Skip to main page content
U.S. flag

An official website of the United States government

Dot gov

The .gov means it’s official.
Federal government websites often end in .gov or .mil. Before sharing sensitive information, make sure you’re on a federal government site.

Https

The site is secure.
The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.

Access keys NCBI Homepage MyNCBI Homepage Main Content Main Navigation
. 2008 Oct;2(4):357-85.
doi: 10.1080/17513750701813184.

Modelling HIV immune response and validation with clinical data

H T Banks  1 M DavidianShuhua HuGrace M KeplerE S Rosenberg
Affiliations

Modelling HIV immune response and validation with clinical data

H T Banks et al. J Biol Dyn. 2008 Oct.

Abstract

A system of ordinary differential equations is formulated to describe the pathogenesis of HIV infection, wherein certain features that have been shown to be important by recent experimental research are incorporated in the model. These include the role of CD4+ memory cells that serve as a major reservoir of latently infected cells, a critical role for T-helper cells in the generation of CD8 memory cells capable of efficient recall response, and stimulation by antigens other than HIV. A stability analysis illustrates the capability of this model in admitting multiple locally asymptotically stable (locally a.s.) off-treatment equilibria.We show that this more biologically detailed model can exhibit the phenomenon of transient viremia experienced by some patients on therapy with viral load levels suppressed below the detection limit. We also show that the loss of CD4+ T-cell help in the generation of CD8+ memory cells leads to larger peak values for the viral load during transient viremia. Censored clinical data is used to obtain parameter estimates. We demonstrate that using a reduced set of 16 free parameters, obtained by fixing some parameters at their population averages, the model provides reasonable fits to the patient data and, moreover, that it exhibits good predictive capability. We further show that parameter values obtained for most clinical patients do not admit multiple locally a.s off-treatment equilibria. This suggests that treatment to move from a high viral load equilibrium state to an equilibrium state with a lower (or zero) viral load is not possible for these patients.

Keywords: HIV; censored data; immune response; inverse problems; model prediction; multiple equilibria.

PubMed Disclaimer

Figures

Figure 1
Figure 1
Flow chart of model (2.1) with compartments as described in Table 1. Solid black arrows indicate death/clearance, solid gray arrows indicate birth/input. PI and RTI denote protease inhibitor and reverse transcriptase inhibitor, respectively.
Figure 2
Figure 2
Phase diagram showing equilibrium attained as a function of the initial viral load ν and the parameter aT. It should be emphasized that this plot is only applicable for the particular initial condition (0, 0, 1400, 0, ν, 0, 0.01, 0).
Figure 3
Figure 3
Phase diagram showing equilibrium attained as a function of the initial viral load ν and the parameter aA. Initial conditions for simulations, corresponding to the uninfected equilibrium EQ1, are calculated for each value of aA. Note that aT = 8 × 10−3 day−1 for these simulations.
Figure 4
Figure 4
(a) Activation rate aA(t) by a non-HIV antigen. The duration of the infection is 30 days; (b) Viral load VI(t) (solid line), censored data level (horizontal dashed line), and infection start and stop times (vertical dash-dot lines).
Figure 5
Figure 5
Model dynamics with ε1 = 0.7, ε2 = 0, and the values of all the other parameters as specified in Table 2. Activation rate by a non-HIV antigen aA(t) is as depicted in Fig. 4(a). Vertical dashed lines indicate the start and stop times of the non-HIV infection.
Figure 6
Figure 6
(a) Activation rate by non-HIV antigens aA(t). The duration of each infection is 30 days, with the first beginning on day 20 and the second on day 80; (b) Viral load VI(t) (solid line) and censor data level (horizontal dashed line).
Figure 7
Figure 7
(a) Activation rate by non-HIV antigens aA(t). The duration of each infection is 30 days, with the first beginning on day 20 and the second on day 200; (b) Viral load VI(t) (solid line) and censor data level (horizontal dashed line).
Figure 8
Figure 8
Model dynamics with ε1 = 0.7, ε2 = 0, and the values of all the other parameters as specified in Table 2. Activation rate by a non-HIV antigen aA(t) is as depicted in Fig. 7(a). Vertical dashed lines indicate the start and stop times of the non-HIV infections for this example. The vertical dotted line indicates the start time (80 days) of the second infection in Fig. 6.
Figure 9
Figure 9
(a) The effect of Kγ on the “healthy” infected (EQ2) values of the VI (circles), E1 (crosses), and E2 (asterisks) compartments. Equilibrium values correspond to the case ε1 = 0.7, ε2 = 0, aA = 0, and the values of all other parameters as specified in Table 5; (b) Relative change of VI (circles), E1 (crosses), and E2 (asterisks) compartments as a function of Kγ.
Figure 10
Figure 10
Clinical data (‘x’) for CD4 T-cells (upper graph) and viral load (lower graph). Also included are the model results with parameters estimated from full data (dash-dot line) or half longitudinal data (solid line). Dark and gray circles denote the predicted censored data values for the full and half longitudinal data, respectively. The vertical line in the middle of the graph delineates between the two halves of the longitudinal data. A solid line along the x-axis in the upper figure indicates periods when the patient is on HAART treatment, while a dashed line indicates off-treatment periods.
Figure 11
Figure 11
Clinical data (‘x’) for CD4 T-cells (upper graph) and viral load (lower graph). Also included are the model results with parameters estimated from full data (dash-dot line) or half longitudinal data (solid line). Dark and gray circles denote the predicted censored data values for the full and half longitudinal data, respectively. The vertical line in the middle of the graph delineates between the two halves of the longitudinal data. A solid line along the x-axis in the upper figure indicates periods when the patient is on HAART treatment, while a dashed line indicates off-treatment periods.
Figure 12
Figure 12
Clinical data (‘x’) for CD4 T-cells (upper graph) and viral load (lower graph). Also included are the model results with parameters estimated from full data (dash-dot line) or half longitudinal data (solid line). Dark and gray circles denote the predicted censored data values for the full and half longitudinal data, respectively. The vertical line in the middle of the graph delineates between the two halves of the longitudinal data. A solid line along the x-axis in the upper figure indicates periods when the patient is on HAART treatment, while a dashed line indicates off-treatment periods.
Figure 13
Figure 13
Clinical data (‘x’) for CD4 T-cells (upper graph) and viral load (lower graph). Also included are the model results with parameters estimated from full data (dash-dot line) or half longitudinal data (solid line). Dark and gray circles denote the predicted censored data values for the full and half longitudinal data, respectively. The vertical line in the middle of the graph delineates between the two halves of the longitudinal data. A solid line along the x-axis in the upper figure indicates periods when the patient is on HAART treatment, while a dashed line indicates off-treatment periods.
Figure 14
Figure 14
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 15
Figure 15
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 16
Figure 16
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 17
Figure 17
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 18
Figure 18
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 19
Figure 19
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 20
Figure 20
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 21
Figure 21
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 22
Figure 22
CD4 T-cells (upper graph) and viral load (lower graph).
Figure 23
Figure 23
CD4 T-cells (upper graph) and viral load (lower graph).
See this image and copyright information in PMC

References

    1. Adams BM, Banks HT, Davidian M, Kwon H, Tran HT, Wynne SN, Rosenberg ES. HIV dynamics: modeling, data analysis, and optimal treatment protocols. J. Computational and Applied Mathematics. 2005;184:10–49.
    1. Adams BM, Banks HT, Tran HT, Kwon H. Dynamic multidrug therapies for HIV: optimal and STI control approaches. Mathematical Biosciences and Engineering. 2004;1:223–241. - PubMed
    1. Adams BM, Banks HT, Davidian M, Rosenberg ES. Model fitting and prediction with HIV treatment interruption data. Bulletin of Mathematical Biology. 2007;69:563–584. CRSC-TR05−40, NCSU, October, 2005. - PubMed
    1. Altfeld M, Rosenberg ES. The role of CD4 T helper cells in the cytotoxic T lymphocyte response to HIV-1. Current Opinion in Immunology. 2000;12:375–380. - PubMed
    1. Bai P, Banks HT, Dediu S, Govan AY, Last M, Loyd A, Nguyen HK, Olufsen MS, Rempala G, Slenning BD. Stochastic and deterministic models for agricultural production networks. Mathematical Biosciences and Engineering. 2007;4:373–402. CRSC-TR07−06, NCSU, February, 2007. - PubMed

Publication types