Abstract
Magnetic resonance (MR) imaging plays a highly important role in radiotherapy treatment planning for the segmentation of tumor volumes and organs. However, the use of MR is limited, owing to its high cost and the increased use of metal implants for patients. This study is aimed towards patients who are contraindicated owing to claustrophobia and cardiac pacemakers, and many scenarios in which only computed tomography (CT) images are available, such as emergencies, situations lacking an MR scanner, and situations in which the cost of obtaining an MR scan is prohibitive. From medical practice, our approach can be adopted as a screening method by radiologists to observe abnormal anatomical lesions in certain diseases that are difficult to diagnose by CT. The proposed approach can estimate an MR image based on a CT image using paired and unpaired training data. In contrast to existing synthetic methods for medical imaging, which depend on sparse pairwise-aligned data or plentiful unpaired data, the proposed approach alleviates the rigid registration of paired training, and overcomes the context-misalignment problem of unpaired training. A generative adversarial network was trained to transform two-dimensional (2D) brain CT image slices into 2D brain MR image slices, combining the adversarial, dual cycle-consistent, and voxel-wise losses. Qualitative and quantitative comparisons against independent paired and unpaired training methods demonstrated the superiority of our approach.
Highlights
Computed tomography (CT)-based radiotherapy [1] is currently used in radiotherapy planning and is reasonably effective
We propose a synthetic method based on generative adversarial networks (GANs) [4] which is a type of convolutional neural network (CNN) [5]
Results from the test set demonstrate that Magnetic resonance (MR)-GAN is much closer to the reference MR images when compared with the other methods
Summary
Computed tomography (CT)-based radiotherapy [1] is currently used in radiotherapy planning and is reasonably effective. Magnetic resonance (MR) imaging delivers superior contrast of soft tissue compared with the CT scans [2]; radiotherapy devices using MR imaging [3]. MR imaging is excellent for detecting very slight differences in soft tissues, ligaments, or organs. Compared with CT scans, MR imaging is much more expensive and takes about six times longer: for example, for an MR imaging that takes about 30 min, the CT scan can be completed within 5 min. While the procedure for MR imaging is contraindicated for Sensors 2019, 19, 2361; doi:10.3390/s19102361 www.mdpi.com/journal/sensors. Sensors 2019, 19, 2361 some patients due to claustrophobia, cardiac pacemakers, and artificial joints. Some patients cannot afford or do not have access to MR imaging due to the high cost
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