Machine learning approaches in cancer detection and treatment

Abstract

Cancer has become the second leading cause of mortality worldwide, and early de-tection and adequate treatment are crucial in reducing the cancer burden. Metastasis,which involves malignant cells detaching from the primary tumor and colonizing otherdistant organs, is the leading cause of cancer-related deaths. The microenvironment,immune cells, stromal cells, and drug selection pressures influence tumors hetero-geneity and dynamicity, making it challenging to select the most effective treatmentapproach throughout the entire course of the disease. Liquid biopsy and single-celltranscriptomics have emerged as promising techniques for cancer detection. Bodily flu-ids such as blood, urine, and saliva provide rich biomarkers. Circulating tumor cellsand other tumor-associated cell products have been identified in the bloodstream, pro-viding potential biomarkers for cancer detection. Through serial blood analysis, liquidbiopsy techniques can help track spatial and temporal heterogeneity in tumor biology.Characterizing circulating tumor cells (CTCs) provides essential biological informa-tion about the disease as they are the primary live tumor cells responsible for metas-tasis. Existing CTC detection methods rely on surface markers, which may be shedduring the epithelial-to-mesenchymal (EMT) process or due to various stressors in theblood. Therefore, marker-free detection and characterization of CTCs are necessary.To achieve the best possible outcomes, it is crucial to manage cancer and any clinicalfactors that may impact treatment response or contribute to disease relapse. By identi-fying and addressing these factors, healthcare providers can develop effective treatmentplans and improve overall cancer management. This approach can help patients achievelonger-term remission and better quality of life.Over the past two decades, machine learning (ML) has shown tremendous potentialin enhancing cancer diagnosis and treatment accuracy and efficiency.