Stochastic models for virus and immune system dynamics

Mathematical Biosciences

Volumn 234, Issue 2, 2011, Pages 84-94

  Yuan, Yuan ^a   Allen, Linda J S ^a  

^a TEXAS TECH UNIVERSITY   (United States)

Author keywords

Branching process; HIV 1 dynamics; Immune response; Stochastic differential equations

Indexed keywords

ASYMPTOTICALLY STABLE; BASIC MODELS; BASIC REPRODUCTION NUMBER; BRANCHING PROCESS; CONTINUOUS TIME MARKOV CHAIN; DETERMINISTIC MODELS; DISEASE-FREE EQUILIBRIUM; GLOBALLY ASYMPTOTICALLY STABLE; HUMAN IMMUNODEFICIENCY VIRUS-1; IMMUNE RESPONSE; IMMUNE SYSTEM DYNAMICS; IMMUNE SYSTEMS; INFECTED CELLS; INFECTION PROCESS; PARAMETER VALUES; POSITIVE PROBABILITY; STOCHASTIC DIFFERENTIAL EQUATIONS; SYSTEM OF ORDINARY DIFFERENTIAL EQUATIONS; VIRAL INFECTIONS;

CONTINUOUS TIME SYSTEMS; DISEASES; IMMUNOLOGY; MARKOV PROCESSES; ORDINARY DIFFERENTIAL EQUATIONS; PROBABILITY; STOCHASTIC SYSTEMS; VIRUSES;

STOCHASTIC MODELS;

HUMAN IMMUNODEFICIENCY VIRUS; IMMUNE RESPONSE; IMMUNE SYSTEM; INFECTIOUS DISEASE; MARKOV CHAIN; NUMERICAL MODEL; PROBABILITY; STOCHASTICITY; VIRUS;

APOPTOSIS; ARTICLE; CELL PROLIFERATION; HUMAN IMMUNODEFICIENCY VIRUS 1 INFECTION; IMMUNE RESPONSE; IMMUNE SYSTEM; MATHEMATICAL COMPUTING; PROBABILITY; STOCHASTIC MODEL; VIRUS CELL INTERACTION; VIRUS ENTRY; VIRUS LOAD; VIRUS PARTICLE; VIRUS RELEASE; VIRUS REPLICATION;

BASIC REPRODUCTION NUMBER; COMPUTER SIMULATION; HIV INFECTIONS; HIV-1; HUMANS; MARKOV CHAINS; MODELS, IMMUNOLOGICAL; STOCHASTIC PROCESSES; VIRUS REPLICATION;

HUMAN IMMUNODEFICIENCY VIRUS 1;

EID: 82255162715     PISSN: 00255564     EISSN: 18793134     Source Type: Journal    
DOI: 10.1016/j.mbs.2011.08.007     Document Type: Article

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