Assessment of the impact of climate shifts on malaria transmission in the Sahel

Title Assessment of the impact of climate shifts on malaria transmission in the Sahel
Publication Type Journal Article
Year of Publication 2009
Authors Bomblies, A. & Eltahir, E. A. B.
Journal EcoHealth
Volume 6
Issue 3
Pagination 426-37
Date Published 2009 Sep
ISSN 1612-9210
Keywords Animals, Anopheles, Climate Change, Disease Vectors, Ecosystem, Humans, Malaria, Niger, Risk Assessment, Temperature
Abstract affects malaria transmission through a complex network of causative pathways. We seek to evaluate the impact of hypothetical climate change scenarios on malaria transmission in the Sahel by using a novel mechanistic, high spatial- and temporal-resolution coupled hydrology and agent-based entomology model. The hydrology model component resolves individual precipitation events and individual breeding pools. The impact of future potential climate shifts on the representative Sahel village of Banizoumbou, Niger, is estimated by forcing the model of Banizoumbou environment with meteorological data from two locations along the north-south climatological gradient observed in the Sahel–both for warmer, drier scenarios from the north and cooler, wetter scenarios from the south. These shifts in climate represent hypothetical but historically realistic climate change scenarios. For Banizoumbou climatic conditions (latitude 13.54 N), a shift toward cooler, wetter conditions may dramatically increase mosquito abundance; however, our modeling results indicate that the increased malaria transmissibility is not simply proportional to the precipitation increase. The cooler, wetter conditions increase the length of the sporogonic cycle, dampening a large vectorial capacity increase otherwise brought about by increased mosquito survival and greater overall abundance. Furthermore, simulations varying rainfall event frequency demonstrate the importance of precipitation patterns, rather than simply average or time-integrated precipitation, as a controlling factor of these dynamics. Modeling results suggest that in addition to changes in temperature and total precipitation, changes in rainfall patterns are very important to predict changes in disease susceptibility resulting from climate shifts. The combined effect of these climate-shift-induced perturbations can be represented with the aid of a detailed mechanistic model.

DOI 10.1007/s10393-010-0274-5
Alternate Journal Ecohealth
Relevant Projects:
Mosquitoes, Monsoons, and Malaria in Africa
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