Abstract
Biological models inherently contain delay. Mathematical analysis of a delay-induced model is, however, more difficult compare to its non-delayed counterpart. Difficulties multiply if the model contains multiple delays. In this paper, we analyze a realistic HIV-1 infection model in the presence and absence of multiple delays. We consider self-proliferation of CD4+T cells, nonlinear saturated infection rate and recovery of infected cells due to incomplete reverse transcription in a basic HIV-1 in-host model and incorporate multiple delays to account for successful viral entry and subsequent virus reproduction from the infected cell. Both of delayed and non-delayed system becomes disease-free if the basic reproduction number is less than unity. In the absence of delays, the infected equilibrium is shown to be locally asymptotically stable under some parametric space and unstable otherwise. The system may show unstable oscillatory behaviour in the presence of either delay even when the non-delayed system is stable. The second delay further enhances the instability of the endemic equilibrium which is otherwise stable in the presence of a single delay. Numerical results are shown to be in agreement with the analytical results and reflect quite realistic dynamics observed in HIV-1 infected individuals.
Highlights
THE MODELHuman Immune Deficiency Virus-type 1 (HIV1 or HIV) is a retrovirus which preferably infects CD4+T lymphocytes and supposed to be the causative agent of AIDS (Acquired Immune Deficiency Syndrome)
BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
The issue we address here is the role of self proliferation of CD4+T cells in an in-host HIV-1 ODE model with more general infection rate and recovery of infected cells
Summary
Human Immune Deficiency Virus-type 1 (HIV1 or HIV) is a retrovirus which preferably infects CD4+T lymphocytes and supposed to be the causative agent of AIDS (Acquired Immune Deficiency Syndrome). Assuming that a proportion of infected CD4+T cells can be reverted to the uninfected class and v(t) be the concentration of free virus particle in the blood plasma at time t, following mathematical models have been proposed and analyzed [11], [12], [13], [14], [15]:. Pawelek et al [37] considered the same model and showed the global stability of the interior equilibrium point under some restrictions They ignored the proliferation character of CD4+T cells in the presence of antigenic infection, saturation effect of the incidence and recovery of some infected CD4+T cells due to incomplete reverse transcription. We will show that x(t) > 0 for t ∈ (0, T )
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