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Corona virus disease 2019 (COVID-19) testing relies on traditional screening methods, which require a lot of manpower and material resources. Recently, to effectively reduce the damage caused by radiation and enhance effectiveness, deep learning of classifying COVID-19 negative and positive using the mixed dataset by CT and X-rays images have achieved remarkable research results. However, the details presented on CT and X-ray images have pathological diversity and similarity features, thus increasing the difficulty for physicians to judge specific cases. On this basis, this paper proposes a novel coronavirus pneumonia classification model using the mixed dataset by CT and X-rays images. To solve the problem of feature similarity between lung diseases and COVID-19, the extracted features are enhanced by an adaptive region enhancement algorithm. Besides, the depth network based on the residual blocks and the dense blocks is trained and tested. On the one hand, the residual blocks effectively improve the accuracy of the model and the non-linear COVID-19 features are obtained by cross-layer link. On the other hand, the dense blocks effectively improve the robustness of the model by connecting local and abstract information. On mixed X-ray and CT datasets, the sensitivity, specificity, positive predictive value (PPV), negative predictive value (NPV), area under curve (AUC), and accuracy can all reach 0.99. On the basis of respecting patient privacy and ethics, the proposed algorithm using the mixed dataset from real cases can effectively assist doctors in performing the accurate COVID-19 negative and positive classification to determine the infection status of patients.
Wydawca
Czasopismo
Rocznik
Tom
Strony
977--994
Opis fizyczny
Bibliogr. 59 poz., rys., tab., wykr.
Twórcy
autor
- Department of Computing and Information Technology, Liaoning Normal University, Dalian City, Liaoning Province, China
autor
- Department of Computing and Information Technology, Liaoning Normal University, Dalian City, Liaoning Province, China
Bibliografia
- [1] Bialek S, Bowen V, Chow N, Curns A, Gierke R, Hall A, et al. Geographic Differences in COVID-19 Cases, Deaths, and Incidence — United States, February 12–April 7, 2020. MMWR Morb Mortal Wkly Rep 2020;69(15):465–71.
- [2] Sun Y, Dong Y, Wang L, et al. Characteristics and prognostic factors of disease severity in patients with COVID-19: The Beijing experience. J Autoimmun Apr. 2020;112 102473.
- [3] Suri J S, Puvvula A, Biswas M, et al., ‘‘COVID-19 pathways for brain and heart injury in comorbidity patients: A role of medical imaging and artificial intelligence-based COVID severity classification: A review,” Comput Biol Med, pp. 103960, Aug. 2020.
- [4] Farhat H, Sakr GE, Kilany R. Deep learning applications in pulmonary medical imaging: recent updates and insights on COVID-19. Mach Vis Appl Sept. 2020;31(6):1–422020.
- [5] Sedaghat A, Gity M, Radpour A, Karimi MA, Haghighatkhah HR, Keshavarz E, et al. COVID-19 protection guidelines in outpatient medical imaging centers. Acad Radiol 2020;27(6):904.
- [6] Li K, Fang Y, Li W, et al. CT image visual quantitative evaluation and clinical classification of coronavirus disease (COVID-19). Eur Radiol Mar. 2020;30(8):4407–16.
- [7] Ko H, Chung H, Kang WS, Kim KW, Shin Y, Kang SJ, et al. COVID-19 pneumonia diagnosis using a simple 2D deep learning framework with a single chest CT image: model development and validation. J Med Intern Res Jan. 2020;22(6).
- [8] Jiang Y, Chen H, Loew M, Ko H. Covid-19 ct image synthesis with a conditional generative adversarial network. IEEE J Biomed Health Inf 2021;25(2):441–52.
- [9] Abd Elaziz M, Ewees AA, Yousri D, et al. An improved Marine Predators algorithm with fuzzy entropy for multi-level thresholding: Real world example of COVID-19 CT image segmentation. IEEE Access Jul. 2020;8:125306–30.
- [10] Apostolopoulos ID, Mpesiana TA. Covid-19: automatic detection from x-ray images utilizing transfer learning with convolutional neural networks. Phys Eng Sci Med Jan. 2020;43(2):635–40.
- [11] Abbas A, Abdelsamea MM, Gaber MM. Classification of COVID-19 in chest X-ray images using DeTraC deep convolutional neural network. Appl Intellig Feb. 2021;51(2):854–64.
- [12] Hassantabar S, Ahmadi M, Sharifi A. Diagnosis and detection of infected tissue of COVID-19 patients based on lung X-ray image using convolutional neural network approaches. Chaos, Solit Fract Jul. 2020;140 110170.
- [13] Civit-Masot J, Luna-Perejón F, Domínguez Morales M, Civit A. Deep learning system for COVID-19 diagnosis aid using X-ray pulmonary images. Appl Sci Jul. 2020;10(13):4640.
- [14] Nishio M, Noguchi S, Matsuo H, et al. Automatic classification between COVID-19 pneumonia, non-COVID-19 pneumonia, and the healthy on chest X-ray image: combination of data augmentation methods. Sci Rep Jan. 2020;10(1):1–6.
- [15] Ibrahim DA, Zebari DA, Mohammed HJ, et al. Effective hybrid deep learning model for COVID-19 patterns identification using CT images. Exp Syst 2022:e13010.
- [16] Shamim S, Awan MJ, Mohd Zain A, Naseem U, Mohammed MA, Garcia-Zapirain B, et al. Automatic COVID-19 Lung Infection Segmentation through Modified Unet Model. J Healthcare Eng 2022;2022:1–13.
- [17] Abdulkareem KH, Mostafa SA, Al-Qudsy ZN, Mohammed MA, Al-Waisy AS, Kadry S, et al. Automated System for Identifying COVID-19 Infections in Computed Tomography Images Using Deep Learning Models. J Healthcare Eng 2022;2022:1–13.
- [18] Krizhevsky A, Sutskever I, Hinton G E, ‘‘Imagenet classification with deep convolutional neural networks,” Advances in neural information processing systems, pp. 1097-1105, Jan. 2012.
- [19] Maghdid HS, Asaad AT, Ghafoor KZ, et al. ‘‘Diagnosing COVID-19 pneumonia from X-ray and CT images using deep learning and transfer learning algorithms”, Multimodal Image Exploitation and Learning 2021. Int Soc Optics Photon Apr. 2021;11734:117340E.
- [20] Turkoglu M. COVIDetectioNet: COVID-19 diagnosis system based on X-ray images using features selected from pre-learned deep features ensemble. Appl Intellig Jan. 2021;51(3):1213–26.
- [21] Loey M, Smarandache FM, Khalifa NE. M Khalifa N E, ‘‘Within the lack of chest COVID-19 X-ray dataset: a novel detection model based on GAN and deep transfer learning”. Symmetry Apr. 2020;12(4):651.
- [22] Sengupta A, Ye Y, Wang R, Liu C, Roy K. Going Deeper in Spiking Neural Networks: Vgg and Residual Architectures. Front Neurosci Jan. 2019;13.
- [23] Sitaula C, Hossain MB. Attention-based Vgg-16 model for COVID-19 chest X-ray image classification. Applied Intelligence Jan. 2021;51(5):2850–63.
- [24] Shibly KH, Dey SK, Islam MTU, et al. COVID faster R-CNN: A novel framework to Diagnose Novel Coronavirus Disease (COVID-19) in X-Ray images. Inf Med Unlocked Aug. 2020;20100405.
- [25] Lee K-S, Kim JY, Jeon E-T, Choi WS, Kim NH, Lee KY. Evaluation of scalability and degree of fine-tuning of deep convolutional neural networks for COVID-19 screening on chest X-ray images using explainable deep-learning algorithm. J Personal Med Nov. 2020;10(4):213.
- [26] He K, Zhang X, Ren S, et al., ‘‘Deep residual learning for image recognition,” Proceedings of the IEEE conference on computer vision and pattern recognition. pp. 770-778; Jun. 2016.
- [27] He K, Zhang X, Ren S, et al., ‘‘Identity mappings in deep residual networks,” European conference on computer vision. Springer, Cham, pp. 630-645; Oct. 2016.
- [28] Zhou C, Song J, Zhou S, Zhang Z, Xing J. COVID-19 Detection based on Image Regrouping and Resnet-SVM using Chest Xray Images. IEEE Access, Jan 2021;9:81902–12.
- [29] Sakib S, Tazrin T, Fouda MM, et al. DL-CRC: deep learning-based chest radiograph classification for COVID-19 detection: a novel approach. IEEE Access Sept. 2020;8:171575–89.
- [30] Hira S, Bai A, Hira S, ‘‘An automatic approach based on CNN architecture to detect Covid-19 disease from chest X-ray images,” Appl Intellig, vol. 51, no. 5, pp. 2864-2889, May. 2021.
- [31] Huang G, Liu Z, Van Der Maaten L, et al., ‘‘Densely connected convolutional networks,” Proceedings of the IEEE conference on computer vision and pattern recognition. Pp. 4700-4708, Aug. 2017.
- [32] Tabrizchi H, Mosavi A, Vamossy Z, et al., ‘‘Densely Connected Convolutional Networks (Densenet) for Diagnosing Coronavirus Disease (COVID-19) from Chest X-ray Imaging,” 2021 IEEE International Symposium on Medical Measurements and Applications (MeMeA). IEEE, pp. 1-5, Sept. 2021.
- [33] Y.-D. Zhang S.C. Satapathy X. Zhang S.-H. Wang COVID-19 Diagnosis via DenseNet and Optimization of Transfer Learning Setting.
- [34] Chowdhury MEH, Rahman T, Khandakar A, et al. Can AI help in screening viral and COVID-19 pneumonia? IEEE Access Jan. 2020;8:132665–76.
- [35] Allioui H, Mohammed MA, Benameur N, Al-Khateeb B, Abdulkareem KH, Garcia-Zapirain B, et al. A multi-agent deep reinforcement learning approach for enhancement of COVID-19 CT image segmentation. J Personal Med 2022;12(2):309.
- [36] Wang S-H, Govindaraj VV, Go´ rriz JM, Zhang X, Zhang Y-D. Covid-19 classification by FGCNet with deep feature fusion from graph convolutional network and convolutional neural network. Informat Fusion 2021;67:208–29.
- [37] Tang Z, ZhaoW, Xie X, et al. Severity assessment of COVID-19 using CT image features and laboratory indices. Phys Med Biol Jan. 2021;66(3) 035015.
- [38] Hasoon JN, Fadel AH, Hameed RS, Mostafa SA, Khalaf BA, Mohammed MA, et al. COVID-19 anomaly detection and classification method based on supervised machine learning of chest X-ray images. Results Phys 2021;31.
- [39] Tuncer T, Dogan S, Ozyurt F. An automated residual exemplar local binary pattern and iterative ReliefF based COVID-19 detection method using chest X-ray image. Chemomet Intellig Laborat Syst Jan. 2020;203 104054.
- [40] Sen S, Saha S, Chatterjee S, Mirjalili S, Sarkar R. A bi-stage feature selection approach for COVID-19 prediction using chest CT images. Appl Intell 2021;51(12):8985–9000.
- [41] Alam N-A-A, Ahsan M, Based MA, Haider J, Kowalski M. COVID-19 detection from chest X-ray images using feature fusion and deep learning. Sensors Feb. 2021;21(4):1480.
- [42] Kermany D, Zhang K, Goldbaum M. Labeled optical coherence tomography (oct) and chest x-ray images for classification. Mendeley data 2018;2(2).
- [43] Bhatt R, Yadav S, Sarvaiya JN. Convolutional neural network based chest X-ray image classification for pneumonia diagnosis//International Conference on Emerging Technology Trends in Electronics Communication and Networking. Singapore: Springer; 2020. p. 254–66.
- [44] Yang X, He X, Zhao J, et al. COVID-CT-Dataset: A CT Scan Dataset about COVID-19. 2020. doi: 10.48550/arXiv.2003.13865.
- [45] Demir F, Sengur A, Bajaj V. Convolutional neural networks based efficient approach for classification of lung diseases. Health Informat Sci Syst Dec. 2020;8(1):1–8.
- [46] Dash L, Chatterji BN. Adaptive contrast enhancement and de-enhancement. Pattern Recogn Jan. 1991;24(4):289–302.
- [47] Zhou Z, Sang N, Hu X. Global brightness and local contrast adaptive enhancement for low illumination color image. Optik Jan. 2014;125(6):1795–9.
- [48] Mohamed AW, Suganthan PN. Real-parameter unconstrained optimization based on enhanced fitness-adaptive differential evolution algorithm with novel mutation. Soft Comput Jan. 2018;22(10):3215–35.
- [49] Ahmed J, Salam Z. An enhanced adaptive P&O MPPT for fast and efficient tracking under varying environmental conditions. IEEE Trans Sustain Energy Jun. 2018;9(3):1487–96.
- [50] Meng Z, Pan JS, Kong L. Parameters with adaptive learning mechanism (PALM) for the enhancement of differential evolution. Knowl-Based Syst Jan. 2018;141:92–112.
- [51] Issa M, Hassanien AE, Oliva D, Helmi A, Ziedan I, Alzohairy A. ASCA-PSO: Adaptive sine cosine optimization algorithm integrated with particle swarm for pairwise local sequence alignment. Expert Syst Appl 2018;99:56–70.
- [52] Shi Z, Feng Y, Zhao M, Zhang E, He L. Normalised gamma transformation-based contrast-limited adaptive histogram equalisation with colour correction for sand–dust image enhancement. IET Image Proc 2020;14(4):747–56.
- [53] Yu Z, Zheng J, Ma L, et al. The predictive accuracy of the black hole sign and the spot sign for hematoma expansion in patients with spontaneous intracerebral hemorrhage. Neurol Sci Sept. 2017;38(9):1591–7.
- [54] Hajibandeh S, Hajibandeh S, Deering R, et al. Accuracy of routinely collected comorbidity data in patients undergoing colectomy: a retrospective study. Int J Colorectal Dis Aug. 2017;32(9):1341–4.
- [55] Yao RJR, Andrade JG, Deyell MW, et al. Sensitivity, specificity, negative and positive predictive values of identifying atrial fibrillation using administrative data: a systematic review and meta-analysis. Clin Epidemiol Jan. 2019;11:753.
- [56] Delate T, Jones AE, Clark NP, Witt DM. Assessment of the coding accuracy of warfarin-related bleeding events. Thrombos Res 2017;159:86–90.
- [57] Nayak SR, Nayak DR, Sinha U, et al. Application of deep learning techniques for detection of COVID-19 cases using chest X-ray images: A comprehensive study. Biomed Signal Process Control Feb. 2021;64 102365.
- [58] Duffey RB, Zio E. Analysing recovery from pandemics by Learning Theory: the case of CoVid-19. IEEE Access Jun. 2020;8:110789–95.
- [59] Toğaçar M, Ergen B, Cömert Z, ‘‘COVID-19 detection using deep learning models to exploit Social Mimic Optimization and structured chest X-ray images using fuzzy color and stacking approaches,” Comput Biol Med, vol. 121, p. 103805, May. 2020.
Typ dokumentu
Bibliografia
Identyfikator YADDA
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