Deep neural networks for magnetic resonance elastography acceleration in thermal-ablation monitoring

Xiang Shan; Jinying Yang; Peng Xu; Liangliang Hu; Haitao Ge

doi:10.1002/mp.15471

Deep neural networks for magnetic resonance elastography acceleration in thermal-ablation monitoring

Med Phys. 2022 Mar;49(3):1803-1813. doi: 10.1002/mp.15471. Epub 2022 Feb 4.

Authors

Xiang Shan¹, Jinying Yang², Peng Xu³, Liangliang Hu⁴, Haitao Ge¹

Affiliations

¹ School of Medical Imaging, Xuzhou Medical University, Xuzhou, Jiangsu, China.
² Laboratory Center for Information Science, University of Science and Technology of China, Hefei, Anhui, China.
³ Department of Radiology, Affiliated Hospital of Xuzhou Medical University, Xuzhou, Jiangsu, China.
⁴ School of Instrument Science and Opto-electronics Engineering, Hefei University of Technology, Hefei, Anhui, China.

PMID: 35061250
DOI: 10.1002/mp.15471

Abstract

Purpose: To develop a deep neural network for accelerating magnetic resonance elastography (MRE) acquisition, to validate the ability to generate reliable MRE results with the down-sampled k-space data, and to demonstrate the feasibility of the proposed method in monitoring the stiffness changes during thermal ablation in a phantom study.

Materials and methods: MRE scans were performed with 60 Hz excitation on porcine ex-vivo liver gel phantoms in a 0.36T MRI scanner to generate the training dataset. The acquisition protocol was based on a spin-echo MRE pulse sequence with tailored motion-sensitive gradients to reduce echo time (TE). A U-Net based deep neural network was developed and trained to interpolate the missing data from down-sampled k-space. We calculated the errors of 80 sets magnitude/phase images reconstructed from the zero-filled, compressive sensing (CS) and deep learning (DL) method for comparison. The peak signal-to-noise rate (PSNR) and structural similarity index (SSIM) of the magnitude/phase images were also calculated for comparison. The stiffness changes were recorded before, during, and after ablation. The mean stiffness values over the region of interest (ROI) were compared between the elastograms reconstructed from the fully sampled k-space and interpolated k-space after thermal ablation.

Results: The mean absolute error (MAE), PSNR, and SSIM of the proposed DL approach were significantly better than the results from the zero-filled method (p < 0.0001) and CS (p < 0.0001). The stiffness changes before and after thermal ablation assessed by the proposed approach (before: 7.7±1.1 kPa, after: 11.9±4.0 kPa, 4.2-kPa increase) gave close agreement with the values calculated from the fully sampled data (before: 8.0±1.0 kPa, after: 12.6±4.2 kPa, 4.6-kPa increase). In contrast, the stiffness changes computed from the zero-filled method (before: 4.9±1.4 kPa, after: 5.6±2.8 kPa, 0.7-kPa increase) were substantially underestimated.

Conclusion: This study demonstrated the capability of the proposed DL method for rapid MRE acquisition and provided a promising solution for monitoring the MRI-guided thermal ablation.

Keywords: MR elastography; U-Net; deep learning; thermal ablation.

MeSH terms

Acceleration
Animals
Echo-Planar Imaging / methods
Elasticity Imaging Techniques* / methods
Magnetic Resonance Imaging / methods
Neural Networks, Computer
Swine

Abstract

MeSH terms

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