Deep learning for radial SMS myocardial perfusion reconstruction using the 3D residual booster U-net

Magn Reson Imaging. 2021 Nov:83:178-188. doi: 10.1016/j.mri.2021.08.007. Epub 2021 Aug 21.

Abstract

Purpose: To develop an end-to-end deep learning solution for quickly reconstructing radial simultaneous multi-slice (SMS) myocardial perfusion datasets with comparable quality to the pixel tracking spatiotemporal constrained reconstruction (PT-STCR) method.

Methods: Dynamic contrast enhanced (DCE) radial SMS myocardial perfusion data were obtained from 20 subjects who were scanned at rest and/or stress with or without ECG gating using a saturation recovery radial CAIPI turboFLASH sequence. Input to the networks consisted of complex coil combined images reconstructed using the inverse Fourier transform of undersampled radial SMS k-space data. Ground truth images were reconstructed using the PT-STCR pipeline. The performance of the residual booster 3D U-Net was tested by comparing it to state-of-the-art network architectures including MoDL, CRNN-MRI, and other U-Net variants.

Results: Results demonstrate significant improvements in speed requiring approximately 8 seconds to reconstruct one radial SMS dataset which is approximately 200 times faster than the PT-STCR method. Images reconstructed with the residual booster 3D U-Net retain quality of ground truth PT-STCR images (0.963 SSIM/40.238 PSNR/0.147 NRMSE). The residual booster 3D U-Net has superior performance compared to existing network architectures in terms of image quality, temporal dynamics, and reconstruction time.

Conclusion: Residual and booster learning combined with the 3D U-Net architecture was shown to be an effective network for reconstructing high-quality images from undersampled radial SMS datasets while bypassing the reconstruction time of the PT-STCR method.

Keywords: 3D U-Net; Myocardial perfusion; boosting; deep learning; radial simultaneous multi-slice; residual learning.

Publication types

  • Research Support, N.I.H., Extramural

MeSH terms

  • Deep Learning*
  • Humans
  • Image Processing, Computer-Assisted
  • Magnetic Resonance Imaging
  • Perfusion