Active Learning for Efficient Segmentation of Liver with Convolutional Neural Network-Corrected Labeling in Magnetic Resonance Imaging-Derived Proton Density Fat Fraction
- Authors
- Cho, Yongwon; Kim, Min Ju; Park, Beom Jin; Sim, Ki Choon; Keu, Yeom Suk; Han, Yeo Eun; Sung, Deuk Jae; Han, Na Yeon
- Issue Date
- 10월-2021
- Publisher
- SPRINGER
- Keywords
- Abdominal image analysis; Active learning; Convolution neural network; Deep learning; Proton density fat fraction
- Citation
- JOURNAL OF DIGITAL IMAGING, v.34, no.5, pp.1225 - 1236
- Indexed
- SCIE
SCOPUS
- Journal Title
- JOURNAL OF DIGITAL IMAGING
- Volume
- 34
- Number
- 5
- Start Page
- 1225
- End Page
- 1236
- URI
- https://scholar.korea.ac.kr/handle/2021.sw.korea/136254
- DOI
- 10.1007/s10278-021-00516-4
- ISSN
- 0897-1889
- Abstract
- This study aimed to propose an efficient method for self-automated segmentation of the liver using magnetic resonance imaging-derived proton density fat fraction (MRI-PDFF) through deep active learning. We developed an active learning framework for liver segmentation using labeled and unlabeled data in MRI-PDFF. A total of 77 liver samples on MRI-PDFF were obtained from patients with nonalcoholic fatty liver disease. For the training, tuning, and testing of the liver segmentation, the ground truth of 71 (internal) and 6 (external) MRI-PDFF scans for training and testing were verified by an expert reviewer. For 100 randomly selected slices, manual and deep learning (DL) segmentations for visual assessments were classified, ranging from very accurate to mostly accurate. The dice similarity coefficients for each step were 0.69 +/- 0.21, 0.85 +/- 0.12, and 0.94 +/- 0.01, respectively (p-value = 0.1389 between the first step and the second step or p-value = 0.0144 between the first step and the third step for paired t-test), indicating that active learning provides superior performance compared with non-active learning. The biases in the Bland-Altman plots for each step were - 24.22% (from - 82.76 to - 2.70), - 21.29% (from - 59.52 to 3.06), and - 0.67% (from - 10.43 to 4.06). Additionally, there was a fivefold reduction in the required annotation time after the application of active learning (2 min with, and 13 min without, active learning in the first step). The number of very accurate slices for DL (46 slices) was greater than that for manual segmentations (6 slices). Deep active learning enables efficient learning for liver segmentation on a limited MRI-PDFF.
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Collections - College of Medicine > Department of Medical Science > 1. Journal Articles
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