Mathematical modeling of TB disease dynamics in a crowded population.

Maku Vyambwera, Sibaliwe

January 2020

Philosophiae Doctor - PhD / Tuberculosis is a bacterial infection which is a major cause of death worldwide. TB is a curable disease, however the bacterium can become resistant to the first line treatment against the disease. This leads to a disease called drug resistant TB that is difficult and expensive to treat. It is well-known that TB disease thrives in communities in overcrowded environments with poor ventilation, weak nutrition, inadequate or inaccessible medical care, etc, such as in some prisons or some refugee camps. In particular, the World Health Organization discovered that a number of prisoners come from socio-economic disadvantaged population where the burden of TB disease may be already high and access to medical care may be limited. In this dissertation we propose compartmental models of systems of differential equations to describe the population dynamics of TB disease under conditions of crowding. Such models can be used to make quantitative projections of TB prevalence and to measure the effect of interventions. Indeed we apply these models to specific regions and for specific purposes. The models are more widely applicable, however in this dissertation we calibrate and apply the models to prison populations.

Cross effect

Awaiting trial

Remand

Sentenced convict

Two-group TB model

Almost sure exponential stability

Stochastic TB model

Removal rate

Inflow of infecteds

Prison TB model

Crowded environment

Multi-drug resistant TB

Basic reproduction number

Optimal control

Lyapunov function

Endemic equilibrium

Disease-free equilibrium