High‐resolution spiral real‐time cardiac cine imaging with deep learning‐based rapid image reconstruction and quantification-Reference-Cited by-同舟云学术

High‐resolution spiral real‐time cardiac cine imaging with deep learning‐based rapid image reconstruction and quantification

Published:2023-11-05 Issue:2 Volume:37 Page:
ISSN:0952-3480
Container-title:NMR in Biomedicine
language:en
Short-container-title:NMR in Biomedicine

Author:

Wang Junyu¹,Awad Marina²,Zhou Ruixi³,Wang Zhixing²⁴^ORCID,Wang Xitong⁵,Feng Xue²,Yang Yang⁶,Meyer Craig²,Kramer Christopher M.⁷⁸,Salerno Michael¹⁹

Affiliation:

1. Department of Medicine, Cardiovascular Medicine Stanford University Stanford California USA

2. Department of Biomedical Engineering University of Virginia Charlottesville Virginia USA

3. School of Artificial Intelligence Beijing University of Posts and Telecommunications Beijing China

4. Department of Radiation Oncology, City of Hope Duarte California USA

5. Department of Bioengineering Stanford University Stanford California USA

6. Department of Radiology and Biomedical Imaging University of California San Francisco San Francisco California USA

7. Department of Medicine, Division of Cardiovascular University of Virginia Health System Charlottesville Virginia USA

8. Department of Radiology and Medical Imaging University of Virginia Health System Charlottesville Virginia USA

9. Department of Radiology, Cardiovascular Imaging Stanford University Stanford California USA

Abstract

AbstractThe objective of the current study was to develop and evaluate a DEep learning‐based rapid Spiral Image REconstruction (DESIRE) and deep learning (DL)‐based segmentation approach to quantify the left ventricular ejection fraction (LVEF) for high‐resolution spiral real‐time cine imaging, including 2D balanced steady‐state free precession imaging at 1.5 T and gradient echo (GRE) imaging at 1.5 and 3 T. A 3D U‐Net–based image reconstruction network and 2D U‐Net–based image segmentation network were proposed and evaluated. Low‐rank plus sparse (L+S) served as the reference for the image reconstruction network and manual contouring of the left ventricle was the reference of the segmentation network. To assess the image reconstruction quality, structural similarity index, peak signal‐to‐noise ratio, normalized root‐mean‐square error, and blind grading by two experienced cardiologists (5: excellent; 1: poor) were performed. To assess the segmentation performance, quantification of the LVEF on GRE imaging at 3 T was compared with the quantification from manual contouring. Excellent performance was demonstrated by the proposed technique. In terms of image quality, there was no difference between L+S and the proposed DESIRE technique. For quantification analysis, the proposed DL method was not different to the manual segmentation method (p > 0.05) in terms of quantification of LVEF. The reconstruction time for DESIRE was ~32 s (including nonuniform fast Fourier transform [NUFFT]) per dynamic series (40 frames), while the reconstruction time of L+S with GPU acceleration was approximately 3 min. The DL segmentation takes less than 5 s. In conclusion, the proposed DL‐based image reconstruction and quantification techniques enabled 1‐min image reconstruction for the whole heart and quantification with automatic reconstruction and quantification of the left ventricle function for high‐resolution spiral real‐time cine imaging with excellent performance.

Funder

Wallace H. Coulter Foundation

National Institutes of Health

Publisher

Wiley

Subject

Spectroscopy,Radiology, Nuclear Medicine and imaging,Molecular Medicine

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