Mathematical analysis on the vertical and horizontal transmission dynamics of HIV and Zika virus co-infection

Benjamin Idoko Omede; Bolarinwa Bolaji; Olumuyiwa James Peter; Abdullahi A. Ibrahim; Festus Abiodun Oguntolu

Franklin Open (Mar 2024)

Mathematical analysis on the vertical and horizontal transmission dynamics of HIV and Zika virus co-infection

Benjamin Idoko Omede,
Bolarinwa Bolaji,
Olumuyiwa James Peter,
Abdullahi A. Ibrahim,
Festus Abiodun Oguntolu

Affiliations

Benjamin Idoko Omede: Department of Mathematical Sciences, Prince Abubakar Audu (Formerly Kogi State) University, Anyigba, Nigeria; Laboratory of Mathematical Epidemiology and Applied Sciences (LOMEAS), Prince Abubakar Audu (Formerly Kogi State) University, Anyigba, Nigeria
Bolarinwa Bolaji: Department of Mathematical Sciences, Prince Abubakar Audu (Formerly Kogi State) University, Anyigba, Nigeria; Laboratory of Mathematical Epidemiology and Applied Sciences (LOMEAS), Prince Abubakar Audu (Formerly Kogi State) University, Anyigba, Nigeria
Olumuyiwa James Peter: Department of Mathematical and Computer Sciences, University of Medical Sciences, Ondo State, Nigeria; Department of Epidemiology and Biostatistics, School of Public Health, University of Medical Sciences, Ondo State, Nigeria; Corresponding author at: Department of Mathematical and Computer Sciences, University of Medical Sciences, Ondo State, Nigeria.
Abdullahi A. Ibrahim: Department of Mathematics, Baze University Abuja, Nigeria
Festus Abiodun Oguntolu: Department of Mathematics, Federal University of Techology, Minna, Niger State, Nigeria

Journal volume & issue: Vol. 6
p. 100064

Abstract

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The co-infection of HIV and Zika virus (ZIKV) poses a complex and understudied health challenge, requiring a comprehensive investigation into the synergistic effects, potential complications, and the impact on affected individuals. Consequently, This paper introduces a novel deterministic mathematical model that examines the transmission dynamics of HIV and Zika virus co-infection, considering both vertical and horizontal transmission. The analysis begins with two sub-models: one for HIV-only and another for ZIKV-only. Qualitative examination indicates that the HIV only sub-model achieves a globally asymptotically stable disease-free equilibrium when the associated reproduction number is below unity. In contrast, the ZIKV only sub-model exhibits a backward bifurcation phenomenon, where both stable disease-free and stable endemic equilibria co-exist when the associated reproduction number of the ZIKV only sub-model is less than unity. Thus, the backward bifurcation property makes effective control of ZIKV infection in the population difficulty when the associated reproduction number is less than unity. It is shown, using the center manifold theory that the full HIV-ZIKV co-infection model undergoes the phenomenon of backward bifurcation. We carried out the sensitivity analysis of the HIV and ZIKV basic reproduction numbers to determine the parameters that positively influence the spread of the two diseases. It is also revealed that an increase in HIV infection in the population will positively influence the transmission of ZIKV. We validated the ZIKV only sub-model by fitting the ZIKV only sub-model to the confirmed cases of ZIKV data in Brazil. The outcome of the numerical simulations of HIV-ZIKV co-infection model reveals that the two diseases co-exist when their basic reproduction number surpasses one. Furthermore, increasing HIV treatment rate significantly reduces the burden of co-infection with the Zika virus.

Published in Franklin Open

ISSN: 2773-1871 (Print); 2773-1863 (Online)
Publisher: Elsevier
Country of publisher: United States
LCC subjects: Technology
Website: https://www.sciencedirect.com/journal/franklin-open

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