Affiliation:
1. Institut National Polytechnique Félix Houphouët-Boigny
2. Institut National de Santé Publique
3. Swiss Centre for Scientific Research
4. Programme National de Lutte contre le Paludisme, Cote d'Ivoire
5. MIVEGEC, University of Montpellier, IRD, CNRS
Abstract
Abstract
Background
Wetlands and irrigated agricultural crops create potential breeding sites for Anopheles mosquitoes, leading to a heterogeneity in malaria transmission. In agricultural areas, heterogeneity of malaria transmission is often associated with the presence of hotspots consisting of localized clusters of higher transmission intensity. This study aims to identify micro-geographic hotspots of malaria transmission in an agricultural setting using a multidisciplinary approach.
Methods
We conducted two cross-sectional surveys at the end of the dry season and at the peak of the rainy season in rural and urban sites in Bouna, northeastern Côte d'Ivoire. We randomly selected 296 individuals from 148 farming households and collected sociological, geographical, entomological, and clinical data as well as blood samples during each visit. We compared parasitological data and Anopheles exposure (measured using entomological and immunological methods) with demographic, agricultural, and geographic data to identify drivers of malaria transmission. Heat maps combining these data were used to identify households with ongoing malaria transmission throughout the year.
Results
In rural areas, Plasmodium prevalence was consistent between the dry and the rainy seasons, with roughly half of the population presented with an infection. In urban areas, malaria transmission indicators were lower, with a parasite prevalence of less than 20%, which remained comparable between the dry and the rainy season. The presence of irrigated crops and proximity to wetlands were associated with increased Anopheles exposure. By mapping Plasmodium infection and Anopheles exposure, we identified 2 different types of hotspots of malaria transmission: micro-geographical scale and local scale hotspots.
Conclusions
The presence of wetlands in urban areas and irrigated agriculture in rural areas resulted in heterogeneity in malaria transmission on a micro-geographical scale. These specific households present particular risk of malaria transmission and could fuel malaria transmission in surrounding households. The identification of micro-geographical areas using heat maps combining several epidemiological parameters can help to identify hotspots of malaria transmission. The implementation of malaria control measures, such as seasonal chemoprophylaxis or vector control, in these areas could help to reduce the incidence of malaria and facilitate its elimination.
Publisher
Research Square Platform LLC
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