Long‐Distance Dispersal and Accelerating Waves of Disease: Empirical Relationships

Mundt, Christopher C.; Sackett, Kathryn E.; Wallace, LaRae D.; Cowger, Christina; Dudley, Joseph P.

doi:10.1086/597220

Cited by 103 publications

(110 citation statements)

References 48 publications

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“…3B). This acceleration rate, estimated solely from viral genomic data, is almost identical to that independently estimated from large-scale patterns of spatiotemporal WNV incidence (31). Such acceleration is theoretically predicted to occur when there is high variance in dispersal among infected hosts-specifically, when the dispersal kernel is positively skewed and "fat-tailed" (32).…”

Section: Resultssupporting

confidence: 64%

Unifying the spatial epidemiology and molecular evolution of emerging epidemics

Pybus

Suchard

Lemey

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

259

350

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We introduce a conceptual bridge between the previously unlinked fields of phylogenetics and mathematical spatial ecology, which enables the spatial parameters of an emerging epidemic to be directly estimated from sampled pathogen genome sequences. By using phylogenetic history to correct for spatial autocorrelation, we illustrate how a fundamental spatial variable, the diffusion coefficient, can be estimated using robust nonparametric statistics, and how heterogeneity in dispersal can be readily quantified. We apply this framework to the spread of the West Nile virus across North America, an important recent instance of spatial invasion by an emerging infectious disease. We demonstrate that the dispersal of West Nile virus is greater and far more variable than previously measured, such that its dissemination was critically determined by rare, long-range movements that are unlikely to be discerned during field observations. Our results indicate that, by ignoring this heterogeneity, previous models of the epidemic have substantially overestimated its basic reproductive number. More generally, our approach demonstrates that easily obtainable genetic data can be used to measure the spatial dynamics of natural populations that are otherwise difficult or costly to quantify.phylogeny | phylogeography | transmission T he explanation of spatial patterns of infectious disease, particularly those of emerging pathogens, has remained a central problem of epidemiology since its inception (1). The existence and nature of traveling waves of infection were first explained in theoretical models (2, 3) and later quantified in empirical studies of rabies and the Black Death (4, 5). These and other studies highlighted the fundamental problem of spatial autocorrelation: observations of infection are statistically dependent due to transmission among proximate individuals, greatly complicating the analysis of spatiotemporal incidence. Consequently, many recent analyses of spatial epidemic behavior use detailed mathematical models of spatial structure to account for autocorrelation (6). Entirely independently, in the field of evolutionary biology there has developed a separate body of work, now termed phylogeography, which focuses on reconstructing past movement events from the genome sequences of sampled organisms (7-10). However, these evolutionary tools typically generate descriptive results that, though informative, remain divorced from epidemiological theory. Crucially neither approach can be considered complete when applied to rapidly evolving viruses, whose spatial, epidemic, and evolutionary dynamics occur on the same timescale (11), necessitating the development of methods that consider all these processes together.Here we introduce a unique approach that integrates the disciplines of spatial epidemiology and phylogenetics. To illustrate the utility of this approach, we show how, from pathogen genomes alone, it can estimate the diffusion coefficient (D) of an epidemic as well as variation in the process of spatial spread. D is...

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Section: Resultssupporting

confidence: 64%

Unifying the spatial epidemiology and molecular evolution of emerging epidemics

Pybus

Suchard

Lemey

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

259

350

View full text Add to dashboard Cite

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“…Meaning of damage categories: 1, no damage; 2, low damage (defoliation substantially below 50 %), 3, moderate damage (defoliation around 50 %); 4, severe damage (defoliation substantially above 50 %). Data on 1224 farms in 2012 and information on first foci in 2011 were provided by ANACAFE The progress of coffee rust at this almost continental scale seems to follow the expected pattern for long distance dispersal diseases (Mundt et al 2009), where epidemic velocity increases with distance from the initial source. This observation indicates that wind probably played a key role in coffee rust spread, although the disease is already present in all of the coffee growing countries and possibly in all of the susceptible coffee plots of Mesoamerica.…”

Section: The Near Continental Scale Evolution Of Several Coffee Rust mentioning

confidence: 99%

The coffee rust crises in Colombia and Central America (2008–2013): impacts, plausible causes and proposed solutions

Cristancho²,

et al. 2015

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“…Transmission of pandemic diseases is often classified into contact and relocated diffusions which are caused, respectively, by short-and long-distance transmissions [8][9][10][11][12]. Contact diffusion refers to the short-distance spread of a disease outward from a central focus continuously in space.…”

Section: Introductionmentioning

confidence: 99%

Wet climate and transportation routes accelerate spread of human plague

Stige

Kausrud

et al. 2014

Proc. R. Soc. B.

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Currently, large-scale transmissions of infectious diseases are becoming more closely associated with accelerated globalization and climate change, but quantitative analyses are still rare. By using an extensive dataset consisting of date and location of cases for the third plague pandemic from 1772 to 1964 in China and a novel method (nearest neighbour approach) which deals with both short-and long-distance transmissions, we found the presence of major roads, rivers and coastline accelerated the spread of plague and shaped the transmission patterns. We found that plague spread velocity was positively associated with wet conditions (measured by an index of drought and flood events) in China, probably due to flood-driven transmission by people or rodents. Our study provides new insights on transmission patterns and possible mechanisms behind variability in transmission speed, with implications for prevention and control measures. The methodology may also be applicable to studies of disease dynamics or species movement in other systems.

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Long‐Distance Dispersal and Accelerating Waves of Disease: Empirical Relationships

Cited by 103 publications

References 48 publications

Unifying the spatial epidemiology and molecular evolution of emerging epidemics

Unifying the spatial epidemiology and molecular evolution of emerging epidemics

The coffee rust crises in Colombia and Central America (2008–2013): impacts, plausible causes and proposed solutions

Wet climate and transportation routes accelerate spread of human plague

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