The spatial dynamics of dengue virus in Kamphaeng Phet, Thailand.

Timothy Endy,Anon Srikiatkhachorn,Piraya Bhoomiboonchoo,Derek A Cummings,Henrik Salje,In-Kyu Yoon,Alan L Rothman,Darunee Buddhari,Siripen Kalanarooj,Angkana Huang,Robert V Gibbons,Natkamol Chansatiporn,Mathuros Thipayamongkolgul,Mammen P Mammen,Sharone Green,Ananda Nisalak

doi:10.1371/journal.pntd.0003138

Abstract

BackgroundDengue is endemic to the rural province of Kamphaeng Phet, Northern Thailand. A decade of prospective cohort studies has provided important insights into the dengue viruses and their generated disease. However, as elsewhere, spatial dynamics of the pathogen remain poorly understood. In particular, the spatial scale of transmission and the scale of clustering are poorly characterized. This information is critical for effective deployment of spatially targeted interventions and for understanding the mechanisms that drive the dispersal of the virus.Methodology/Principal FindingsWe geocoded the home locations of 4,768 confirmed dengue cases admitted to the main hospital in Kamphaeng Phet province between 1994 and 2008. We used the phi clustering statistic to characterize short-term spatial dependence between cases. Further, to see if clustering of cases led to similar temporal patterns of disease across villages, we calculated the correlation in the long-term epidemic curves between communities. We found that cases were 2.9 times (95% confidence interval 2.7–3.2) more likely to live in the same village and be infected within the same month than expected given the underlying spatial and temporal distribution of cases. This fell to 1.4 times (1.2–1.7) for individuals living in villages 1 km apart. Significant clustering was observed up to 5 km. We found a steadily decreasing trend in the correlation in epidemics curves by distance: communities separated by up to 5 km had a mean correlation of 0.28 falling to 0.16 for communities separated between 20 km and 25 km. A potential explanation for these patterns is a role for human movement in spreading the pathogen between communities. Gravity style models, which attempt to capture population movement, outperformed competing models in describing the observed correlations.ConclusionsThere exists significant short-term clustering of cases within individual villages. Effective spatially and temporally targeted interventions deployed within villages may target ongoing transmission and reduce infection risk.

Highlights

Dengue remains a major public health concern throughout global tropical and subtropical regions
The objective of our study was to characterize the shortterm spatial dependence between dengue cases, to quantify the correlation in the long-term epidemics experienced by different communities and to explore the ability of human movement models to describe the observed correlations
Correlation between village clusters We explored whether any short-term spatial dependence between individual cases resulted in correlation in the epidemics experienced by different communities

Summary

Introduction

Dengue remains a major public health concern throughout global tropical and subtropical regions. An effective dengue vaccine remains elusive and intervention measures will continue to rely on mosquito control for the foreseeable future These efforts include the detection and removal of potential oviposition sites, the spraying of insecticides, and potentially the future releases of Wolbachia-infected mosquitoes that have been shown to reduce the mosquitoes’ ability to transmit dengue [4]. Effective use of these measures requires a good understanding of the spatial distribution of cases. This information is critical for effective deployment of spatially targeted interventions and for understanding the mechanisms that drive the dispersal of the virus

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Conclusion