Abstract
The rapid pace of urbanization makes it imperative that we better understand the influence of climate forcing on urban malaria transmission. Despite extensive study of temperature effects in vector-borne infections in general, consideration of relative humidity remains limited. With process-based dynamical models informed by almost two decades of monthly surveillance data, we address the role of relative humidity in the interannual variability of epidemic malaria in two semi-arid cities of India. We show a strong and significant effect of humidity during the pre-transmission season on malaria burden in coastal Surat and more arid inland Ahmedabad. Simulations of the climate-driven transmission model with the MLE (Maximum Likelihood Estimates) of the parameters retrospectively capture the observed variability of disease incidence, and also prospectively predict that of ‘out-of-fit’ cases in more recent years, with high accuracy. Our findings indicate that relative humidity is a critical factor in the spread of urban malaria and potentially other vector-borne epidemics, and that climate change and lack of hydrological planning in cities might jeopardize malaria elimination efforts.
Highlights
The rapid pace of urbanization makes it imperative that we better understand the influence of climate forcing on urban malaria transmission
Cities of South Asia from Thailand to the Arabian Peninsula, and throughout the Indian subcontinent, harbor the mosquito Anopheles stephensi, a truly urban vector that thrives in the built human environment
When the average monthly relative humidity (RH) is below 60%, the lifespan of the mosquito should be too short for effective malaria transmission[22,23]
Summary
The rapid pace of urbanization makes it imperative that we better understand the influence of climate forcing on urban malaria transmission. In regions of unstable malaria, transmission is most sensitive to changes in the vector’s lifespan[17,24] This sensitivity is relevant for An. stephensi, with a relatively short lifespan[25,26], and points to humidity as a potential critical parameter for this urban vector (in the more arid range of its niche). Despite these observations, most mathematical models of malaria transmission rely exclusively on studies of the temperature dependence of fundamental demographic parameters for Anopheles gambiae (and for the development of Plasmodium falciparum within this vector), including rates of parasite sporogony, vector survival, and biting[25,26,27,28]
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