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Examining the effect of climate variability on malaria transmission using a dynamic mosquito-human malaria model
Joint Event on 3rd International Conference on Infection, Disease Control and Prevention & 2nd International Conference on Microbial Pathogenesis & Infectious Diseases
Gbenga J Abiodun
Foundation for Professional Development, South Africa
The reasons for malaria resurgence mostly in Africa are yet to be well understood. Although the causes are often linked to
regional climate change, it is important to understand the impact of climate variability on the dynamics of the disease.
However, this is difficult due to the unavailability of long-term malaria data over the study areas. In this study, we develop a
climatebased mosquito-human malaria model to study malaria dynamics in the human population over KwaZulu-Natal, one
of the epidemic provinces in South Africa, from 1970-2005. We compare the model output with available observed monthly
malaria cases over the province from September 1999 to December 2003. We further use the model outputs to explore the
relationship between the climate variables (rainfall and temperature) and malaria incidence over the province using principal
component analysis, wavelet power spectrum and wavelet coherence analysis. The model produces a reasonable fit with the
observed data and in particular, it captures all the spikes in malaria prevalence. Our results highlight the importance of climate
factors on malaria transmission and show the seasonality of malaria epidemics over the province. Results from the principal
component analyses further suggest that, there are two principal factors associated with climates variables and the model
outputs. One of the factors indicate high loadings on Susceptible, Exposed and Infected human, while the other is more
correlated with Susceptible and Recovered humans. However, both factors reveal the inverse correlation between Susceptible-
Infected and Susceptible-Recovered humans respectively. Through the spectrum analysis, we notice a strong annual cycle of
malaria incidence over the province and ascertain a dominant of one year periodicity. Consequently, our findings indicate
that an average of 0 to 120-day lag is generally noted over the study period, but the 120-day lag is more associated with
temperature than rainfall. This is consistence with other results obtained from our analyses that malaria transmission is more
tightly coupled with temperature than with rainfall in KwaZulu-Natal province.
Biography
Gbenga J. Abiodun, PhD is a young scientist whose research interest focuses on biomathematics, epidemiology and mathematical modelling of the impacts of climate (variability and change) on vector-borne and infectious diseases. He completed his Masters and Doctoral degrees in Mathematics at the University of the Western Cape (UWC) in 2012 and 2016, respectively. Dr. Abiodun has worked extensively on infectious diseases and published peer-reviewed papers in highprofile international journals.