Dynamics of tumor interaction with the host immune system

A quantitative cellular automaton model of in vitro multicellular spheroid tumour growth ⋮ On a mathematical model of immune competition ⋮ MODELLING OF THE IMMUNE RESPONSE: CONCEPTUAL FRAMEWORKS AND APPLICATIONS ⋮ FROM MICROSCOPIC TO MACROSCOPIC DESCRIPTION FOR GENERALIZED KINETIC MODELS ⋮ HYBRID TWO SCALES MATHEMATICAL TOOLS FOR ACTIVE PARTICLES MODELLING COMPLEX SYSTEMS WITH LEARNING HIDING DYNAMICS ⋮ Qualitative analysis of kinetic-based models for tumor-immune system interaction ⋮ Numerical algorithm for the growth of human tumor cells and their responses to therapy ⋮ Chemotherapeutic treatments: A study of the interplay among drug resistance, toxicity and recuperation from side effects ⋮ On the kinetic and stochastic games theory for active particles: Some reasonings on open large living systems ⋮ NUMERICAL VERSUS EXPERIMENTAL DATA FOR PROSTATE TUMOUR GROWTH ⋮ FROM DISCRETE KINETIC AND STOCHASTIC GAME THEORY TO MODELLING COMPLEX SYSTEMS IN APPLIED SCIENCES ⋮ On the mathematical theory of post-Darwinian mutations, selection, and evolution ⋮ From the Boltzmann equation to generalized kinetic models in applied sciences ⋮ A mathematical model of periodically pulsed chemotherapy: Tumor recurrence and metastasis in a competitive environment ⋮ Effects of vascularization on lymphocyte/tumor cell dynamics: Qualitative features ⋮ Qualitative analysis of a nonlinear integrodifferential equation modeling tumor-host dynamics ⋮ Tumor-host relationship: The viewpoint of an immunologist towards applied mathematicians ⋮ From population dynamics to modelling the competition between tumors and immune system ⋮ Solution of a new class of nonlinear kinetic models of population dynamics ⋮ On the mathematical theory of living systems. I: Complexity analysis and representation ⋮ An algorithm for partial functional differential equations modeling tumor growth ⋮ From the mathematical kinetic theory of active particles to multiscale modelling of complex biological systems ⋮ On the kinetic theory for active particles: a model for tumor-immune system competition ⋮ The modelling of the immune competition by generalized kinetic (Boltzmann) models: Review and research perspectives ⋮ ON THE FOUNDATIONS OF CANCER MODELLING: SELECTED TOPICS, SPECULATIONS, AND PERSPECTIVES ⋮ Qualitative analysis and simulation of a nonlinear integro-differential system modeling tumor-immune cells competition ⋮ A kinetic theory approach for modelling tumour and macrophages heterogeneity and plasticity during cancer progression ⋮ Control in dormancy or eradication of cancer stem cells: mathematical modeling and stability issues ⋮ Bifurcation analysis for a mean field modelling of tumor and immune system competition ⋮ Mathematical modelling of the competition between tumors and immune system considering the role of the antibodies ⋮ Qualitative analysis of second-order models of tumor-immune system competition ⋮ MATHEMATICAL METHODS AND TOOLS OF KINETIC THEORY TOWARDS MODELLING COMPLEX BIOLOGICAL SYSTEMS ⋮ On the discrete kinetic theory for active particles. Mathematical tools ⋮ Modelling complex systems in applied sciences; methods and tools of the mathematical kinetic theory for active particles ⋮ Hopf bifurcation in a solid avascular tumour growth model with two discrete delays ⋮ Oscillations and bistability in the dynamics of cytotoxic reactions mediated by the response of immune cells to solid tumours ⋮ MATHEMATICAL TOPICS ON THE MODELLING COMPLEX MULTICELLULAR SYSTEMS AND TUMOR IMMUNE CELLS COMPETITION ⋮ Thermodynamical analysis of the dynamics of tumor interaction with the host immune system ⋮ A kinetic model of \(T\) cell autoreactivity in autoimmune diseases ⋮ The competitive dynamics between tumor cells, a replication-competent virus and an immune response ⋮ General population systems. macroscopic limit of a class of stochastic semigroups ⋮ Nonlinear modeling with mammographic evidence of carcinoma ⋮ On the modelling of space dynamics in the kinetic theory for active particles ⋮ Nonlinear mathematical model of pulsed-therapy of heterogeneous tumors ⋮ Discretization of nonlinear models by sinc collocation-interpolation methods ⋮ Mathematical tools of the kinetic theory of active particles with some reasoning on the modelling progression and heterogeneity ⋮ LOOKING FOR NEW PARADIGMS TOWARDS A BIOLOGICAL-MATHEMATICAL THEORY OF COMPLEX MULTICELLULAR SYSTEMS ⋮ Modelling and mathematical problems related to tumor evolution and its interaction with the immune system ⋮ Kinetic modelling of autoimmune diseases ⋮ A Fast Parallel Algorithm for Delay Partial Differential Equations Modeling the Cell Cycle in Cell Lines Derived from Human Tumors ⋮ Analysis of a kinetic cellular model for tumor-immune system interaction ⋮ What is life? A perspective of the mathematical kinetic theory of active particles ⋮ A PARABOLIC–HYPERBOLIC FREE BOUNDARY PROBLEM MODELLING TUMOR TREATMENT WITH VIRUS ⋮ A mathematical model of cellular immune response to leukemia ⋮ A mathematical model for single cell cancer\,--\, immune system dynamics ⋮ Critical analysis and perspectives on kinetic (cellular) theory of immune competition ⋮ Solid tumour growth analysis of necrotic core formation

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