Bayesian risk maps for Schistosoma mansoni and hookworm mono-infections in a setting where both parasites co-exist

There is growing interest in the use of Bayesian geostatistical models for predicting the spatial distribution of parasitic infections, including hookworm, <em>Schistosoma mansoni</em> and co-infections with both parasites. The aim of this study was to predict the spatial distribution of...

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Bibliographic Details
Main Authors: Giovanna Raso, Penelope Vounatsou, Donald P. McManus, Jürg Utzinger
Format: Article
Language:English
Published: PAGEPress Publications 2007-11-01
Series:Geospatial Health
Subjects:
Online Access:http://www.geospatialhealth.net/index.php/gh/article/view/257
Description
Summary:There is growing interest in the use of Bayesian geostatistical models for predicting the spatial distribution of parasitic infections, including hookworm, <em>Schistosoma mansoni</em> and co-infections with both parasites. The aim of this study was to predict the spatial distribution of mono-infections with either hookworm or <em>S. mansoni</em> in a setting where both parasites co-exist. School-based cross-sectional parasitological and questionnaire surveys were carried out in 57 rural schools in the Man region, western Côte d’Ivoire. A single stool specimen was obtained from each schoolchild attending grades 3-5. Stool specimens were processed by the Kato-Katz technique and an ether concentration method and examined for the presence of hookworm and <em>S. mansoni</em> eggs. The combined results from the two diagnostic approaches were considered for the infection status of each child. Demographic data (i.e. age and sex) were obtained from readily available school registries. Each child’s socio-economic status was estimated, using the questionnaire data following a household-based asset approach. Environmental data were extracted from satellite imagery. The different data sources were incorporated into a geographical information system. Finally, a Bayesian spatial multinomial regression model was constructed and the spatial patterns of <em>S. mansoni</em> and hookworm mono-infections were investigated using Bayesian kriging. Our approach facilitated the production of smooth risk maps for hookworm and <em>S. mansoni</em> mono-infections that can be utilized for targeting control interventions. We argue that in settings where <em>S. mansoni</em> and hookworm co-exist and control efforts are under way, there is a need for both mono- and co-infection risk maps to enhance the cost-effectiveness of control programmes.
ISSN:1827-1987
1970-7096