Early lung cancer diagnostic biomarker discovery by machine learning methods

• Published in: Translational oncology Vol. 14; no. 1; p. 100907
• Main Authors: Xie, Ying, Meng, Wei-Yu, Li, Run-Ze, Wang, Yu-Wei, Qian, Xin, Chan, Chang, Yu, Zhi-Fang, Fan, Xing-Xing, Pan, Hu-Dan, Xie, Chun, Wu, Qi-Biao, Yan, Pei-Yu, Liu, Liang, Tang, Yi-Jun, Yao, Xiao-Jun, Wang, Mei-Fang, Leung, Elaine Lai-Han
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 01.01.2021; Neoplasia Press; Elsevier
• Subjects: Biomarker; Early diagnosis; Lung cancer; Machine learning; Metabolites; Original article; Biomarker; Early diagnosis; Metabolites; Lung cancer; Machine learning
• ISSN: 1936-5233; 1936-5233
• DOI: 10.1016/j.tranon.2020.100907

•Early diagnosis could improve lung cancer survival rate.•The availability of blood-based screening could increase lung cancer patient uptake.•An interdisciplinary mechanism combines metabolomics and machine learning methods.•Metabolic biomarkers could be potential screening biomarkers for early detection of lung cancer.•Naïve Bayes is recommended as an exploitable tool for early lung tumor prediction. Early diagnosis has been proved to improve survival rate of lung cancer patients. The availability of blood-based screening could increase early lung cancer patient uptake. Our present study attempted to discover Chinese patients’ plasma metabolites as diagnostic biomarkers for lung cancer. In this work, we use a pioneering interdisciplinary mechanism, which is firstly applied to lung cancer, to detect early lung cancer diagnostic biomarkers by combining metabolomics and machine learning methods. We collected total 110 lung cancer patients and 43 healthy individuals in our study. Levels of 61 plasma metabolites were from targeted metabolomic study using LC-MS/MS. A specific combination of six metabolic biomarkers note-worthily enabling the discrimination between stage I lung cancer patients and healthy individuals (AUC = 0.989, Sensitivity = 98.1%, Specificity = 100.0%). And the top 5 relative importance metabolic biomarkers developed by FCBF algorithm also could be potential screening biomarkers for early detection of lung cancer. Naïve Bayes is recommended as an exploitable tool for early lung tumor prediction. This research will provide strong support for the feasibility of blood-based screening, and bring a more accurate, quick and integrated application tool for early lung cancer diagnostic. The proposed interdisciplinary method could be adapted to other cancer beyond lung cancer.