Abstract
Ecological regression studies are widely used in geographical epidemiology to assess the relationships between health hazard and putative risk factors. Very often, health data are measured at an aggregate level because of confidentiality restrictions, while putative risk factors are measured on a different grid, i.e., independent (exposure) variable and response (counts) variable are spatially misaligned. To perform a regression of risk on exposure, one needs to realign the spatial support of the variables. Bayesian hierarchical models constitute a natural approach to the problem because of their ability to model the exposure field and the relationship between exposure and relative risk at different levels of the hierarchy, taking proper account of the variability induced by the covariate estimation. In the current paper, we propose two fully Bayesian solutions to the problem. The first one is based on the kernel-smoothing technique, while the second one is built on the tessellation of the study region. We illustrate our methods by assessing the relationship between exposure to uranium in drinkable waters and cancer incidence, in South Carolina (USA).
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References
Azzalini, A. and Bowman, A. (1997) Applied smoothing techniques for data Analysis. Oxford Science publications.
S. Banerjee A.E. Gelfand (2002) ArticleTitlePrediction, interpolation and regression for spatially misaligned data The Indian Journal of Statistics, Series A 64 227–45
J. Besag J. York A. Mollié (1991) ArticleTitleBayesian image restoration, with two applications in spatial statistics Ann. Inst. Statist. Math. 43 1–21
L. Bernardinelli C. Montomoli (1992) ArticleTitleEmpirical Bayes versus fully Bayesian analysis of geographical variations in disease risk Statistics in Medicine 11 983–1007 Occurrence Handle1:STN:280:By2A2MfgtFM%3D Occurrence Handle1496200
Best, N. (1999) Bayesian ecological modelling. In: Disease Mapping and Risk Assessment For Public Health, Wiley, Chichester, pp.193–201.
N.G. Best K. Ickstadt R.L. Wolpert (2000) ArticleTitleSpatial Poisson regression for health and exposure data measured at disparate resolutions Journal of the American Statistical Association 95 1076–88
Brewer, M.J. (1998) A Modelling Approach for Bandwidth Selection in Kernel Density Estimation. In COMPSTAT 1998 Proceedings, pp. 203–8.
M.J. Brewer (2000) ArticleTitleA Model-based approach for variable bandwidth selection in kernel density estimation Statistics and Computing 10 299–310 Occurrence Handle10.1023/A:1008925425102
Carlin, B.P., Xia, H., Devine, O., Tolbert, P., and Mulholland, J. (1999) Spatio-temporal hierarchical models for analyzing Atlanta pediatric asthma ER visits rates. In: Gatsonis, C., et al. (ed.), Case Studies in Bayesian Statistics, vol. IV, Springer-Verlag, New York, pp. 303–20.
A.E. Gelfand L. Zhu B.P. Carlin (2001) ArticleTitleOn the change of support problem for spatio-temporal data Biostatistics 2 31–45 Occurrence Handle10.1093/biostatistics/2.1.31 Occurrence Handle12933555
C.A. Gotway L.J. Young (2002) ArticleTitleCombining incompatible spatial data Journal of the American Statistical Association 97 632–48 Occurrence Handle10.1198/016214502760047140
A. Mollié (1996) Bayesian mapping of disease. In: Markov Chain Monte Carlo in practice Chapman & Hall London
A.S. Mugglin B.P. Carlin (1998) ArticleTitleHierarchical modelling in geographic information system: population interpolation over incompatible zones Journal of Agricultural, Biological and Environmental Statistics 3 111–30
A.S. Mugglin B.P. Carlin A.E. Gelfand (2000) ArticleTitleFully model-based approaches for spatially misaligned data Journal of American Statistical Association 95 877–87
Spiegelhalter, D., Thomas, A., and Best, N. (1998) WinBugs: Bayesian Inference Using Gibbs Sampler, Manula Version 1.2. Imperial College, London and Medical Research Council Biostatistics Unit, Cambridge.
G. Voronoi (1908) ArticleTitleRecherches sur les paralléloèdres Primitives J. reine angew. Math. 134 198–87
M.P. Wand M.C. Jones (1995) Kernel Smoothing Chapman & Hall London
G.S. Watson (1964) ArticleTitleSmooth regression analysis Sankhya, Series A. 26 359–72
L. Zhu B.P. Carlin P. English R. Scalf (2000) ArticleTitleHierarchical modelling of spatio-temporally misaligned data: relating density to paediatric asthma hospitalisations Environmetrics 11 43–61 Occurrence Handle10.1002/(SICI)1099-095X(200001/02)11:1<43::AID-ENV380>3.0.CO;2-V Occurrence Handle1:CAS:528:DC%2BD3cXptVOmsQ%3D%3D
L. Zhu B.P. Carlin A.E. Gelfand (2003) ArticleTitleHierarchical regression with misaligned spatial data: relating ambient ozone and paediatric asthma ER visits in Atlanta Environmetrics 14 537–557 Occurrence Handle10.1002/env.614
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Greco, F.P., Lawson, A.B., Cocchi, D. et al. Some Interpolation Estimators in Environmental Risk Assessment for Spatially Misaligned Health Data. Environ Ecol Stat 12, 379–395 (2005). https://doi.org/10.1007/s10651-005-1520-9
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DOI: https://doi.org/10.1007/s10651-005-1520-9