Dynamics of HIV infection of CD4 + T cells

We examine a model for the interaction of HIV with CD4 + T cells that considers four populations: uninfected T cells, latently infected T cells, actively infected T cells, and free virus. Using this model we show that many of the puzzling quantitative features of HIV infection can be explained simpl...

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Bibliographic Details
Published in:Mathematical biosciences 1993-03, Vol.114 (1), p.81-125
Main Authors: Perelson, Alan S., Kirschner, Denise E., De Boer, Rob
Format: Article
Language:English
Subjects:
550900 > Pathology
551000 > Physiological Systems
AIDS VIRUS
AIDS/HIV
ANIMAL CELLS
BASIC BIOLOGICAL SCIENCES
Biological and medical sciences
BIOLOGICAL MATERIALS
BLOOD
BLOOD CELLS
BODY FLUIDS
CD4-Positive T-Lymphocytes - immunology
CD4-Positive T-Lymphocytes - microbiology
Computerized, statistical medical data processing and models in biomedicine
CONNECTIVE TISSUE CELLS
DIFFERENTIAL EQUATIONS
EQUATIONS
EQUILIBRIUM
GROWTH
HIV - physiology
HIV Infections - immunology
HIV Infections - microbiology
Humans
INTERACTIONS
LEUKOCYTES
LYMPHOCYTES
MATERIALS
MATHEMATICAL MODELS
Mathematics
Medical sciences
MICROORGANISMS
Models and simulation
Models, Biological
PARASITES
POPULATION DYNAMICS
SOMATIC CELLS
Virus Replication
VIRUSES 550700 > Microbiology
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Summary:We examine a model for the interaction of HIV with CD4 + T cells that considers four populations: uninfected T cells, latently infected T cells, actively infected T cells, and free virus. Using this model we show that many of the puzzling quantitative features of HIV infection can be explained simply. We also consider effects of AZT on viral growth and T-cell population dynamics. The model exhibits two steady states, an uninfected state in which no virus is present and an endemically infected state, in which virus and infected T cells are present. We show that if N, the number of infectious virions produced per actively infected T cell, is less a critical value, N crit, then the uninfected state is the only steady state in the nonnegative orthant, and this state is stable. For N > N crit, the uninfected state is unstable, and the endemically infected state can be either stable, or unstable and surrounded by a stable limit cycle. Using numerical bifurcation techniques we map out the parameter regimes of these various behaviors. Oscillatory behavior seems to lie outside the region of biologically realistic parameter values. When the endemically infected state is stable, it is characterized by a reduced number of T cells compared with the uninfected state. Thus T-cell depletion occurs through the establishment of a new steady state. The dynamics of the establishment of this new steady state are examined both numerically and via the quasi-steady-state approximation. We develop approximations for the dynamics at early times in which the free virus rapidly binds to T cells, during an intermediate time scale in which the virus grows exponentially, and a third time scale on which viral growth slows and the endemically infected steady state is approached. Using the quasi-steady-state approximation the model can be simplified to two ordinary differential equations the summarize much of the dynamical behavior. We compute the level of T cells in the endemically infected state and show how that level varies with the parameters in the model. The model predicts that different viral strains, characterized by generating differing numbers of infective virions within infected T cells, can cause different amounts of T-cell depletion and generate depletion at different rates. Two versions of the model are studied. In one the source of T cells from precursors is constant, whereas in the other the source of T cells decreases with viral load, mimicking the infection and killing o
ISSN:0025-5564
1879-3134
DOI:10.1016/0025-5564(93)90043-A