Disease mapping and spatial regression with count data

doi:10.1093/biostatistics/kxl008

Biostatistics Advance Access originally published online on June 29, 2006
Biostatistics 2007 8(2):158-183; doi:10.1093/biostatistics/kxl008

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Disease mapping and spatial regression with count data

Jon Wakefield^*

Departments of Statistics and Biostatistics, Box 357232, University of Washington, Seattle, WA 98195-7232, USA jonno{at}u.washington.edu

^* To whom correspondence should be addressed.

In this paper, we provide critical reviews of methods suggestedfor the analysis of aggregate count data in the context of diseasemapping and spatial regression. We introduce a new method forpicking prior distributions, and propose a number of refinementsof previously used models. We also consider ecological bias,mutual standardization, and choice of both spatial model andprior specification. We analyze male lip cancer incidence datacollected in Scotland over the period 1975–1980, and outlinea number of problems with previous analyses of these data. Indisease mapping studies, hierarchical models can provide robustestimation of area-level risk parameters, though care is requiredin the choice of covariate model, and it is important to assessthe sensitivity of estimates to the spatial model chosen, andto the prior specifications on the variance parameters. Spatialecological regression is a far more hazardous enterprise fortwo reasons. First, there is always the possibility of ecologicalbias, and this can only be alleviated by the inclusion of individual-leveldata. For the Scottish data, we show that the previously usedmean model has limited interpretation from an individual perspective.Second, when residual spatial dependence is modeled, and ifthe exposure has spatial structure, then estimates of exposureassociation parameters will change when compared with thoseobtained from the independence across space model, and the dataalone cannot choose the form and extent of spatial correlationthat is appropriate.

Keywords: Bayesian methods; Ecological bias; Ecological correlation studies; Hierarchical models; Prior distributions; Spatial epidemiology; Standardization

Received December 19, 2005; revised May 6, 2006; revised June 10, 2006; accepted for publication June 15, 2006.

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