Identyfikatory
Warianty tytułu
Sieci neuronowe z Keras w diagnostyce zmian skórnych
Języki publikacji
Abstrakty
Melanoma is currently one of the most dangerous skin diseases, in addition many others appear in the population. Scientists are developing techniques for early non-invasive skin lesions diagnosis from dermatoscopic images, for this purpose neural networks are increasingly used. Many tools are being developed to allow for faster implementation of the network, including the Keras package. The article presents selected methods of diagnosing skin diseases, including the process of classification, features selection, extracting the skin lesion from the whole image.The described methods have been implemented using deep neural networks available in the Keras package. The article draws attention to the effectiveness, specificity, accuracy of classification based on available data sets, attention was paid to tools that allow for more effective operation of algorithms.
Melanoma jest obecnie jedną z najbardziej niebezpiecznych chorób skóry, oprócz niej pojawia się w populacji wiele innych. Naukowcy rozwijają techniki wczesnego nieinwazyjnego diagnozowania zmian skórnych z obrazów dermatoskopowych, w tym celu coraz częściej wykorzystywane są sieci neuronowe. Powstaje wiele narzędzi powzalajcych na szybszą implementację sieci należy do niej pakiet Keras. W artykule przedstawiono wybrane metody diagnostyki chorób skóry, należy do nich proces klasyfikacji, selekcji cech, wyodrębnienia zmiany skórnej z całego obrazu. Opisane metody zostały zostały zaimplementowane za pomocą dostępnych w pakiecie Keras głębokich sieci neuronowych. W artykule zwrócono uwagę na skuteczność, specyficzność, dokładność klasyfikacji w oparciu o dostępne zestawy danych, zwrócono uwagę na narzędzi pozwalające na efektywniejsze działanie algorytmów.
Rocznik
Tom
Strony
40--43
Opis fizyczny
Bibliogr. 37 poz., tab., rys., wykr.
Twórcy
- Lublin University of Technology, Department of Electronics and Information Technology, Lublin, Poland
Bibliografia
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- [5] Barata C., Celebi M., Marques J.: A survey of feature extraction in dermoscopy image analysis of skin cancer. IEEE Journal of Biomedical and Health Informatics 23(3), 2019, 1096–1109.
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- [10] Esteva A.: Dermatologist-level classification of skin cancer with deep neural networks. Nat. Res. 542(7639), 2017, 115–118.
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- [12] Ge Z., Demyanov S., Chakravorty R., Bowling A., Garnavi R.: Skin disease recognition using deep saliency features and multimodal learning of dermoscopy and clinical images. Descoteaux M., Maier-Hein L., Franz A., Jannin P., Collins D. L., Duchesne S. (eds.), Springer, Cham LNCS 10435, 250–258, 2017.
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- [17] Katapadi A. B.: Evolving strategies for the development and evaluation of a computerised melanoma image analysis system. Comput.Methods Biomech. Biomed. Eng., Imag Visual. 6, 2018, 465–472.
- [18] Li Y., Shen L.: Skin Lesion Analysis towards Melanoma Detec-tion Using Deep Learning Network. arXiv.org > cs > arXiv:1703.00577, Computer Vision and Pattern Recognition 2017 (v2).
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- [20] Lopez A. R.: Skin lesion classification from dermoscopic images using deep learning techniques. Proc. 13th IASTED Int. Conf. Biomed. Eng. 2017, 49–54.
- [21] Majumder S., Ahsan Ullah M.: Feature extraction from der-moscopy images for an effective diagnosis of melanoma skin cancer. 10th International Conference on Electrical and Compu-ter Engineering Bangladesh, 2018, 185–188.
- [22] Marchetti M. A., Codella N. C., Dusza S. W., Gutman D. A., Helba B., Kalloo A.: Results of the 2016 international skin imaging collaboration international symposium on biomedical imaging challenge: comparison of the accuracy of computer algorithms to dermatologists for the diagnosis of melanoma from dermoscopic images. J Am Acad Dermatol 78, 2018, 270–277.
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- [28] Nida N., Irtaza A., Javed A., Yousaf M., Mahmood M.: Melanoma lesion detection and segmentation using deep region based convolutional neural network and fuzzy C-means clustering. International Journal of Medical Informatics 124, 2019, 37–48.
- [29] Panja A., Jackson J. Ch., Quadir Md. A.: An Approach to Skin Cancer Detection Using Keras and Tensorflow. Journal of Physics: Conference Series 1911 012032, 2021, [http://doi.org/10.1088/1742-6596/1911/1/012032].
- [30] Rahi M., Khan F., Mahtab M., Amanat Ullah A., Alam M. G., Alam M.: Detection Of Skin Cancer Using Deep Neural Networks, IEEE Asia-Pacific Conference on Computer Science and Data Engineering (CSDE), 2019, 1–7, [http://doi.org/10.1109/CSDE48274.2019.9162400].
- [31] Romero Lopez A., Xiro-i-Nieto X., Burdick J., Marques O.: Skin lesion classification from dermoscopic images using deep learning techniques. 13th IASTED International Conference on Biomedical Engineering (BioMed), 49–54, 2017, [http://doi.org/10.2316/P.2017.852-053]
- [32] Sherif F., Mohamed W. A., Mohra A. S.: Skin lesion analysis toward melanoma detection using deep learning techniques. INTL Journal of Electronics and Telecommunications 65(4), 2019, 597–602.
- [33] Villa-Pulgarin J., Ruales-Torres A., Arias-Garzón D., Bravo-Ortiz M., Arteaga-Arteaga H., Mora-Rubio A., Alzate-Grisales J., Mercado-Ruiz E., Hassaballah M., Orozco-Arias S., Cardona-Morales O., Tabares-Soto R.: Optimized Convolutional Neural Network Models for Skin Lesion Classification. Computers, Materials & Continua Tech Science Press, CMC 70(2), 2022, [http://doi.org/10.32604/cmc.2022.019529].
- [34] Wang Y., Cai J., Louie D., Wang J., Lee T.: Incorporating clinical knowledge with constrained classifier chain into a multimodal deep network for melanoma detection. Computers in Biology and Medicine 137, 2021, 104812.
- [35] Young A. T., Xiong M., Pfau J., Keiser M. J, Wei M.L.: Artificial intelligence in dermatology: A Primer. Journal of Investigative Dermatology 140, 2020, 1504–1512.
- [36] Yu L., Chen H., Dou Q., Qin J., Heng P. A.: Automated melanoma recognition in dermoscopy images via very deep residual networks. IEEE Trans. Med. Imaging 36(4), 2017, 994–1004.
- [37] Zhang J., Xie Y., Wu Q., Xia Y.: Skin lesion classification in dermoscopy images using synergic deep learning, Springer Nature Switzerland. LNCS 11071, 2018, 12–20.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-039b3db6-c295-48c9-b155-8231a2eab6e4