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There are several reasons why spatial analysis is key to our integrated
assessment framework. First, different health outcomes require varying resolution of
climate model projections, necessitating specialized statistical analysis to achieve
realistic integration across the overall risk assessment. Second, many disease-carrying
vectors disperse and spread disease spatially; the dispersal of infected individuals also
spreads the disease spatially. This is apparent in the disease clusters observed for most
infectious diseases. Finally, although one strives to incorporate all of the known
covariates in the model, inevitably some will be missed. Spatially contiguous observations
can serve as effective proxies for such missing covariates. The incorporation of the
spatial component is known to have added not just to the realism of the models but also to
more accurate prediction and prediction errors by borrowing from spatially contiguous
observations (Clayton and Kaldor 1987; Yasui and Lele 1996; Lele and Taper 1996).
Spatial statistical analysis will help determine the spatial distribution of the
regional populations at risk. Disease may shift in distribution, rather than simply expand
or contract. For diseases such as dengue fever and Rocky Mountain Spotted Fever (RMSF),
well validated mathematical models have proven useful (Focks 1993,1995; Mount 1989) but
there are limitations to the purely deterministic models such as the Leslie Matrix model
used for vector-borne diseases. They do not provide a measure for uncertainty of the
predictions; such measures are central to supporting policy decisions. We will modify
these mathematical models in two ways: First, we will make them stochastic, explicitly
incorporating noise in the parameters. Such a modification, giving rise to Stochastic
Differential Equations, has proven valuable in theoretical population ecology (May 1974;
Dennis and Patil 1984). Second, we suggest explicitly incorporating spatial features to
enhance ecologically-based disease models.
| ecosystems
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| public health impacts
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| sampling
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| inference
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| spatial statistics
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