95th ESA Annual Meeting (August 1 -- 6, 2010)

COS 12-8 - Quantifying the effects of space on disease transmission: A Bayesian analysis of smallpox outbreaks in Missions of the Southwest United States

Monday, August 2, 2010: 4:00 PM
412, David L Lawrence Convention Center
Bret D. Elderd, Department of Biological Sciences, Louisiana State University, Baton Rouge, LA, Vanja Dukic, Department of Health Studies, University of Chicago, Chicago, IL and Greg Dwyer, Department of Ecology and Evolution, University of Chicago, Chicago, IL
Background/Question/Methods

Spatial processes can be important for disease spread between populations as well as within populations.  Populations that are tightly linked spatially,  due to proximity and possibly other metrics, may have similar epidemic dynamics and, as a corollary, reproductive rates of disease spread R0.  Thus, the spatial covariance between populations may be important to account for when estimating R0 along with its associated uncertainty. The question remains whether models that account for spatial correlation between populations provide better estimates than those that do not.  Using a Bayesian susceptible-exposed-infected-recovered (SEIR) model, we quantified R0 for a set of eight smallpox outbreaks in Mission communities of the Southwest United States from 1780--1781.  We compared models that considered spatial correlation between outbreaks and those that did not using information theoretic criteria.  We also incorporated prior knowledge regarding the infectious and latency periods associated with smallpox to determine how prior information affected the distribution of R0
Results/Conclusions

As model complexity increased, the variability surrounding estimates of R0 also increased, which can have widespread consequences for controlling an epidemic or understanding disease spread.  In general, the spatial Bayesian SEIR models can properly combine the uncertainty associated with spatial and temporal processes to estimate R0 and, thus, provide a clearer understanding of epidemic dynamics.