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Towards a Mathematical Theory of Complex Biological Systems cover

This monograph has the ambitious aim of developing a mathematical theory of complex biological systems with special attention to the phenomena of ageing, degeneration and repair of biological tissues under individual self-repair actions that may have good potential in medical therapy.

The approach to mathematically modeling biological systems needs to tackle the additional difficulties generated by the peculiarities of living matter. These include the lack of invariance principles, abilities to express strategies for individual fitness, heterogeneous behaviors, competition up to proliferative and/or destructive actions, mutations, learning ability, evolution and many others.

Applied mathematicians in the field of living systems, especially biological systems, will appreciate the special class of integro-differential equations offered here for modeling at the molecular, cellular and tissue scales. A unique perspective is also presented with a number of case studies in biological modeling.

Sample Chapter(s)
Chapter 1: Looking for a Mathematical Theory of Biological Systems (124 KB)


Contents:
    • Looking for a Mathematical Theory of Biological Systems
    • On the Complexity of Biological Systems
  • Immune System, Wound Healing Process, and System Biology:
    • The Immune System: A Phenomenological Overview
    • Wound Healing Process and Organ Repair
    • From Levels of Biological Organization to System Biology
  • Mathematical Tools:
    • Mathematical Tools and Structures
    • Multiscale Modeling: Linking Molecular, Cellular, and Tissues Scales
  • Applications and Research Perspectives:
    • A Model for the Malign Keloid Formation and Immune System Competition
    • Macroscopic Models of Chemotaxis by KTAP Asymptotic Methods
    • Looking Ahead

Readership: Researchers in mathematical modeling and biological systems.