Characterizing the interface between wild ducks and poultry to evaluate the potential of transmission of avian pathogens
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  • 作者:Julien Cappelle (1)
    Nicolas Gaidet (1)
    Samuel A Iverson (2)
    John Y Takekawa (2)
    Scott H Newman (3)
    Bouba Fofana (4) (5)
    Marius Gilbert (6) (7)
  • 关键词:Distribution modelling ; Satellite Telemetry ; Contact rate ; Remote sensing ; MODIS ; GPS ; Maxent
  • 刊名:International Journal of Health Geographics
  • 出版年:2011
  • 出版时间:December 2011
  • 年:2011
  • 卷:10
  • 期:1
  • 全文大小:454KB
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  • 作者单位:Julien Cappelle (1)
    Nicolas Gaidet (1)
    Samuel A Iverson (2)
    John Y Takekawa (2)
    Scott H Newman (3)
    Bouba Fofana (4) (5)
    Marius Gilbert (6) (7)

    1. CIRAD ES, UR Animal et Gestion int茅gr茅e des risques, Montpellier, France
    2. USGS Western Ecological Research Center, Vallejo, CA, USA
    3. Food and Agriculture Organisation, EMPRES Wildlife Unit, Infectious Disease Group Animal Health Service, Animal Production and Health Division, Rome, Italy
    4. Wetlands International, PO Box 471, 6700 AL, Wageningen, The Netherlands
    5. Direction Nationale des Eaux et For锚ts du Mali, BP 275, Bamako, Mali
    6. Biological Control and Spatial Ecology, Universit茅 Libre de Bruxelles, av FD Roosevelt, 50, B-1050, Brussels, Belgium
    7. Fonds National de la Recherche Scientifiques, rue d鈥橢gmont 5, B-1000, Brussels, Belgium
  • ISSN:1476-072X
文摘
Background Characterizing the interface between wild and domestic animal populations is increasingly recognized as essential in the context of emerging infectious diseases (EIDs) that are transmitted by wildlife. More specifically, the spatial and temporal distribution of contact rates between wild and domestic hosts is a key parameter for modeling EIDs transmission dynamics. We integrated satellite telemetry, remote sensing and ground-based surveys to evaluate the spatio-temporal dynamics of indirect contacts between wild and domestic birds to estimate the risk that avian pathogens such as avian influenza and Newcastle viruses will be transmitted between wildlife to poultry. We monitored comb ducks (Sarkidiornis melanotos melanotos) with satellite transmitters for seven months in an extensive Afro-tropical wetland (the Inner Niger Delta) in Mali and characterise the spatial distribution of backyard poultry in villages. We modelled the spatial distribution of wild ducks using 250-meter spatial resolution and 8-days temporal resolution remotely-sensed environmental indicators based on a Maxent niche modelling method. Results Our results show a strong seasonal variation in potential contact rate between wild ducks and poultry. We found that the exposure of poultry to wild birds was greatest at the end of the dry season and the beginning of the rainy season, when comb ducks disperse from natural water bodies to irrigated areas near villages. Conclusions Our study provides at a local scale a quantitative evidence of the seasonal variability of contact rate between wild and domestic bird populations. It illustrates a GIS-based methodology for estimating epidemiological contact rates at the wildlife and livestock interface integrating high-resolution satellite telemetry and remote sensing data.
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