Immune Response to a Variable Pathogen: A Stochastic Model with Two Interlocked Darwinian Entities

This paper presents the modeling of a host immune system, more precisely the immune effector cell and immune memory cell population, and its interaction with an invading pathogen population. It will tackle two issues of interest; on the one hand, in defining a stochastic model accounting for the inherent nature of organisms in population dynamics, namely multiplication with mutation and selection; on the other hand, in providing a description of pathogens that may vary their antigens through mutations during infection of the host. Unlike most of the literature, which models the dynamics with first-order differential equations, this paper proposes a Galton-Watson type branching process to describe stochastically by whole distributions the population dynamics of pathogens and immune cells. In the first model case, the pathogen of a given type is either eradicated or shows oscillatory chronic response. In the second model case, the pathogen shows variational behavior changing its antigen resulting in a prolonged immune reaction.

• Publication year

  2012

• Venue

  Comput. Math. Methods Medicine

• Publication date

  2012-12-02

• Fields of study

  Biology, Medicine, Mathematics, Computer Science

• Identifiers
  DOI 10.1155/2012/784512PMID 23424603PMCID 3574756
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• Monte Carlo Simulation

  2013cited by this paper
• An information-carrying and knowledge-producing molecular machine. A Monte-Carlo simulation

  2011cited by this paper
• Systems biology in immunology: a computational modeling perspective.

  2011cited by this paper
• Antibiotic-resistant bugs in the 21st century--a clinical super-challenge.

  2009cited by this paper
• BRANCHING PROCESSES

  2006cited by this paper
• Branching Processes: Variation, Growth and Extinction of Populations

  2006cited by this paper
• A Computer-Glimpse of the Origin of Life

  2005cited by this paper
• Survival Chances of Mutants Starting With One Individual

  2005cited by this paper
• Survival Chances of Mutants Starting With One Individual

  2005cited by this paper
• Adjoint equations and analysis of complex systems: application to virus infection modelling

  2005cited by this paper
• Divide and conquer: the importance of cell division in regulating B‐cell responses

  2004cited by this paper
• Generation and maintenance of immunological memory.

  2004cited by this paper
• Asymptotic analysis of three random branching walk models arising in molecular biology

  2003cited by this paper
• Diversified world: drive to life's origin?!

  2003cited by this paper
• Evolution of immunological memory and the regulation of competition between pathogens.

  2003cited by this paper
• Proliferation and competition in discrete biological systems

  2003cited by this paper
• Antigen dependent and independent mechanisms that sustain serum antibody levels.

  2003cited by this paper
• Modelling viral and immune system dynamics

  2002influential reference
• Dynamics and selection of many-strain pathogens

  2002cited by this paper
• Branching processes in biology

  2002cited by this paper
• Computer-modeling origin of a simple genetic apparatus

  2001cited by this paper
• Modeling complexity in biology

  2001cited by this paper
• Quantification of Cell Turnover Kinetics Using 5-Bromo-2′-deoxyuridine1

  2000cited by this paper
• Applied problems of mathematical modeling in immunology

  2000cited by this paper
• HIV time hierarchy: winning the war while, loosing all the battles

  2000cited by this paper
• The importance of being discrete: life always wins on the surface.

  1999cited by this paper
• Population biology, evolution, and infectious disease: convergence and synthesis.

  1999cited by this paper
• Population structure of pathogens: the role of immune selection.

  1999cited by this paper
• The Galton-Watson branching process as a quantitative tool in parasitology.

  1999cited by this paper
• Modelling the dynamics of LCMV infection in mice: conventional and exhaustive CTL responses.

  1998cited by this paper
• Dynamics of cytotoxic T–lymphocyte exhaustion

  1998cited by this paper
• Chaos, persistence, and evolution of strain structure in antigenically diverse infectious agents.

  1998cited by this paper
• Immunology for physicists

  1997cited by this paper
• Survival probability of drug resistant mutants in malaria parasites

  1997cited by this paper
• Mathematical Modelling of Immune Response in Infectious Diseases

  1997cited by this paper
• Long-term humoral immunity against viruses: revisiting the issue of plasma cell longevity

  1996cited by this paper
• The maintenance of strain structure in populations of recombining infectious agents

  1996cited by this paper
• Population Dynamics of Immune Responses to Persistent Viruses

  1996cited by this paper
• Immunology Taught by Viruses

  1996cited by this paper
• Adventures in Stochastic Processes

  1993influential reference
• A computer model of cellular interactions in the immune system.

  1992cited by this paper
• The dynamics of gene amplification described as a multitype compartmental model and as a branching process.

  1991cited by this paper
• Handbook of Stochastic Methods for Physics, Chemistry and the Natural Sciences.@@@Elements of Applied Stochastic Processes, 2nd Edition.@@@Comparison Methods for Queues and Other Stochastic Models.@@@Parameter Estimation for Stochastic Processes.

  1986cited by this paper
• Handbook of Stochastic Methods for Physics, Chemistry and the Natural Sciences

  1984cited by this paper
• A modification of jerne's theory of antibody production using the concept of clonal selection

  1976cited by this paper
• Selforganization of matter and the evolution of biological macromolecules

  1971cited by this paper
• The Theory of Branching Processes.

  1963influential reference
• THE NATURAL-SELECTION THEORY OF ANTIBODY FORMATION.

  1955cited by this paper
• Immune Responses against Multiple Epitopes: a Theory for Immunodominance and Antigenic Variation Competition between Ctl Epitopes: the Competitive Exclusion Principle

  year unknowncited by this paper

• Establishing a system to identify correlations among immune system components for exploring alternative pathways for immune information transfer.

  2025cites this paper