Article contents
Advancements in Early Detection of Lung Cancer in Public Health: A Comprehensive Study Utilizing Machine Learning Algorithms and Predictive Models
Authors
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Mohammad Shafiquzzaman Bhuiyan
Department of Business Administration, Westcliff University, Irvine, California
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Imranul Kabir Chowdhury
Department of Business & Information Technology, Missouri University of Science and Technology, USA
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Mahfuz Haider
Department of Revenue Cycle, University of Toledo Physicians, Ohio, USA
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Afjal Hossain Jisan
Department of Supply Chain & Information Systems, The Pennsylvania State University, University Park, Pennsylvania, USA
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Rasel Mahmud Jewel
Department of Business Administration, Westcliff University, Irvine, California, USA
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Rumana Shahid
Department of Management of Science and Quantitative Methods, Gannon University, USA
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Mst Zannatun Ferdus
Department of Science in Information Technology (MSIT), Washington University of Science and Technology Alexandria, Virginia, USA
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Cynthia Ummay Siddiqua
Department of Pharmacy Administration, University of Mississippi, Oxford, Mississippi, US
Abstract
Lung cancer stands as the leading cause of death in the United States, attributed to factors such as the spontaneous growth of malignant tumors in the lungs that can metastasize to other parts of the body, posing severe threats. Notably, smoking emerges as a predominant external factor contributing to lung problems and ultimately leading to lung cancer. Nevertheless, early detection presents a pivotal strategy for preventing this lethal disease. Leveraging machine learning, we aspire to develop robust algorithms capable of predicting lung cancer at its nascent stage. Such a model could prove instrumental in aiding physicians in making informed decisions during the diagnostic process, determining whether a patient necessitates an intensive or standard level of diagnosis. This approach holds the potential to significantly reduce treatment costs, as physicians can tailor the treatment plan based on accurate predictions, thereby avoiding unnecessary and costly interventions. Our goal is to establish a sustainable model that accurately predicts the disease, and our findings reveal that XGBoost outperformed other models, achieving an impressive accuracy level of 96.92%. In comparison, LightGBM, AdaBoost, Logistic Regression, and Support Vector Machine achieved accuracies of 93.50%, 92.32%, 67.41%, and 88.02%, respectively.
Article information
Journal
Journal of Computer Science and Technology Studies
Volume (Issue)
6 (1)
Pages
113-121
Published
Copyright
Open access
This work is licensed under a Creative Commons Attribution 4.0 International License.
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