Abstract
Cancer remains a formidable challenge in the field of medical research, necessitating novel approaches to better comprehend its complex dynamics and develop effective treatment strategies. This article presents a comprehensive review of the latest mathematical models employed in the study of tumor growth dynamics and its treatment. The heterogeneous nature of cancer poses unique complexities, requiring interdisciplinary efforts involving mathematics and other relevant domains. Through an extensive examination of the literature, various mathematical frameworks ranging from ordinary differential equation systems to stochastic hybrid multiscale models are discussed. It highlights the crucial role played by mathematical modeling in understanding the diverse characteristics of tumors, including growth patterns, angiogenesis, cell-cell interactions, and the effects of treatment. These models facilitate a deeper comprehension of cancer progression, resistance mechanisms, and the influence of microenvironmental factors. The review emphasizes the importance of combining multiple therapeutic approaches to overcome treatment resistance and optimize patient outcomes. By exploring the synergistic effects of combining different therapies, mathematical models assist in identifying optimal treatment sequences, minimizing side effects, and improving overall treatment efficacy. In conclusion, this review contributes to the growing body of knowledge in mathematical oncology and highlights the vital role of mathematical modeling in comprehending tumor dynamics and guiding treatment decisions.
Keywords
Mathematical modeling, Tumor dynamics, Cancer treatment model, Multiscale modeling, Tumor microenvironment