Litcius/Paper detail

Unpaired Deep Learning for Accelerated MRI Using Optimal Transport Driven CycleGAN

Gyutaek Oh, Byeongsu Sim, Hyungjin Chung, Leonard Sunwoo, Jong Chul Ye

2020IEEE Transactions on Computational Imaging85 citationsDOI

Abstract

Recently, deep learning approaches for accelerated MRI have been extensively studied thanks to their high performance reconstruction in spite of significantly reduced run-time complexity. These neural networks are usually trained in a supervised manner, so matched pairs of subsampled, and fully sampled k-space data are required. Unfortunately, it is often difficult to acquire matched fully sampled k-space data, since the acquisition of fully sampled k-space data requires long scan time, and often leads to the change of the acquisition protocol. Therefore, unpaired deep learning without matched label data has become a very important research topic. In this article, we propose an unpaired deep learning approach using a optimal transport driven cycle-consistent generative adversarial network (OT-cycleGAN) that employs a single pair of generator, and discriminator. The proposed OT-cycleGAN architecture is rigorously derived from a dual formulation of the optimal transport formulation using a specially designed penalized least squares cost. The experimental results show that our method can reconstruct high resolution MR images from accelerated k-space data from both single, and multiple coil acquisition, without requiring matched reference data.

Topics & Concepts

DiscriminatorComputer scienceArtificial intelligenceDeep learningArtificial neural networkGenerator (circuit theory)Data acquisitionIterative reconstructionPattern recognition (psychology)DetectorOperating systemQuantum mechanicsPhysicsTelecommunicationsPower (physics)Advanced MRI Techniques and ApplicationsMedical Imaging Techniques and ApplicationsAdvanced Neuroimaging Techniques and Applications