Volume 11 , Issue 2 , PP: 97-110, 2024 | Cite this article as | XML | Html | PDF | Full Length Article
R. Rajkumar 1 , Dınesh Valluru 2 , Siva Satya Sreedhar P. 3 , N. Ramshankar 4 , Sujatha S. 5 * , Somasundaram R. 6 , M. Sudha 7 , S. Navaneethan 8 *
Doi: https://doi.org/10.54216/JISIoT.110209
Recently, healthcare systems integrate the power of deep learning (DL) models with the connectivity and data processing capabilities of the Internet of Things (IoT) to enhance the early recognition and diagnosis of disease. Oral cancer diagnosis comprises the detection of cancerous or pre-cancerous abrasions in the oral cavity. Timely identification is essential for successful treatment and enhanced prognosis. Here is an overview of the key aspects of oral cancer diagnosis. One potential benefit of utilizing DL for oral cancer detection is that it analyses huge counts of data fast and accurately, and it could not need clear programming of the rules for recognizing abnormalities. This can create the procedure of detecting oral cancer more effective and efficient. Thus, the study presents an Enhanced Jaya Optimization Algorithm with Deep Learning Based Oral Cancer Classification (EJOADL-OCC) method. The presented EJOADL-OCC method aims to classify and detect the existence of oral cancer accurately and effectively. To accomplish this, the presented EJOADL-OCC method initially exploits median filtering for the noise elimination. Next, the feature vector generation process is performed by the residual network (ResNetv2) model with EJOA as a hyperparameter optimizer. For accurate classification of oral cancer, a continuously restricted Boltzmann machine with a deep belief network (CRBM-DBN) model. The simulated validation of the EJOADL-OCC algorithm is tested by the series of simulations and the outcome demonstrates its supremacy over present DL approaches.
Healthcare , Oral cancer , Deep learning , Computer-assisted diagnoses , Internet of Things , Jaya Optimization Algorithm , Medical imaging
[1] Lin, H., Chen, H., Weng, L., Shao, J. and Lin, J., 2021. Automatic detection of oral cancer in smartphone-based images using deep learning for early diagnosis. Journal of Biomedical Optics, 26(8), p.086007.
[2] López-Cortés, X.A., Matamala, F., Venegas, B. and Rivera, C., 2022. Machine-Learning Applications in Oral Cancer: A Systematic Review. Applied Sciences, 12(11), p.5715.
[3] Prabhakaran, R. and Mohana, D.J., 2020. Detection of Oral Cancer Using Machine Learning Classification Methods. International Journal of Electrical Engineering and Technology, 11(3).
[4] Sharma, D., Kudva, V., Patil, V., Kudva, A. and Bhat, R.S., 2022. A Convolutional Neural Network Based Deep Learning Algorithm for Identification of Oral Precancerous and Cancerous Lesion and Differentiation from Normal Mucosa: A Retrospective Study. Engineered Science, 18, pp.278-287.
[5] Kouznetsova, V.L., Li, J., Romm, E. and Tsigelny, I.F., 2021. Finding distinctions between oral cancer and periodontitis using saliva metabolites and machine learning. Oral diseases, 27(3), pp.484-493.
[6] Siddalingappa, R. and Kanagaraj, S., 2022. K-nearest-neighbour algorithm to predict the survival time and classification of various stages of oral cancer: a machine learning approach. F1000Research, 11(70), p.70.
[7] Fu, Q., Chen, Y., Li, Z., Jing, Q., Hu, C., Liu, H., Bao, J., Hong, Y., Shi, T., Li, K. and Zou, H., 2020. A deep learning algorithm for detection of oral cavity squamous cell carcinoma from photographic images: A retrospective study. EClinicalMedicine, 27, p.100558.
[8] Bansal, K., Batla, R.K., Kumar, Y. and Shafi, J., 2022. Artificial Intelligence Techniques in Health Informatics for Oral Cancer Detection. In Connected e-Health (pp. 255-279). Springer, Cham.
[9] Song, B., Li, S., Sunny, S., Gurushanth, K., Mendonca, P., Mukhia, N., Patrick, S., Gurudath, S., Raghavan, S., Tsusennaro, I. and Leivon, S.T., 2021. Classification of imbalanced oral cancer image data from high-risk population. Journal of biomedical optics, 26(10), p.105001.
[10] Rauf, A.R.A., Isa, W.H.M., Khairuddin, I.M., Razman, M.A.M., Arzmi, B.M.H. and Majeed, A.P.A., 2022. The Classification of Oral Squamous Cell Carcinoma (OSCC) by Means of Transfer Learning. In Robot Intelligence Technology and Applications 6: Results from the 9th International Conference on Robot Intelligence Technology and Applications (Vol. 429, p. 386). Springer Nature.
[11] Lim, J.H., Tan, C.S., Chan, C.S., Welikala, R.A., Remagnino, P., Rajendran, S., Kallarakkal, T.G., Zain, R.B., Jayasinghe, R.D., Rimal, J. and Kerr, A.R., 2021, July. D’OraCa: deep learning-based classification of oral lesions with mouth landmark guidance for early detection of oral cancer. In Annual Conference on Medical Image Understanding and Analysis (pp. 408-422). Springer, Cham.
[12] Tanriver, G., Soluk Tekkesin, M. and Ergen, O., 2021. Automated detection and classification of oral lesions using deep learning to detect oral potentially malignant disorders. Cancers, 13(11), p.2766.
[13] Lu, J., Sladoje, N., Runow Stark, C., Darai Ramqvist, E., Hirsch, J.M. and Lindblad, J., 2020, June. A deep learning based pipeline for efficient oral cancer screening on whole slide images. In International Conference on Image Analysis and Recognition (pp. 249-261). Springer, Cham.
[14] Jeyaraj, P.R. and Samuel Nadar, E.R., 2019. Computer-assisted medical image classification for early diagnosis of oral cancer employing deep learning algorithm. Journal of cancer research and clinical oncology, 145(4), pp.829-837.
[15] Shamim, M.Z.M., Syed, S., Shiblee, M., Usman, M., Ali, S.J., Hussein, H.S. and Farrag, M., 2022. Automated detection of oral pre-cancerous tongue lesions using deep learning for early diagnosis of oral cavity cancer. The Computer Journal, 65(1), pp.91-104.
[16] Welikala, R.A., Remagnino, P., Lim, J.H., Chan, C.S., Rajendran, S., Kallarakkal, T.G., Zain, R.B., Jayasinghe, R.D., Rimal, J., Kerr, A.R. and Amtha, R., 2020. Automated detection and classification of oral lesions using deep learning for early detection of oral cancer. IEEE Access, 8, pp.132677-132693.
[17] Huang, C., Zhang, G., Chen, S. and de Albuquerque, V.H.C., 2022. An Intelligent Multisampling Tensor Model for Oral Cancer Classification. IEEE Transactions on Industrial Informatics, 18(11), pp.7853-7861.
[18] Ahmed Abdelhafeez, Hoda K. Mohamed, Skin Cancer Detection using Neutrosophic c-means and Fuzzy c-means Clustering Algorithms, Journal of Intelligent Systems and Internet of Things, Vol. 8 , No. 1 , (2023) : 33-42 (Doi : https://doi.org/10.54216/JISIoT.080103).
[19] Eman Shawky Mira,Ahmed M. Saaduddin Sapri,Rowaa F. Aljehanı,Bayan S. Jambı,Taseer Bashir,El-Sayed M. El-Kenawy,Mohamed Saber, Early Diagnosis of Oral Cancer Using Image Processing and Artificial Intelligence, Fusion: Practice and Applications, Vol. 14 , No. 1 , (2024) : 293-308 (Doi : https://doi.org/10.54216/FPA.140122).
[20] Zitar, R.A., Al-Betar, M.A., Awadallah, M.A., Doush, I.A. and Assaleh, K., 2022. An intensive and comprehensive overview of JOA, its versions and applications. Archives of Computational Methods in Engineering, 29(2), pp.763-792.
[21] Parthiban, S., Harshavardhan, A., Neelakandan, S., Prashanthi, V., Alhassan Alolo, A.R.A. and Velmurugan, S., 2022. Chaotic Salp Swarm Optimization-Based Energy-Aware VMP Technique for Cloud Data Centers. Computational Intelligence and Neuroscience, 2022.
[22] Zhao, X., Liu, D. and Yan, X., 2023. Diameter Prediction of Silicon Ingots in the Czochralski Process Based on a Hybrid Deep Learning Model. Crystals, 13(1), p.36.
[23] https://www.kaggle.com/datasets/shivam17299/oral-cancer-lips-and-tongue-images
[24] Alabdan, R.; Alruban, A.; Hilal, A.M.; Motwakel, A. Artificial-Intelligence-Based Decision Making for Oral Potentially Malignant Disorder Diagnosis in Internet of Medical Things Environment. Healthcare 2023, 11, 113. https://doi.org/10.3390/healthcare 11010113