Cancer Diagnosis in Endoscopic Images using Discrete Wavelet Transform
Subject Areas : Majlesi Journal of Telecommunication DevicesSinan Ghanem 1 , Mehran Emadi 2
1 - Master student in Computer Engineering, Isfahan (Khorasgan) branch, Islamic Azad University Isfahan, Iran
2 - signal processing
Keywords: Diagnosis, Destroyed tissues, Endoscopic Images, Based Stomach.,
Abstract :
Stomach cancer destroys the tissues of the digestive system. This cancer is one of the deadliest diseases. Endoscopic imaging is used to diagnose cancer. In endoscopy, the diagnosis of gastric cancer is difficult due to the similarity of the tissues, the low contrast of the image and the background. In order to overcome these problems, discrete wavelet transform has been used to detect stomach cancer. In the proposed method, there are data registration, data preprocessing, feature extraction, dimensionality reduction, and classification. The features are extracted with the help of discrete wavelet transform and then dimension reduction is done with the help of principal component analysis. The proposed approach was evaluated on datasets collected from five classes, including gastritis, ulcer, esophagitis , bleeding, and healthy. Jungle Tassafi has a value above 99% in all evaluation criteria, which represents the advantages of this category. The results of this research show that this method is accurate and reliable in diagnosis.
[1] A. Abbasi, R. Sadeghi, A. Maleki, and G. Balakhani, “A meta-analysis of factors related to fertility attitudes, desires, and childbearing intentions in Iranian studies,” Interdisciplinary Studies in Humanities, vol. 14, no. 4, pp. 63-92, 2022.
[2] M. Emadi, Z. Jafarian Dehkordi, and M. Iranpour Mobarakeh, “Improving the Accuracy of Brain Tumor Identification in Magnetic Resonanceaging using Super-pixel and Fast Primal Dual Algorithm,” International Journal of Engineering, vol. 36, no. 3, pp. 505-512, 2023.
[3] M. Karimi, M. Harouni, A. Nasr, and N. Tavakoli, "Automatic lung infection segmentation of covid-19 in CT scan images," Intelligent Computing Applications for COVID-19, pp. 235-253: CRC Press, 2021.
[4] M. Harouni, M. Karimi, A. Nasr, H. Mahmoudi, and Z. Arab Najafabadi, "Health monitoring methods in heart diseases based on data mining approach: A directional review," Prognostic models in healthcare: Ai and statistical approaches, pp. 115-159: Springer, 2022.
[5] M. Harouni, M. Karimi, and S. Rafieipour, “Precise segmentation techniques in various medical images,” Artificial Intelligence and Internet of Things: Applications in Smart Healthcare, vol. 117, 2021.
[6] F. Mahmudi, M. Soleimani, and M. Naderi, “Some Properties of the Maximal Graph ofa Commutative Ring,” Southeast Asian Bulletin of Mathematics, vol. 43, no. 4, 2019.
[7] A. J. Moshayedi, A. S. Khan, Y. Shuxin, G. Kuan, H. Jiandong, M. Soleimani, and A. Razi, “E-Nose design and structures from statistical analysis to application in robotic: a compressive review,” EAI Endorsed Transactions on AI and Robotics, vol. 2, no. 1, pp. e1-e1, 2023.
[8] A. Rehman, M. Harouni, M. Karimi, T. Saba, S. A. Bahaj, and M. J. Awan, “Microscopic retinal blood vessels detection and segmentation using support vector machine and Kenearest neighbors,” Microscopy research and technique, vol. 85, no. 5, pp. 1899-1914, 2022.
[9] M. Soleimani, M. H. Naderi, and A. R. Ashrafi, “TENSOR PRODUCT OF THE POWER GRAPHS OF SOME FINITE RINGS,” Facta Universitatis, Series: Mathematics and Informatics, pp. 101-122, 2019.
[10] T. Itoh, H. Kawahira, H. Nakashima, and N. Yata, “Deep learning analyzes Helicobacter pylori infection by upper gastrointestinal endoscopy images,” Endoscopy international open, vol. 6, no. 02, pp. E139-E144, 2018.
[11] J. Podlasek, M. Heesch, R. Podlasek, W. Kilisiński, and R. Filip, “Real-time deep learning-based colorectal polyp localization on clinical video footage achievable with a wide array of hardware configurations,” Endoscopy International Open, vol. 9, no. 05, pp. E741-E748, 2021.
[12] M. Karimi, M. Harouni, E. I. Jazi, A. Nasr, and N. Azizi, "Improving monitoring and controlling parameters for alzheimer’s patients based on iomt," Prognostic models in healthcare: Ai and statistical approaches, pp. 213-237: Springer, 2022.
[13] E. Karimi, A. Ebrahimi, and M. R. Tavakoli, “How optimal PMU placement can mitigate cascading outages blackouts?,” International Transactions on Electrical Energy Systems, vol. 29, no. 6, pp. e12015, 2019.
[14] T. Yan, P. K. Wong, and Y.-Y. Qin, “Deep learning for diagnosis of precancerous lesions in upper gastrointestinal endoscopy: A review,” World Journal of Gastroenterology, vol. 27, no. 20, pp. 2531, 2021.
[15] M. Soleimani, F. Mahmudi, and M. Naderi, “Some results on the maximal graph of commutative rings,” Advanced Studies: Euro-Tbilisi Mathematical Journal, vol. 16, no. supp1, pp. 21-26, 2023.
[16] G. Zhang, M. Wang, and K. Liu, “Forest fire susceptibility modeling using a convolutional neural network for Yunnan province of China,” International Journal of Disaster Risk Science, vol. 10, no. 3, pp. 386-403, 2019.
[17] K. Namikawa, T. Hirasawa, T. Yoshio, J. Fujisaki, T. Ozawa, S. Ishihara, T. Aoki, A. Yamada, K. Koike, and H. Suzuki, “Utilizing artificial intelligence in endoscopy: a clinician’s guide,” Expert review of gastroenterology & hepatology, vol. 14, no. 8, pp. 689-706, 2020.
[18] M. Karimi, M. Harouni, and S. Rafieipour, "Automated medical image analysis in digital mammography," Artificial intelligence and internet of things, pp. 85-116: CRC Press, 2021.
[19] F. Navabifar, and M. Emadi, “A Fusion Approach Based on HOG and Adaboost Algorithm for Face Detection under Low-Resolution Images,” INTERNATIONAL ARAB JOURNAL OF INFORMATION TECHNOLOGY, vol. 19, no. 5, pp. 728-735, 2022.
[20] L. A. de Souza Jr, C. Palm, R. Mendel, C. Hook, A. Ebigbo, A. Probst, H. Messmann, S. Weber, and J. P. Papa, “A survey on Barrett's esophagus analysis using machine learning,” Computers in biology and medicine, vol. 96, pp. 203-213, 2018.
[21] F. Van Der Sommen, S. Zinger, and E. J. Schoon, "Computer-aided detection of early cancer in the esophagus using HD endoscopy images." pp. 216-227.
[22] F. Van Der Sommen, S. Zinger, E. J. Schoon, and P. H. De With, “Supportive automatic annotation of early esophageal cancer using local gabor and color features,” Neurocomputing, vol. 144, pp. 92-106, 2014.
[23] A. R. Hassan, and M. A. Haque, “Computer-aided gastrointestinal hemorrhage detection in wireless capsule endoscopy videos,” Computer methods and programs in biomedicine, vol. 122, no. 3, pp. 341-353, 2015.
[24] R. Mendel, A. Ebigbo, A. Probst, H. Messmann, and C. Palm, "Barrett’s esophagus analysis using convolutional neural networks," Bildverarbeitung für die Medizin 2017, pp. 80-85: Springer, 2017.
[25] Z. Zhang, L. Bai, P. Ren, and E. R. Hancock, “High-order graph matching kernel for early carcinoma EUS image classification,” Multimedia Tools and Applications, vol. 75, no. 7, pp. 3993-4012, 2016.
[26] S. Klomp, F. van der Sommen, A.-F. Swager, S. Zinger, E. J. Schoon, W. L. Curvers, and J. J. Bergman, "Evaluation of image features and classification methods for Barrett's cancer detection using VLE imaging." pp. 84-93.
[27] L. A. Passos, L. A. de Souza Jr, R. Mendel, A. Ebigbo, A. Probst, H. Messmann, C. Palm, and J. P. Papa, “Barrett’s esophagus analysis using infinity restricted Boltzmann machines,” Journal of Visual Communication and Image Representation, vol. 59, pp. 475-485, 2019.
[28] G. Liu, J. Hua, Z. Wu, T. Meng, M. Sun, P. Huang, X. He, W. Sun, X. Li, and Y. Chen, “Automatic classification of esophageal lesions in endoscopic images using a convolutional neural network,” Annals of translational medicine, vol. 8, no. 7, 2020.
[29] K.-b. Chen, Y. Xuan, A.-j. Lin, and S.-h. Guo, “Esophageal cancer detection based on classification of gastrointestinal CT images using improved Faster RCNN,” Computer Methods and Programs in Biomedicine, vol. 207, pp. 106172, 2021.
[30] V. Seena, and J. Yomas, "A review on feature extractionand denoising of ECG signal using wavelet transform." pp. 1-6.
[31] J. Gnitecki, and Z. M. Moussavi, “Separating heart sounds from lung sounds,” IEEE Engineering in medicine and biology magazine, vol. 26, no. 1, pp. 20, 2007.
[32] A. K. Lam, M. J. Bourke, R. Chen, R. Fiocca, F. Fujishima, S. Fujii, M. Jansen, P. Kumarasinghe, R. Langer, and S. Law, “Dataset for the reporting of carcinoma of the esophagus in resection specimens: recommendations from the International Collaboration on Cancer Reporting,” Human Pathology, vol. 114, pp. 54-65, 2021.
[33] M. S. Ayyaz, M. I. U. Lali, M. Hussain, H. T. Rauf, B. Alouffi, H. Alyami, and S. Wasti, “Hybrid deep learning model for endoscopic lesion detection and classification using endoscopy videos,” Diagnostics, vol. 12, no. 1, pp. 43, 2021.
[34] M. Sugimoto, Y. Kawai, Y. Akimoto, M. Hamada, E. Iwata, M. Murata, H. Mizuno, R. Niikura, N. Nagata, and M. Fukuzawa, “Third-Generation High-Vision Ultrathin Endoscopy Using Texture and Color Enhancement Imaging and Narrow-Band Imaging to Evaluate Barrett’s Esophagus,” Diagnostics, vol. 12, no. 12, pp. 3149, 2022.
[35] S. Iyer, D. Narmadha, G. N. Sundar, S. J. Priya, and K. M. Sagayam, "Deep Learning Model for Disease Prediction Using Gastrointestinal-Endoscopic Images." pp. 133-137.
[36] F. Mahmudi, M. Soleimani, and M. Naderi, "Some Properties of the Maximal Graph of a Commutative Ring," Southeast Asian Bulletin of Mathematics, vol. 43, no. 4, 2019.
[37] A. J. Moshayedi et al., "E-Nose design and structures from statistical analysis to application in robotic: a compressive review," EAI Endorsed Transactions on AI and Robotics, vol. 2, no. 1, pp. e1-e1, 2023.
[38] B. Heidari and M. Ramezanpour, "Reduction of intra-coding time for HEVC based on temporary direction map," Journal of Real-Time Image Processing, vol. 17, pp. 567-579, 2020.
[39] E. Karimi and A. Ebrahimi, "Probabilistic transmission expansion planning considering risk of cascading transmission line failures," International Transactions on Electrical Energy Systems, vol. 25, no. 10, pp. 2547-2561, 2015.
[40] E. Karimi and A. Ebrahimi, "Considering risk of cascading line outages in transmission expansion planning by benefit/cost analysis," International Journal of Electrical Power & Energy Systems, vol. 78, pp. 480-488, 2016.
[41] N. Najafabadi and M. Ramezanpour, "Mass center direction-based decision method for intraprediction in HEVC standard," Journal of Real-Time Image Processing, vol. 17, no. 5, pp. 1153-1168, 2020.
[42] A. Rehman, M. Harouni, F. Zogh, T. Saba, M. Karimi, and G. Jeon, "Detection of Lung Tumors in CT Scan Images using Convolutional Neural Networks," IEEE/ACM Transactions on Computational Biology and Bioinformatics, 2023.
[43] Y. Saberi, M. Ramezanpour, and R. Khorsand, "An efficient data hiding method using the intra prediction modes in HEVC," Multimedia Tools and Applications, vol. 79, pp. 33279-33302, 2020.
[44] R. G. Anaraky et al., "Older and younger adults are influenced differently by dark pattern designs," arXiv preprint arXiv:2310.03830, 2023.
[45] M. Emadi, M. Karimi, and F. Davoudi, "A Review on Examination Methods of Types of Working Memory and Cerebral Cortex in EEG Signals," Majlesi Journal of Telecommunication Devices, vol. 12, no. 3, 2023.