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Research output: Contribution to Journal/Magazine › Journal article › peer-review
Research output: Contribution to Journal/Magazine › Journal article › peer-review
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TY - JOUR
T1 - A multivariate geostatistical framework for combining multiple indices of abundance for disease vectors and reservoirs
T2 - a case study of rattiness in a low-income urban Brazilian community
AU - Eyre, Max
AU - Carvalho-Pereira, Ticiana
AU - Souza, Fábio N.
AU - Hussein, Khalil
AU - Hacker, Kathryn P.
AU - Serrano, Soledad
AU - Taylor, Joshua
AU - Reis, Mitermayer G.
AU - Ko, Albert I.
AU - Begon, Mike
AU - Diggle, Peter
AU - Costa, Federico
AU - Giorgi, Emanuele
PY - 2020/9/30
Y1 - 2020/9/30
N2 - A key requirement in studies of endemic vector-borne or zoonotic disease is an estimate of the spatial variation in vector or reservoir host abundance. For many vector species, multiple indices of abundance are available, but current approaches to choosing between or combining these indices do not fully exploit the potential inferential benefits that might accrue from modelling their joint spatial distribution. Here, we develop a class of multivariate generalized linear geostatistical models for multiple indices of abundance. We illustrate this novel methodology with a case study on Norway rats in a low-income urban Brazilian community, where rat abundance is a likely risk factor for human leptospirosis. We combine three indices of rat abundance to draw predictive inferences on a spatially continuous latent process, rattiness, that acts as a proxy for abundance. We show how to explore the association between rattiness and spatially varying environmental factors, evaluate the relative importance of each of the three contributing indices and assess the presence of residual, unexplained spatial variation, and identify rattiness hotspots. The proposed methodology is applicable more generally as a tool for understanding the role of vector or reservoir host abundance in predicting spatial variation in the risk of human disease.
AB - A key requirement in studies of endemic vector-borne or zoonotic disease is an estimate of the spatial variation in vector or reservoir host abundance. For many vector species, multiple indices of abundance are available, but current approaches to choosing between or combining these indices do not fully exploit the potential inferential benefits that might accrue from modelling their joint spatial distribution. Here, we develop a class of multivariate generalized linear geostatistical models for multiple indices of abundance. We illustrate this novel methodology with a case study on Norway rats in a low-income urban Brazilian community, where rat abundance is a likely risk factor for human leptospirosis. We combine three indices of rat abundance to draw predictive inferences on a spatially continuous latent process, rattiness, that acts as a proxy for abundance. We show how to explore the association between rattiness and spatially varying environmental factors, evaluate the relative importance of each of the three contributing indices and assess the presence of residual, unexplained spatial variation, and identify rattiness hotspots. The proposed methodology is applicable more generally as a tool for understanding the role of vector or reservoir host abundance in predicting spatial variation in the risk of human disease.
KW - Norway rat
KW - zoonotic and vector-borne diseases
KW - multivariate model-based geostatistics
KW - abundance indices
KW - epidemiology
KW - leptospirosis
U2 - 10.1098/rsif.2020.0398
DO - 10.1098/rsif.2020.0398
M3 - Journal article
VL - 17
JO - Interface
JF - Interface
SN - 1742-5689
IS - 170
ER -