A mathematical modeling of optimal vaccination strategies in epidemiology

A mathematical modeling of optimal vaccination strategies in epidemiology

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Magister Scientiae - MSc === We review a number of compartmental models in epidemiology which leads to a nonlinear system of ordinary differential equations. We focus an SIR, SEIR and SIS epidemic models with and without vaccination. A threshold parameter R0 is identified which governs the spread of...

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Main Author: Nemaranzhe, Lutendo
Other Authors: Witbooi, Peter J.
Language:en
Published: University of the Western Cape 2014
Subjects:
Basic reproductive number
Disease-free equilibrium
Epidemiology
Endemic model
Numerical simulation
Population model
Optimization
Vaccination
Online Access:http://hdl.handle.net/11394/3065
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spelling ndltd-netd.ac.za-oai-union.ndltd.org-uwc-oai-etd.uwc.ac.za-11394-30652018-09-06T04:53:32Z A mathematical modeling of optimal vaccination strategies in epidemiology Nemaranzhe, Lutendo Witbooi, Peter J. Dept. of Mathematics Basic reproductive number Disease-free equilibrium Epidemiology Endemic model Numerical simulation Population model Optimization Vaccination Magister Scientiae - MSc We review a number of compartmental models in epidemiology which leads to a nonlinear system of ordinary differential equations. We focus an SIR, SEIR and SIS epidemic models with and without vaccination. A threshold parameter R0 is identified which governs the spread of diseases, and this parameter is known as the basic reproductive number. The models have at least two equilibria, an endemic equilibrium and the disease-free equilibrium. We demonstrate that the disease will die out, if the basic reproductive number R0 < 1. This is the case of a disease-free state, with no infection in the population. Otherwise the disease may become endemic if the basic reproductive number R0 is bigger than unity. Furthermore, stability analysis for both endemic and disease-free steady states are investigated and we also give some numerical simulations. The second part of this dissertation deals with optimal vaccination strategy in epidemiology. We use optimal control technique on vaccination to minimize the impact of the disease. Hereby we mean minimizing the spread of the disease in the population, while also minimizing the effort on vaccination roll-out. We do this optimization for the cases of SIR and SEIR models, and show how optimal strategies can be obtained which minimize the damage caused by the infectious disease. Finally, we describe the numerical simulations using the fourth-order Runge-Kutta method. These are the most useful references: [G. Zaman, Y.H Kang, II. H. Jung. BioSystems 93, (2008), 240 − 249], [K. Hattaf, N. Yousfi. The Journal of Advanced Studies in Biology, Vol. 1(8), (2008), 383 − 390.], [Lenhart, J.T. Workman. Optimal Control and Applied to Biological Models. Chapman and Hall/CRC, (2007).], [P. Van den Driessche, J. Watmough. Math. Biosci., 7, (2005)], and [J. Wu, G. R¨ost. Mathematical Biosciences and Engineering, Vol 5(2), (2008), 389 − 391]. South Africa 2014-03-28T10:29:04Z 2013/03/20 2013/03/20 12:16 2014-03-28T10:29:04Z 2010 http://hdl.handle.net/11394/3065 en Copyright: University of the Western Cape University of the Western Cape
collection NDLTD
language en
sources NDLTD
topic Basic reproductive number
Disease-free equilibrium
Epidemiology
Endemic model
Numerical simulation
Population model
Optimization
Vaccination
spellingShingle Basic reproductive number
Disease-free equilibrium
Epidemiology
Endemic model
Numerical simulation
Population model
Optimization
Vaccination
Nemaranzhe, Lutendo
A mathematical modeling of optimal vaccination strategies in epidemiology
description Magister Scientiae - MSc === We review a number of compartmental models in epidemiology which leads to a nonlinear system of ordinary differential equations. We focus an SIR, SEIR and SIS epidemic models with and without vaccination. A threshold parameter R0 is identified which governs the spread of diseases, and this parameter is known as the basic reproductive number. The models have at least two equilibria, an endemic equilibrium and the disease-free equilibrium. We demonstrate that the disease will die out, if the basic reproductive number R0 < 1. This is the case of a disease-free state, with no infection in the population. Otherwise the disease may become endemic if the basic reproductive number R0 is bigger than unity. Furthermore, stability analysis for both endemic and disease-free steady states are investigated and we also give some numerical simulations. The second part of this dissertation deals with optimal vaccination strategy in epidemiology. We use optimal control technique on vaccination to minimize the impact of the disease. Hereby we mean minimizing the spread of the disease in the population, while also minimizing the effort on vaccination roll-out. We do this optimization for the cases of SIR and SEIR models, and show how optimal strategies can be obtained which minimize the damage caused by the infectious disease. Finally, we describe the numerical simulations using the fourth-order Runge-Kutta method. These are the most useful references: [G. Zaman, Y.H Kang, II. H. Jung. BioSystems 93, (2008), 240 − 249], [K. Hattaf, N. Yousfi. The Journal of Advanced Studies in Biology, Vol. 1(8), (2008), 383 − 390.], [Lenhart, J.T. Workman. Optimal Control and Applied to Biological Models. Chapman and Hall/CRC, (2007).], [P. Van den Driessche, J. Watmough. Math. Biosci., 7, (2005)], and [J. Wu, G. R¨ost. Mathematical Biosciences and Engineering, Vol 5(2), (2008), 389 − 391]. === South Africa
author2 Witbooi, Peter J.
author_facet Witbooi, Peter J.
Nemaranzhe, Lutendo
author Nemaranzhe, Lutendo
author_sort Nemaranzhe, Lutendo
title A mathematical modeling of optimal vaccination strategies in epidemiology
title_short A mathematical modeling of optimal vaccination strategies in epidemiology
title_full A mathematical modeling of optimal vaccination strategies in epidemiology
title_fullStr A mathematical modeling of optimal vaccination strategies in epidemiology
title_full_unstemmed A mathematical modeling of optimal vaccination strategies in epidemiology
title_sort mathematical modeling of optimal vaccination strategies in epidemiology
publisher University of the Western Cape
publishDate 2014
url http://hdl.handle.net/11394/3065
work_keys_str_mv AT nemaranzhelutendo amathematicalmodelingofoptimalvaccinationstrategiesinepidemiology
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