Litcius/Paper detail

Mathematical modeling of cholera dynamics with intrinsic growth considering constant interventions

Kewani Welay Brhane, Abdulaziz Garba Ahmad, Hina Hina, Homan Emadifar

2024Scientific Reports12 citationsDOIOpen Access PDF

Abstract

A mathematical model that describes the dynamics of bacterium vibrio cholera within a fixed population considering intrinsic bacteria growth, therapeutic treatment, sanitation and vaccination rates is developed. The developed mathematical model is validated against real cholera data. A sensitivity analysis of some of the model parameters is also conducted. The intervention rates are found to be very important parameters in reducing the values of the basic reproduction number. The existence and stability of equilibrium solutions to the mathematical model are also carried out using analytical methods. The effect of some model parameters on the stability of equilibrium solutions, number of infected individuals, number of susceptible individuals and bacteria density is rigorously analyzed. One very important finding of this research work is that keeping the vaccination rate fixed and varying the treatment and sanitation rates provide a rapid decline of infection. The fourth order Runge-Kutta numerical scheme is implemented in MATLAB to generate the numerical solutions.

Topics & Concepts

Basic reproduction numberSanitationConstant (computer programming)Stability (learning theory)MATLABApplied mathematicsPopulationStability theoryComputer scienceMathematicsMathematical optimizationMedicinePhysicsEnvironmental healthEnvironmental scienceEnvironmental engineeringOperating systemQuantum mechanicsMachine learningProgramming languageNonlinear systemMathematical and Theoretical Epidemiology and Ecology ModelsCOVID-19 epidemiological studiesVibrio bacteria research studies