Deep learning-based image segmentation model using an MRI-based convolutional neural network for physiological evaluation of the heart

Wanni Xu; Jianshe Shi; Yunling Lin; Chao Liu; Weifang Xie; Huifang Liu; Siyu Huang; Daxin Zhu; Lianta Su; Yifeng Huang; Yuguang Ye; Jianlong Huang

doi:10.3389/fphys.2023.1148717

Deep learning-based image segmentation model using an MRI-based convolutional neural network for physiological evaluation of the heart

Front Physiol. 2023 Mar 21:14:1148717. doi: 10.3389/fphys.2023.1148717. eCollection 2023.

Authors

Wanni Xu^{1

2

3}, Jianshe Shi⁴, Yunling Lin⁵, Chao Liu^{1

2

3}, Weifang Xie^{1

2

3}, Huifang Liu⁴, Siyu Huang¹, Daxin Zhu^{1

2

3}, Lianta Su^{1

3}, Yifeng Huang⁵, Yuguang Ye^{1

2

3}, Jianlong Huang^{1

2

3}

Affiliations

¹ Department of Mathematics and Computer Science, Quanzhou Normal University, Quanzhou, China.
² Fujian Provincial Key Laboratory of Data Intensive Computing, Quanzhou, China.
³ Key Laboratory of Intelligent Computing and Information Processing, Fujian Province University, Quanzhou, China.
⁴ Department of General Surgery, Huaqiao University Affiliated Strait Hospital, Quanzhou, China.
⁵ Department of Diagnostic Radiology, Huaqiao University Affiliated Strait Hospital, Quanzhou, China.

Abstract

Background and Objective: Cardiovascular disease is a high-fatality health issue. Accurate measurement of cardiovascular function depends on precise segmentation of physiological structure and accurate evaluation of functional parameters. Structural segmentation of heart images and calculation of the volume of different ventricular activity cycles form the basis for quantitative analysis of physiological function and can provide the necessary support for clinical physiological diagnosis, as well as the analysis of various cardiac diseases. Therefore, it is important to develop an efficient heart segmentation algorithm. Methods: A total of 275 nuclear magnetic resonance imaging (MRI) heart scans were collected, analyzed, and preprocessed from Huaqiao University Affiliated Strait Hospital, and the data were used in our improved deep learning model, which was designed based on the U-net network. The training set included 80% of the images, and the remaining 20% was the test set. Based on five time phases from end-diastole (ED) to end-systole (ES), the segmentation findings showed that it is possible to achieve improved segmentation accuracy and computational complexity by segmenting the left ventricle (LV), right ventricle (RV), and myocardium (myo). Results: We improved the Dice index of the LV to 0.965 and 0.921, and the Hausdorff index decreased to 5.4 and 6.9 in the ED and ES phases, respectively; RV Dice increased to 0.938 and 0.860, and the Hausdorff index decreased to 11.7 and 12.6 in the ED and ES, respectively; myo Dice increased to 0.889 and 0.901, and the Hausdorff index decreased to 8.3 and 9.2 in the ED and ES, respectively. Conclusion: The model obtained in the final experiment provided more accurate segmentation of the left and right ventricles, as well as the myocardium, from cardiac MRI. The data from this model facilitate the prediction of cardiovascular disease in real-time, thereby providing potential clinical utility.

Keywords: U-Net; batch normalization layer; cardiac MRI; image segmentation; physiological analysis.

Grants and funding

The Science and Technology Program of Quanzhou funded this research (No. 2021CT0010).