Daryl L X Fung1, Qian Liu1,2, Judah Zammit1, Carson Kai-Sang Leung1, Pingzhao Hu3,4,5. 1. Department of Computer Science, University of Manitoba, Winnipeg, MB, R3T 2N2, Canada. 2. Department of Biochemistry and Medical Genetics, University of Manitoba, 745 Bannatyne Avenue, Winnipeg, MB, R3E 0J9, Canada. 3. Department of Computer Science, University of Manitoba, Winnipeg, MB, R3T 2N2, Canada. pingzhao.hu@umanitoba.ca. 4. Department of Biochemistry and Medical Genetics, University of Manitoba, 745 Bannatyne Avenue, Winnipeg, MB, R3E 0J9, Canada. pingzhao.hu@umanitoba.ca. 5. CancerCare Manitoba Research Institute, CancerCare Manitoba, Winnipeg, MB, R3E 0W3, Canada. pingzhao.hu@umanitoba.ca.
Abstract
BACKGROUND: Coronavirus disease 2019 (COVID-19) is very contagious. Cases appear faster than the available Polymerase Chain Reaction test kits in many countries. Recently, lung computerized tomography (CT) has been used as an auxiliary COVID-19 testing approach. Automatic analysis of the lung CT images is needed to increase the diagnostic efficiency and release the human participant. Deep learning is successful in automatically solving computer vision problems. Thus, it can be introduced to the automatic and rapid COVID-19 CT diagnosis. Many advanced deep learning-based computer vison techniques were developed to increase the model performance but have not been introduced to medical image analysis. METHODS: In this study, we propose a self-supervised two-stage deep learning model to segment COVID-19 lesions (ground-glass opacity and consolidation) from chest CT images to support rapid COVID-19 diagnosis. The proposed deep learning model integrates several advanced computer vision techniques such as generative adversarial image inpainting, focal loss, and lookahead optimizer. Two real-life datasets were used to evaluate the model's performance compared to the previous related works. To explore the clinical and biological mechanism of the predicted lesion segments, we extract some engineered features from the predicted lung lesions. We evaluate their mediation effects on the relationship of age with COVID-19 severity, as well as the relationship of underlying diseases with COVID-19 severity using statistic mediation analysis. RESULTS: The best overall F1 score is observed in the proposed self-supervised two-stage segmentation model (0.63) compared to the two related baseline models (0.55, 0.49). We also identified several CT image phenotypes that mediate the potential causal relationship between underlying diseases with COVID-19 severity as well as the potential causal relationship between age with COVID-19 severity. CONCLUSIONS: This work contributes a promising COVID-19 lung CT image segmentation model and provides predicted lesion segments with potential clinical interpretability. The model could automatically segment the COVID-19 lesions from the raw CT images with higher accuracy than related works. The features of these lesions are associated with COVID-19 severity through mediating the known causal of the COVID-19 severity (age and underlying diseases).
BACKGROUND:Coronavirus disease 2019 (COVID-19) is very contagious. Cases appear faster than the available Polymerase Chain Reaction test kits in many countries. Recently, lung computerized tomography (CT) has been used as an auxiliary COVID-19 testing approach. Automatic analysis of the lung CT images is needed to increase the diagnostic efficiency and release the humanparticipant. Deep learning is successful in automatically solving computer vision problems. Thus, it can be introduced to the automatic and rapid COVID-19 CT diagnosis. Many advanced deep learning-based computer vison techniques were developed to increase the model performance but have not been introduced to medical image analysis. METHODS: In this study, we propose a self-supervised two-stage deep learning model to segment COVID-19 lesions (ground-glass opacity and consolidation) from chest CT images to support rapid COVID-19 diagnosis. The proposed deep learning model integrates several advanced computer vision techniques such as generative adversarial image inpainting, focal loss, and lookahead optimizer. Two real-life datasets were used to evaluate the model's performance compared to the previous related works. To explore the clinical and biological mechanism of the predicted lesion segments, we extract some engineered features from the predicted lung lesions. We evaluate their mediation effects on the relationship of age with COVID-19 severity, as well as the relationship of underlying diseases with COVID-19 severity using statistic mediation analysis. RESULTS: The best overall F1 score is observed in the proposed self-supervised two-stage segmentation model (0.63) compared to the two related baseline models (0.55, 0.49). We also identified several CT image phenotypes that mediate the potential causal relationship between underlying diseases with COVID-19 severity as well as the potential causal relationship between age with COVID-19 severity. CONCLUSIONS: This work contributes a promising COVID-19 lung CT image segmentation model and provides predicted lesion segments with potential clinical interpretability. The model could automatically segment the COVID-19 lesions from the raw CT images with higher accuracy than related works. The features of these lesions are associated with COVID-19 severity through mediating the known causal of the COVID-19 severity (age and underlying diseases).
Authors: Alberto Aleta; David Martín-Corral; Ana Pastore Y Piontti; Marco Ajelli; Maria Litvinova; Matteo Chinazzi; Natalie E Dean; M Elizabeth Halloran; Ira M Longini; Stefano Merler; Alex Pentland; Alessandro Vespignani; Esteban Moro; Yamir Moreno Journal: Nat Hum Behav Date: 2020-08-05
Authors: Scott Simpson; Fernando U Kay; Suhny Abbara; Sanjeev Bhalla; Jonathan H Chung; Michael Chung; Travis S Henry; Jeffrey P Kanne; Seth Kligerman; Jane P Ko; Harold Litt Journal: Radiol Cardiothorac Imaging Date: 2020-03-25
Authors: Joyce Chelangat Bore; Peiyang Li; Lin Jiang; Walid M A Ayedh; Chunli Chen; Dennis Joe Harmah; Dezhong Yao; Zehong Cao; Peng Xu Journal: IEEE Trans Med Imaging Date: 2021-11-30 Impact factor: 10.048
Authors: Ashley G Gillman; Febrio Lunardo; Joseph Prinable; Gregg Belous; Aaron Nicolson; Hang Min; Andrew Terhorst; Jason A Dowling Journal: Phys Eng Sci Med Date: 2021-12-17