Identifying Lung Cancer Using CT Scan Images Based on Artificial Intelligence
DOI:
https://doi.org/10.56532/mjsat.v2i1.34Keywords:
Lung Cancer, CT Image Segmentation, Image Processing, X- RayAbstract
Lung cancer is among the leading cause of death among men and women. Early detection of lung cancers can increase the possibility of survival amongst patients. The preferred 5-years survival rate for lung most cancers sufferers will increase from 16% to 50% if the disease is detected on time. Computerized tomography (CT) is frequently used for diagnosis and is more efficient than X-ray. However, the images need to be reviewed by a qualified physician who specializes in interpreting the CT scan. This may lead to misinterpretation and conflicting reports among physicians. Therefore, a lung cancer detection system that uses image processing methods to categorize lung cancer in CT images will be more consistent and precise. This paper presents a lung cancer detection system using the Artificial Intelligence (AI) method. The study uses Median, Gaussian, and Watershed segments to reduce noisy and shredded CT images. Then, the Weight Optimization Neural Network method was used to improve accuracy and reduce the computational time. The results were compared with previous works and shows higher accuracy and shorter computational time.
References
Sharma, S. (2018). A two-stage hybrid ensemble classifier-based diagnostic tool for chronic kidney disease diagnosis using optimally selected reduced feature set. International Journal of Intelligent Systems and Applications in Engineering, 6(2), 113-122.
Podolsky, M. D., Barchuk, A. A., Kuznetcov, V. I., Gusarova, N. F., Gaidukov, V. S., & Tarakanov, S. A. (2016). Evaluation of machine learning algorithm utilization for lung cancer classification based on gene expression levels. Asian Pacific journal of cancer prevention, 17(2),835-838.
Gindi, A., Attiatalla, T. A., & Sami, M. M. (2014). A comparative study for comparing two feature extraction methods and two classifiers in the classification of early-stage lung cancer diagnosis of chest x-ray images. Journal of American Science, 10(6), 13-22.
Suzuki, K., Kusumoto, M., Watanabe, S. I., Tsuchiya, R., & Asamura, H. (2006). Radiologic classification of small adenocarcinoma of the lung: radiologic-pathologic correlation and its prognostic impact. The Annals of thoracic surgery, 81(2), 413-419.
Aggarwal, T., Furqan, A., & Kalra, K. (2015, August). Feature extraction and LDA-based classification of lung nodules in chest CT scan images. In 2015 International Conference on Advances in Computing, Communications, and Informatics (ICACCI) (pp. 1189-1193). IEEE.
Jin, X. Y., Zhang, Y. C., & Jin, Q. L. (2016, December). Pulmonary nodule detection based on CT images using convolution neural network. In 2016 9th International symposium on computational intelligence and design (ISCID) (Vol. 1, pp. 202-204). IEEE.
Maurer, A. (2021). An Early Prediction of Lung Cancer using CT Scan Images. Journal of Computing and Natural Science, 39-44.
Ignatious, S., & Joseph, R. (2015, April). Computer-aided lung cancer detection system. In 2015 Global Conference on Communication Technologies (GCCT) (pp. 555-558). IEEE.
Ghorai, S., Mukherjee, A., Sengupta, S., & Dutta, P. K. (2010). Cancer classification from gene expression data by NPPC ensemble. IEEE/ACM Transactions on Computational Biology and Bioinformatics, 8(3), 659-671.
Li, K., Liu, K., Zhong, Y., Liang, M., Qin, P., Li, H., & Liu, X. (2021). Assessing the predictive accuracy of lung cancer, metastases, and benign lesions using an artificial intelligence-driven computer aided diagnosis system. Quantitative Imaging in Medicine and Surgery, 11(8), 3629.
Das, R., & Sengur, A. (2010). Evaluation of ensemble methods for diagnosing valvular heart disease. Expert Systems with Applications, 37(7), 5110-5115.
Costa, V. S., Farias, A. D. S., Bedregal, B., Santiago, R. H., & Canuto, A. M. D. P. (2018). Combining multiple algorithms in classifier ensembles using generalized mixture functions. Neurocomputing, 313, 402-414.
Dande, P., & Samant, P. (2018). Acquaintance to artificial neural networks and use of artificial intelligence as a diagnostic tool for tuberculosis: a review. Tuberculosis, 108, 1-9.
Obulesu, O., Kallam, S., Dhiman, G., Patan, R., Kadiyala, R., Raparthi, Y., & Kautish, S. (2021). Adaptive diagnosis of lung cancer by deep learning Classification Using Wilcoxon gain and generator. Journal of Healthcare Engineering, 2021.
Khosravi, P., Kazemi, E., Imielinski, M., Elemento, O., & Hajirasouliha, I. (2018). Deep convolutional neural networks enable the discrimination of heterogeneous digital pathology images. EBioMedicine, 27, 317-328.
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Copyright (c) 2022 MD. Ismail Hossain Sadhin, Methila Farzana Woishe, Nila Sultana, Tamanna Zaman Bristy
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