Mathematical Model for an Effective Management of HIV Infection

Ogunlaran, Oladotun Matthew; Noutchie, Suares Clovis Oukouomi

doi:10.1155/2016/4217548

Cited by 35 publications

(21 citation statements)

References 15 publications

(10 reference statements)

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“…The dynamical behavior of the population model with time delay has now become a hot topic of research [ 2 ]. Ogunlaran et al [ 3 ] presented an effective strategy to fight against HIV infection in humans by using the compartment models. Duffin et al [ 4 ] studied the dynamics of the immune deficiency virus of the complete course of infection.…”

Section: Literature Surveymentioning

confidence: 99%

Modeling the effect of delay strategy on transmission dynamics of HIV/AIDS disease

et al. 2020

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In this manuscript, we investigate a nonlinear delayed model to study the dynamics of human-immunodeficiency-virus in the population. For analysis, we find the equilibria of a susceptible–infectious–immune system with a delay term. The well-established tools such as the Routh–Hurwitz criterion, Volterra–Lyapunov function, and Lasalle invariance principle are presented to investigate the stability of the model. The reproduction number and sensitivity of parameters are investigated. If the delay tactics are decreased, then the disease is endemic. On the other hand, if the delay tactics are increased then the disease is controlled in the population. The effect of the delay tactics with subpopulations is investigated. More precisely, all parameters are dependent on delay terms. In the end, to give the strength to a theoretical analysis of the model, a computer simulation is presented.

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Section: Literature Surveymentioning

confidence: 99%

Modeling the effect of delay strategy on transmission dynamics of HIV/AIDS disease

et al. 2020

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“…HIV causes a reduction in the number of functional CD4 + T cells thereby making the body unable to fight and prevent cell infections. A lot of mathematical models have been formulated to study the interactions between CD4 + T cells and HIV [3][4][5][6].…”

Section: Introductionmentioning

confidence: 99%

Mathematical Transmission of HIV/AID with Early Treatment

Akinwumi

Olopade

Adesanya

et al. 2021

JAMCS

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In this paper, a mathematical model for the transmission of HIV/AIDS with early treatment is developed and analyzed to gain insight into early treatment of HIV/AIDS and other epidemiological features that cause the progression from HIV to full blown AIDS. We established the basic reproduction number which is the average number of new secondary infection generated by a single infected individual during infectious period. The analysis shows that the disease free equilibrium is locally and globally asymptotically stable whenever the threshold quantity is less than unity i.e. Numerical analysis shows that the early treatment of latently infected individuals reduces the dynamical progression to full blown AIDS. The result also showed that immunity boosted substances increase the red blood cells, sensitivity analysis of basic reproduction number with respect to parameters showed that effective contact rate must not exceed 0.3 to avoid endemic stage.

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“…Mathematical modelling provides a powerful tool to describe and analyse many engineering and physical problems. It has also been used to describe some biological processes such as heart beats [15], diffusion of drugs [15], hepatitis C virus [16], management of HIV infection [17], treatment of diabetes [18], clearing the antibiotic resistant infection [19], aortic aneurysm formation [20], and tumor growth and cancer treatment. Studies in the field of cancer biology focus on developing suitable mathematical models involving quantitative approaches to understand various aspects of tumor growth and the response of cancer cells to clinical interventions.…”

Section: Introductionmentioning

confidence: 99%

Mathematical Modelling for the Role of CD4⁺T Cells in Tumor-Immune Interactions

Makhlouf

El-Shennawy

Elkaranshawy

2020

Computational and Mathematical Methods in Medicine

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Mathematical modelling has been used to study tumor-immune cell interaction. Some models were proposed to examine the effect of circulating lymphocytes, natural killer cells, and CD8+T cells, but they neglected the role of CD4+T cells. Other models were constructed to study the role of CD4+T cells but did not consider the role of other immune cells. In this study, we propose a mathematical model, in the form of a system of nonlinear ordinary differential equations, that predicts the interaction between tumor cells and natural killer cells, CD4+T cells, CD8+T cells, and circulating lymphocytes with or without immunotherapy and/or chemotherapy. This system is stiff, and the Runge–Kutta method failed to solve it. Consequently, the “Adams predictor-corrector” method is used. The results reveal that the patient’s immune system can overcome small tumors; however, if the tumor is large, adoptive therapy with CD4+T cells can be an alternative to both CD8+T cell therapy and cytokines in some cases. Moreover, CD4+T cell therapy could replace chemotherapy depending upon tumor size. Even if a combination of chemotherapy and immunotherapy is necessary, using CD4+T cell therapy can better reduce the dose of the associated chemotherapy compared to using combined CD8+T cells and cytokine therapy. Stability analysis is performed for the studied patients. It has been found that all equilibrium points are unstable, and a condition for preventing tumor recurrence after treatment has been deduced. Finally, a bifurcation analysis is performed to study the effect of varying system parameters on the stability, and bifurcation points are specified. New equilibrium points are created or demolished at some bifurcation points, and stability is changed at some others. Hence, for systems turning to be stable, tumors can be eradicated without the possibility of recurrence. The proposed mathematical model provides a valuable tool for designing patients’ treatment intervention strategies.

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Mathematical Model for an Effective Management of HIV Infection

Cited by 35 publications

References 15 publications

Modeling the effect of delay strategy on transmission dynamics of HIV/AIDS disease

Modeling the effect of delay strategy on transmission dynamics of HIV/AIDS disease

Mathematical Transmission of HIV/AID with Early Treatment

Mathematical Modelling for the Role of CD4⁺T Cells in Tumor-Immune Interactions

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Mathematical Model for an Effective Management of HIV Infection

Cited by 35 publications

References 15 publications

Modeling the effect of delay strategy on transmission dynamics of HIV/AIDS disease

Modeling the effect of delay strategy on transmission dynamics of HIV/AIDS disease

Mathematical Transmission of HIV/AID with Early Treatment

Mathematical Modelling for the Role of CD4+T Cells in Tumor-Immune Interactions

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Mathematical Modelling for the Role of CD4⁺T Cells in Tumor-Immune Interactions