Author: Shan, Fei; Gao, Yaozong; Wang, Jun; Shi, Weiya; Shi, Nannan; Han, Miaofei; Xue, Zhong; Shen, Dinggang; Shi, Yuxin
Title: Abnormal Lung Quantification in Chest CT Images of COVIDâ€19 Patients with Deep Learning and its Application to Severity Prediction Cord-id: h63afhr6 Document date: 2020_11_22
ID: h63afhr6
Snippet: OBJECTIVE: CT provides rich diagnosis and severity information of COVIDâ€19 in clinical practice. However, there is no computerized tool to automatically delineate COVIDâ€19 infection regions in chest CT scans for quantitative assessment in advanced applications such as severity prediction. The aim of this study is to develop a deep learning (DL) based method for automatic segmentation and quantification of infection regions as well as the entire lungs from chest CT scans. METHODS: The DLâ€ba
Document: OBJECTIVE: CT provides rich diagnosis and severity information of COVIDâ€19 in clinical practice. However, there is no computerized tool to automatically delineate COVIDâ€19 infection regions in chest CT scans for quantitative assessment in advanced applications such as severity prediction. The aim of this study is to develop a deep learning (DL) based method for automatic segmentation and quantification of infection regions as well as the entire lungs from chest CT scans. METHODS: The DLâ€based segmentation method employs the “VBâ€Net†neural network to segment COVIDâ€19 infection regions in CT scans. The developed DLâ€based segmentation system is trained by CT scans from 249 COVIDâ€19 patients, and further validated by CT scans from other 300 COVIDâ€19 patients. To accelerate the manual delineation of CT scans for training, a humanâ€involvedâ€modelâ€iterations (HIMI) strategy is also adopted to assist radiologists to refine automatic annotation of each training case. To evaluate the performance of the DLâ€based segmentation system, three metrics, i.e., Dice similarity coefficient, the differences of volume, and percentage of infection (POI), are calculated between automatic and manual segmentations on the validation set. Then, a clinical study on severity prediction is reported based on the quantitative infection assessment. RESULTS: The proposed DLâ€based segmentation system yielded Dice similarity coefficients of 91.6%±10.0% between automatic and manual segmentations, and a mean POI estimation error of 0.3% for the whole lung on the validation dataset. Moreover, compared with the cases with fully manual delineation that often takes hours, the proposed HIMI training strategy can dramatically reduce the delineation time to 4 minutes after 3 iterations of model updating. Besides, the best accuracy of severity prediction was 73.4%±1.3% when the mass of infection (MOI) of multiple lung lobes and bronchopulmonary segments were used as features for severity prediction, indicating the potential clinical application of our quantification technique on severity prediction. CONCLUSIONS: A DLâ€based segmentation system has been developed to automatically segment and quantify infection regions in CT scans of COVIDâ€19 patients. Quantitative evaluation indicated high accuracy in automatic infection delineation and severity prediction.
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