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A novel end-to-end deep learning approach for cancer detection based on microscopic medical images

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
As a result of late diagnosis, cancer is the second leading cause of death in most countries in the world. Usually, many cases of cancer are diagnosed at an advanced stage, which reduces the chances of recovery from the disease due to the inability to provide appropriate treatment. The earlier cancer is detected, the more effective the treatment can be, especially for incurable cancers, which can result in a shorter life expectancy due to the rapid spread of the disease. The early detection of cancer also greatly reduces the financial consequences of it, as the cost of treating it in its early stages is much lower than in its other stages. Therefore, several previous studies focus on developing computer-aided cancer diagnosis systems (CACDs) that can detect cancer in its earliest stages automatically. In this paper, a novel approach is proposed for cancer detection. The proposed approach is an end-to-end deep learning approach, where the input images are fed directly to the deep model for final decision. In this research, the accuracy of a new deep convolutional neural network (CNN) for cancer detection is explored. The microscopic medical images obtained from the cancer database were used to evaluate our study, which were labelled as normal and abnormal images. The presented model achieved an accuracy of 99.99%, which is the highest accuracy compared with other deep learning models. Finally, the proposed approach would be very useful and effective, especially in low-income countries where referral systems for patients with suspected cancer are often unavailable, resulting in delayed and fragmented care.
Twórcy
  • Information Technology Department, Faculty of computers and information, Menoufia University, Egypt
  • City of Culture and Science, Higher Institute for Computer Science and Information Systems, Cairo, Egypt
autor
  • City of Culture and Science, Higher Institute for Computer Science and Information Systems, Cairo, Egypt
  • AGH University of Science and Technology, Department of Biocybernetics and Biomedical Engineering, Krakow, Poland
  • EIAS Data Science Lab, College of Computer and Information Sciences, Prince Sultan University, Riyadh, Saudi Arabia
  • Department of Mathematics and Computer Science, Faculty of Science, Menoufia University, Shebin El-Kom, Egypt
  • Department of Computer Science, Faculty of Computer Science and Telecommunications, Cracow University of Technology, Warszawska 24, 31-155 Krakow, Poland
  • Institute of Theoretical and Applied Informatics, Polish Academy of Sciences, Gliwice, Poland
Bibliografia
  • [1] WHO, Cancer, 2021, https://www.who.int/news-room/factsheets/detail/cancer. [Accessed: 13-01-2022].
  • [2] Etzioni R, Urban N, Ramsey S, McIntosh M, Schwartz S, Reid B, et al. The case for early detection. Nat Rev Cancer 2003;3(4):243–52.
  • [3] Sadoughi F, Kazemy Z, Hamedan F, Owji L, Rahmanikatigari M, Azadboni TT. Artificial intelligence methods for the diagnosis of breast cancer by image processing: a review. Breast Cancer: Targets Ther 2018;10:219.
  • [4] Książek W, Hammad M, Pławiak P, Acharya UR, Tadeusiewicz R. Development of novel ensemble model using stacking learning and evolutionary computation techniques for automated hepatocellular carcinoma detection. Biocybern Biomed Eng 2020;40(4):1512–24.
  • [5] Kumar Y, Gupta S, Singla R, Hu YC. A systematic review of artificial intelligence techniques in cancer prediction and diagnosis. Arch Comput Methods Eng 2021:1–28.
  • [6] Huang S, Yang J, Fong S, Zhao Q. Artificial intelligence in cancer diagnosis and prognosis: Opportunities and challenges. Cancer Lett 2020;471:61–71.
  • [7] Abdollahi J, Keshandehghan A, Gardaneh M, Panahi Y, Gardaneh M. Accurate detection of breast cancer metastasis using a hybrid model of artificial intelligence algorithm. Arch Breast Cancer 2020:22–8.
  • [8] Perincheri S, Levi AW, Celli R, Gershkovich P, Rimm D, Morrow JS, et al. An independent assessment of an artificial intelligence system for prostate cancer detection shows strong diagnostic accuracy. Mod Pathol 2021;34(8):1588–95.
  • [9] Hammad M, Kandala RN, Abdelatey A, Abdar M, Zomorodi-Moghadam M, San Tan R, et al. Automated detection of shockable ECG signals: a review. Inf Sci 2021;571:580–604.
  • [10] Hemanth DJ, Estrela VV, editors. Deep learning for image processing applications. IOS Press; 2017.
  • [11] Razzak MI, Naz S, Zaib A. Deep learning for medical image processing: Overview, challenges and the future. Classif BioApps 2018:323–50.
  • [12] Maier A, Syben C, Lasser T, Riess C. A gentle introduction to deep learning in medical image processing. Zeitschrift für Medizinische Physik 2019;29(2):86–101.
  • [13] Sakr AS, Pławiak P, Tadeusiewicz R, Hammad M. Cancelable ECG biometric based on combination of deep transfer learning with DNA and amino acid approaches for human authentication. Inf Sci 2022;585:127–43.
  • [14] El-Rahiem A, Hammad M. A multi-fusion IoT authentication system based on internal deep fusion of ECG signals. In Security and Privacy Preserving for IoT and 5G Networks 2022 (pp. 53-79). Springer, Cham.
  • [15] Sedik A, Hammad M, Abd El-Latif AA, El-Banby GM, Khalaf AA, Abd El-Samie FE, et al. Deep learning modalities for biometric alteration detection in 5G networks-based secure smart cities. IEEE Access 2021;9:94780–8.
  • [16] Hammad M, Zhang S, Wang K. A novel two-dimensional ECG feature extraction and classification algorithm based on convolution neural network for human authentication. Future Gener Comput Syst 2019;101:180–96.
  • [17] Hammad M, Alkinani MH, Gupta BB, El-Latif A, Ahmed A. Myocardial infarction detection based on deep neural network on imbalanced data. Multimedia Syst 2021;6:1–3.
  • [18] Hammad M, Iliyasu AM, Subasi A, Ho ES, Abd El-Latif AA. A multitier deep learning model for arrhythmia detection. IEEE Trans Instrum Meas 2020;70:1–9.
  • [19] Sedik A, Hammad M, El-Samie A, Fathi E, Gupta BB, El-Latif A, et al. Efficient deep learning approach for augmented detection of Coronavirus disease. Neural Comput Appl 2021;19:1–8.
  • [20] Amrani M, Hammad M, Jiang F, Wang K, Amrani A. Very deep feature extraction and fusion for arrhythmias detection. Neural Comput Appl 2018;30(7):2047–57.
  • [21] Zhang Y, Shi X, Zhang H, Cao Y, Terzija V. Review on deep learning applications in frequency analysis and control of modern power system. Int J Electr Power Energy Syst 2022;136:107744.
  • [22] Saber S, Amin KM, Adel HM. An efficient person reidentification method based on deep transfer learning techniques. IJCI Int J Comput Inf 2021;8(2):94–9.
  • [23] Quaak M, van de Mortel L, Thomas RM, van Wingen G. Deep learning applications for the classification of psychiatric disorders using neuroimaging data: systematic review and meta-analysis. NeuroImage: Clin 2021;30:102584.
  • [24] Dixit P, Silakari S. Deep learning algorithms for cybersecurity applications: A technological and status review. Comput Sci Rev 2021;39:100317.
  • [25] Rezaeilouyeh H, Mollahosseini A, Mahoor MH. Microscopic medical image classification framework via deep learning and shearlet transform. J Med Imaging 2016;3(4):044501.
  • [26] Danaee P, Ghaeini R, Hendrix DA. A deep learning approach for cancer detection and relevant gene identification. In: Pacific Symposium on Biocomputing. p. 219–29.
  • [27] Kumar D, Jain N, Khurana A, Mittal S, Satapathy SC, Senkerik R, et al. Automatic detection of white blood cancer from bone marrow microscopic images using convolutional neural networks. IEEE Access 2020;8:142521–31.
  • [28] Khouani A, El Habib DM, Mahmoudi SA, Chikh MA, Benzineb B. Automated recognition of white blood cells using deep learning. Biomed Eng Lett 2020;10(3):359–67.
  • [29] Ding Y, Yang Y, Cui Y. Deep learning for classifying of white blood cancer. In: ISBI 2019 C-NMC Challenge: Classification in Cancer Cell Imaging 2019 (pp. 33-41). Springer, Singapore.
  • [30] Hu Z, Tang J, Wang Z, Zhang K, Zhang L, Sun Q. Deep learning for image-based cancer detection and diagnosis- A survey. Pattern Recogn 2018;83:134–49.
  • [31] Manhas J, Gupta RK, Roy. A review on automated cancer detection in medical images using machine learning and deep learning based computational techniques: challenges and opportunities. Arch Comput Methods Eng 2021:1–41.
  • [32] Gehlot S, Gupta A, Gupta R. SDCT-AuxNeth: DCT augmented stain deconvolutional CNN with auxiliary classifier for cancer diagnosis. Med Image Anal 2020;61:101661.
  • [33] Fakoor R, Ladhak F, Nazi A, Huber M. Using deep learning to enhance cancer diagnosis and classification. In: Proceedings of the International Conference on Machine Learning 2013 Jun (Vol. 28, pp. 3937-3949). ACM, New York, USA.
  • [34] Pianpanit T, Lolak S, Sawangjai P, Sudhawiyangkul T, Wilaiprasitporn T. Parkinson’s disease recognition using SPECT image and interpretable AI: A tutorial. IEEE Sens J 2021.
  • [35] Ausawalaithong W, Thirach A, Marukatat S, Wilaiprasitporn T. Automatic lung cancer prediction from chest X-ray images using the deep learning approach. In: 2018 11th Biomedical Engineering International Conference (BMEiCON) 2018 Nov 21 (pp. 1-5). IEEE.
  • [36] Dhahri H, Al Maghayreh E, Mahmood A, Elkilani W, Faisal NM. Automated breast cancer diagnosis based on machine learning algorithms. J Healthc Eng 2019:2019.
  • [37] Ghasemzadeh A, Sarbazi Azad S, Esmaeili E. Breast cancer detection based on Gabor-wavelet transform and machine learning methods. Int J Mach Learn Cybern 2019;10(7):1603–12.
  • [38] Karabatak M. A new classifier for breast cancer detection based on Naïve Bayesian. Measurement 2015;72:32–6.
  • [39] Zheng B, Yoon SW, Lam SS. Breast cancer diagnosis based on feature extraction using a hybrid of K-means and support vector machine algorithms. Expert Syst Appl 2014;41(4):1476–82.
  • [40] Mohapatra S, Abhishek NV, Bardhan D, Ghosh AA, Mohanty S. Comparison of MobileNet and ResNet CNN architectures in the CNN-based skin cancer classifier model. Mach Learn Healthc Appl 2021;12:169–86.
  • [41] Jahangeer GS, Rajkumar TD. Early detection of breast cancer using hybrid of series network and VGG-16. Multimedia Tools Appl 2021;80(5):7853–86.
  • [42] Gupta R, Gehlot S, Gupta A. C-NMC: B-lineage acute lymphoblastic leukaemia: A blood cancer dataset. Med Eng Phys 2022;103:103793.
  • [43] Gupta A, Gupta R, Gehlot S, Goswami S. Segpc-2021: Segmentation of multiple myeloma plasma cells in microscopic images. IEEE Dataport 2021;1(1):1.
  • [44] Goswami S, Mehta S, Sahrawat D, Gupta A, Gupta R. Heterogeneity loss to handle intersubject and intrasubject variability in cancer. ICLR Workshop: AI for Affordable Healthcare; 2020.
  • [45] Pan Y, Liu M, Xia Y, Shen D. Neighborhood-correction algorithm for classification of normal and malignant cells. In: ISBI, C-NMC Challenge: Classification in Cancer Cell Imaging. Singapore: Springer; 2019. p. 73–82.
  • [46] Verma E, Singh V. ISBI challenge 2019: Convolution neural networks for B-ALL cell classification. In: ISBI 2019 C-NMC Challenge: Classification in Cancer Cell Imaging 2019 (pp. 131-139). Springer, Singapore.
  • [47] Gelasca ED, Byun J, Obara B, Manjunath BS. Evaluation and benchmark for biological image segmentation. In: 15th IEEE International Conference on Image Processing 2008 Oct 12 (pp. 1816-1819). IEEE.
  • [48] Weinstein JN, Collisson EA, Mills GB, Shaw KRM, Ozenberger BA, Ellrott K, et al. Nat Genet 2013;45:1113.
  • [49] Hatipoglu N, Bilgin G. Classification of histopathological images using convolutional neural network. In: 4th International Conference on Image Processing Theory, Tools and Applications (IPTA) 2014 Oct 14 (pp. 1-6). IEEE.
  • [50] Benazzouz M, Baghli I, Benomar A, Ammar M, Benmouna Y, Chikh M. Evidential segmentation scheme of bone marrow images. Adv Image Video Process 2016;4(1):37.
  • [51] Duggal R, Gupta A, Gupta R, Wadhwa M, Ahuja C. Overlapping cell nuclei segmentation in microscopic images using deep belief networks. In: Proceedings of the Tenth Indian Conference on Computer Vision, Graphics and Image Processing 2016 Dec 18 (pp. 1-8).
  • [52] Hammad M, Iliyasu AM, Elgendy IA, Abd El-Latif AA. End-to-end data authentication deep learning model for securing IoT configurations. Human-Centric Comput Inf Sci 2022;30:12.
  • [53] Sahlol AT, Kollmannsberger P, Ewees AA. Efficient classification of white blood cell leukemia with improved swarm optimization of deep features. Sci Rep. 2020;10(1):1-1.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-0b6912ec-5763-4026-8a4e-f2d151f1e584
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