Abstract
Echo planar imaging (EPI), a fast magnetic resonance imaging technique, is a powerful tool in functional neuroimaging studies. However, susceptibility artifacts, which cause misinterpretations of brain functions, are unavoidable distortions in EPI. This paper proposes an end-to-end deep learning framework, named TS-Net, for susceptibility artifact correction (SAC) in a pair of 3D EPI images with reversed phase-encoding directions. The proposed TS-Net comprises a deep convolutional network to predict a displacement field in three dimensions to overcome the limitation of existing methods, which only estimate the displacement field along the dominant-distortion direction. In the training phase, anatomical T1-weighted images are leveraged to regularize the correction, but they are not required during the inference phase to make TS-Net more flexible for general use. The experimental results show that TS-Net achieves favorable accuracy and speed trade-off when compared with the state-of-the-art SAC methods, i.e., TOPUP, TISAC, and S-Net. The fast inference speed (less than a second) of TS-Net makes real-time SAC during EPI image acquisition feasible and accelerates the medical image-processing pipelines.
Highlights
Published: 26 March 2021Echo planar imaging is a fast magnetic resonance imaging (MRI) technique that has served as an important non-invasive tool in cognitive neuroscience [1]
Echo planar imaging (EPI) is prone to susceptibility artifacts (SAs) [4,5] and eddy-current artifacts [6,7], which consist of geometric distortions
This paper presents an end-to-end 3D anatomy-guided deep learning framework, TS-Net, to correct the susceptibility artifacts in reversed phase-encoding 3D EPI image pairs
Summary
Echo planar imaging is a fast magnetic resonance imaging (MRI) technique that has served as an important non-invasive tool in cognitive neuroscience [1]. EPI is widely used to record the functional magnetic resonance imaging (fMRI) data for studying human brain functions [2]. It is the technique of choice to acquire the diffusion-weighted imaging (DWI) data for analyzing brain connection patterns [3]. EPI is prone to susceptibility artifacts (SAs) [4,5] and eddy-current artifacts [6,7], which consist of geometric distortions. An accurate geometric distortion correction method is crucial for applications that rely on EPI images The geometric distortions cause misalignments between the functional image and the underlying structural image, subsequently leading to errors in brain analysis, e.g. incorrect localization of neural activities in the functional brain studies.
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