better in multichannel models with mean absolute error ranging from 33 to 40 Hounsfield units in humans and from 35 to 47 Hounsfield units in canines. CONCLUSION: Significant differences in performance and robustness of deep learning models for synthetic CT generation were observed depending on the input. In-phase images outperformed opposed-phase images, and Dixon reconstructed multichannel inputs outperformed single-channel inputs.

Keywords

deep learning, gradient echo, MR contrasts, synthetic CT, Radiology Nuclear Medicine and imaging, Journal Article

Citation

Florkow, M C, Zijlstra, F, Willemsen, K, Maspero, M, van den Berg, C A T, Kerkmeijer, L G W, Castelein, R M, Weinans, H, Viergever, M A, van Stralen, M & Seevinck, P R 2020, 'Deep learning-based MR-to-CT synthesis : The influence of varying gradient echo-based MR images as input channels', Magnetic Resonance in Medicine, vol. 83, no. 4, pp. 1429-1441. https://doi.org/10.1002/mrm.28008