Impact of Awareness to Control Malaria Disease: A Mathematical Modeling Approach

Impact of Awareness to Control Malaria Disease: A Mathematical Modeling Approach

The mathematical modeling of malaria disease has a crucial role in understanding the insights of the transmission dynamics and corresponding appropriate prevention strategies. In this study, a novel nonlinear mathematical model for malaria disease has been proposed. To prevent the disease, we divide...

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Bibliographic Details
Published in:Complexity (New York, N.Y.) Vol. 2020; no. 2020; pp. 1 - 13
Main Authors: Kim, Sangil, Naeem Mannan, Malik Muhammad, Kamran, Muhammad Ahmad, Ibrahim, Malik Muhammad, Jung, Il Hyo
Format: Journal Article
Language:English
Published: Cairo, Egypt Hindawi Publishing Corporation 2020
Hindawi
Hindawi Limited
Hindawi-Wiley
Subjects:
Disease control
Disease transmission
Infections
Infectious diseases
Iterative methods
Malaria
Mathematical models
Mosquitoes
Parasites
Population
Runge-Kutta method
Stability analysis
Tropical diseases
Vectors (Biology)
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Summary:The mathematical modeling of malaria disease has a crucial role in understanding the insights of the transmission dynamics and corresponding appropriate prevention strategies. In this study, a novel nonlinear mathematical model for malaria disease has been proposed. To prevent the disease, we divided the infected population into two groups, unaware and aware infected individuals. The growth rate of awareness programs impacting the population is assumed to be proportional to the unaware infected individuals. It is further assumed that, due to the effect of awareness campaign, the aware infected individuals avoid contact with mosquitoes. The positivity and the boundedness of solutions have been derived through the completing differential process. Local and global stability analysis of disease-free equilibrium has been investigated via basic reproductive number R0, if R0 < 1, the system is stable otherwise unstable. The existence of the unique endemic equilibrium has been also determined under certain conditions. The solution to the proposed model is derived through an iterative numerical technique, the Runge–Kutta method. The proposed model is simulated for different numeric values of the population of humans and anopheles in each class. The results show that a significant increase in the population of susceptible humans is achieved in addition to the decrease in the population of the infected mosquitoes.
ISSN:1076-2787
1099-0526
DOI:10.1155/2020/8657410