Improvement of disease prediction and modeling through the use of meteorological ensembles: human plague in Uganda

Climate and weather influence the occurrence, distribution, and incidence of infectious diseases, particularly those caused by vector-borne or zoonotic pathogens. Thus, models based on meteorological data have helped predict when and where human cases are most likely to occur. Such knowledge aids in...

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Veröffentlicht in:	PloS one 2012-09, Vol.7 (9), p.e44431
Hauptverfasser:	Moore, Sean M, Monaghan, Andrew, Griffith, Kevin S, Apangu, Titus, Mead, Paul S, Eisen, Rebecca J
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Antibiotics Atmospheric models Biology Climate Climate and weather Climate change Climate models Datasets Disease control Disease prevention Dry season Earth Sciences Epidemics Fatalities Geography Health aspects Humans Incidence Infectious diseases Medicine Meteorological conditions Meteorological data Meteorological observations Models, Statistical Morbidity Mortality Plague Plague - epidemiology Precipitation Prevention Prognosis Rain Rainfall Risk Factors Tropical environment Tropical environments Uganda - epidemiology Variables Vector-borne diseases Vectors (Biology) Weather Weather patterns Zoonoses
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creator	Moore, Sean M Monaghan, Andrew Griffith, Kevin S Apangu, Titus Mead, Paul S Eisen, Rebecca J
description	Climate and weather influence the occurrence, distribution, and incidence of infectious diseases, particularly those caused by vector-borne or zoonotic pathogens. Thus, models based on meteorological data have helped predict when and where human cases are most likely to occur. Such knowledge aids in targeting limited prevention and control resources and may ultimately reduce the burden of diseases. Paradoxically, localities where such models could yield the greatest benefits, such as tropical regions where morbidity and mortality caused by vector-borne diseases is greatest, often lack high-quality in situ local meteorological data. Satellite- and model-based gridded climate datasets can be used to approximate local meteorological conditions in data-sparse regions, however their accuracy varies. Here we investigate how the selection of a particular dataset can influence the outcomes of disease forecasting models. Our model system focuses on plague (Yersinia pestis infection) in the West Nile region of Uganda. The majority of recent human cases have been reported from East Africa and Madagascar, where meteorological observations are sparse and topography yields complex weather patterns. Using an ensemble of meteorological datasets and model-averaging techniques we find that the number of suspected cases in the West Nile region was negatively associated with dry season rainfall (December-February) and positively with rainfall prior to the plague season. We demonstrate that ensembles of available meteorological datasets can be used to quantify climatic uncertainty and minimize its impacts on infectious disease models. These methods are particularly valuable in regions with sparse observational networks and high morbidity and mortality from vector-borne diseases.
doi_str_mv	10.1371/journal.pone.0044431
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subjects	Analysis Antibiotics Atmospheric models Biology Climate Climate and weather Climate change Climate models Datasets Disease control Disease prevention Dry season Earth Sciences Epidemics Fatalities Geography Health aspects Humans Incidence Infectious diseases Medicine Meteorological conditions Meteorological data Meteorological observations Models, Statistical Morbidity Mortality Plague Plague - epidemiology Precipitation Prevention Prognosis Rain Rainfall Risk Factors Tropical environment Tropical environments Uganda - epidemiology Variables Vector-borne diseases Vectors (Biology) Weather Weather patterns Zoonoses
title	Improvement of disease prediction and modeling through the use of meteorological ensembles: human plague in Uganda
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