Differentiating novel coronavirus pneumonia from general pneumonia based on machine learning

Liu, Chenglong; Wang, Xiaoyang; Liu, Chenbin; Sun, Qingfeng; Peng, Wenxian

doi:10.21203/rs.3.rs-31313/v3

Cited by 10 publications

(17 citation statements)

References 22 publications

(32 reference statements)

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“…Abraham et al [ 26 ] combined multiple CNN-extracted features with a correlation-based feature selection (CFS) technique and a Bayesian classifier for COVID-19 prediction. Liu et al [ 27 ] developed and validated a complete machine learning framework for chest CT images to distinguish COVID-19 from global pneumonia (GP). Tuncer et al [ 28 ] proposed a novel intelligent computer vision method for automatic detection of the COVID-19 virus and conducted 10-fold cross-validation based on the SVM classifier, which showed a classification accuracy of 100.0%.…”

Section: Introductionmentioning

confidence: 99%

Detection of COVID-19 severity using blood gas analysis parameters and Harris hawks optimized extreme learning machine

Han

Heidari

et al. 2022

Computers in Biology and Medicine

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Section: Introductionmentioning

confidence: 99%

Detection of COVID-19 severity using blood gas analysis parameters and Harris hawks optimized extreme learning machine

Han

Heidari

et al. 2022

Computers in Biology and Medicine

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“…For example, a convolutional neural network was used to distinguish between pneumonia patients and healthy controls [30]. Besides, novel coronavirus pneumonia was differentiated from general pneumonia using the convolutional neural network [31]. Moreover, a variety of deep learning feature embedding methods were used to improve the recognition accuracy of COVID-19 pneumonia [32], screen diseased frames from pneumonia images [33], and screen patients with pneumonia [34].…”

Section: Discussionmentioning

confidence: 99%

A Practical Deep Learning Model in Differentiating Pneumonia-Type Lung Carcinoma from Pneumonia on CT Images: ResNet Added with Attention Mechanism

Luo

Chen

2022

Journal of Oncology

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Objective. We aim to develop a deep neural network model to differentiate pneumonia-type lung carcinoma from pneumonia based on chest CT scanning and evaluate its performance. Materials and Methods. We retrospectively analyzed 131 patients diagnosed with pneumonia-type lung carcinoma and 171 patients with pneumonia treated in Beijing Hospital from October 2019 to February 2021. The average age was 68 (±15) years old, and the proportion of men (162/302) was slightly more than that of women (140/302). In this study, a deep learning based model UNet was applied to extract lesion areas from chest CT images. Lesion areas were extracted and classified by a designed spatial attention mechanism network. The model AUC and diagnostic accuracy were analyzed based on the results of the model. We analyzed the accuracy rate, sensitivity, and specificity and compared the results of the model to the junior and senior radiologists and radiologists based on the model. Results. The model has a good efficiency in detecting pneumonia-like lesions (6.31 seconds/case). The model accuracy rate, sensitivity, and specificity were 74.20%, 60.37%, and 89.36%, respectively. The junior radiologist’s accuracy rate, sensitivity, and specificity were 61.00%, 48.08%, and 75.00%, respectively. The senior radiologist’s accuracy rate, sensitivity, and specificity were 65.00%, 51.92%, and 79.17%, respectively. The results of junior radiologists based on the model were improved (76.00% for accuracy rate, 62.75% for sensitivity, and 89.80% for specificity). The results of senior radiologists based on the model were also improved (78.00% for accuracy rate, 64.71% for sensitivity, and 91.84% for specificity) and the diagnostic accuracy of which was statistically higher than other groups P < 0.05 . Based on the lesion texture diversity and the lesion boundary ambiguity, the algorithm produced false-positive samples (13.51%). Conclusion. This deep learning model could detect pneumonia-type lung carcinoma and differentiate it from pneumonia accurately and efficiently.

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“…In studies of adults with COVID‐19, lung imaging quantification has been successfully implemented to predict adverse outcomes and severe complications 13–16 . We previously described CXR‐based methods to quantify lung disease severity in pediatric viral LRTIs 19–23 .…”

Section: Discussionmentioning

confidence: 99%

“…We found that 64% of lung CT images in PCR‐confirmed pediatric COVID‐19 cases had abnormalities, primarily characterized by focal ground‐glass opacities (GGO) and consolidations 2 . In adult COVID‐19 cases, CT scan‐based algorithms have recently been developed for lung disease quantification and prediction of life‐threatening complications 13–16 . However, chest CT‐based risk prediction approaches cannot be readily applied to infants and children due to concerns about sedation requirements, radiation exposure, and costs 17,18 .…”

Section: Introductionmentioning

confidence: 99%

Chest X‐ray lung imaging features in pediatric COVID‐19 and comparison with viral lower respiratory infections in young children

Niño

Moltó

Aguilar

et al. 2021

Pediatric Pulmonology

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Rationale Chest radiography (CXR) is a noninvasive imaging approach commonly used to evaluate lower respiratory tract infections (LRTIs) in children. However, the specific imaging patterns of pediatric coronavirus disease 2019 (COVID‐19) on CXR, their relationship to clinical outcomes, and the possible differences from LRTIs caused by other viruses in children remain to be defined. Methods This is a cross‐sectional study of patients seen at a pediatric hospital with polymerase chain reaction (PCR)‐confirmed severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) (n = 95). Patients were subdivided in infants (0–2 years, n = 27), children (3–10 years, n = 27), and adolescents (11–19 years, n = 41). A sample of young children (0–2 years, n = 68) with other viral lower respiratory infections (LRTI) was included to compare their CXR features with the subset of infants (0–2 years) with COVID‐19. Results Forty‐five percent of pediatric patients with COVID‐19 were hospitalized and 20% required admission to intensive care unit (ICU). The most common abnormalities identified were ground‐glass opacifications (GGO)/consolidations (35%) and increased peribronchial markings/cuffing (33%). GGO/consolidations were more common in older individuals and perihilar markings were more common in younger subjects. Subjects requiring hospitalization or ICU admission had significantly more GGO/consolidations in CXR (p < .05). Typical CXR features of pediatric viral LRTI (e.g., hyperinflation) were more common in non‐COVID‐19 viral LRTI cases than in COVID‐19 cases (p < .05). Conclusions CXR may be a complemental exam in the evaluation of moderate or severe pediatric COVID‐19 cases. The severity of GGO/consolidations seen in CXR is predictive of clinically relevant outcomes. Hyperinflation could potentially aid clinical assessment in distinguishing COVID‐19 from other types of viral LRTI in young children.

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Differentiating novel coronavirus pneumonia from general pneumonia based on machine learning

Cited by 10 publications

References 22 publications

Detection of COVID-19 severity using blood gas analysis parameters and Harris hawks optimized extreme learning machine

Detection of COVID-19 severity using blood gas analysis parameters and Harris hawks optimized extreme learning machine

A Practical Deep Learning Model in Differentiating Pneumonia-Type Lung Carcinoma from Pneumonia on CT Images: ResNet Added with Attention Mechanism

Chest X‐ray lung imaging features in pediatric COVID‐19 and comparison with viral lower respiratory infections in young children

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