Abstract
Along with the widespread achievement of machine learning in computer vision in recent years, plenty of deep learning models for medical image segmentation have been published, with impressive results. However, the majority of those model just leverages supervised technics while others additionally utilize semi-supervised and unsupervised technics, with the results are not as good as supervised ones though. Inspired by the efficiency of Mumford-Shah functional for unsupervised and Active Contour functional for supervised tasks, in this work, we proposed the new loss functional which integrates those two with some modifications and extension to the case of multiphase segmentation. It allows our deep learning model to segment multi-class simultaneously with high accuracy instead of binary segmentation. The proposed approach is applied to the segmentation of left ventricle from cardiac MR images, in which both endocardium and epicardium are simultaneously segmented. Our proposed method is assessed on 2017 ACDCA dataset. The experiment demonstrates that our new loss achieves the promising results in term of Dice coefficient and Jaccard index. This illuminates the efficiency of our method in multi-class segmentation for medical images.
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This research is funded by Vietnam National Foundation for Science and Technology Development (NAFOSTED) under grant number 102.05-2018.302.
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Trinh, MN., Nguyen, NT., Tran, TT., Pham, VT. (2022). A Semi-supervised Deep Learning-Based Approach with Multiphase Active Contour Loss for Left Ventricle Segmentation from CMR Images. In: Poonia, R.C., Singh, V., Singh Jat, D., Diván, M.J., Khan, M.S. (eds) Proceedings of Third International Conference on Sustainable Computing. Advances in Intelligent Systems and Computing, vol 1404. Springer, Singapore. https://doi.org/10.1007/978-981-16-4538-9_2
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