Predictability in a highly stochastic system: final size of measles epidemics in small populations

Caudron, Quentin; Mahmud, Ayesha S.; Metcalf, C. Jessica E.; Gottfreðsson, Magnús; Viboud, Cécile; Cliff, Andrew; Grenfell, Bryan T.

doi:10.1098/rsif.2014.1125

Cited by 19 publications

(23 citation statements)

References 19 publications

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“…At the most predictable scales, the Susceptible-Infected-Recovered (SIR) family of models has been used to analyze measles dynamics in city and country metapopulations (1)(2)(3)(4), as well as in allowing for heterogeneities in space (5,6), age (7,8), and population sizes (9,10). As a badge of simplicity, SIR models successfully assume well-mixed mass action in city populations (i.e., that the number of individuals who will become infected is proportional to the total number currently infected as well as those currently susceptible).…”

mentioning

confidence: 99%

Estimating enhanced prevaccination measles transmission hotspots in the context of cross-scale dynamics

Becker

Birger

Teillant

et al. 2016

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

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A key question in clarifying human-environment interactions is how dynamic complexity develops across integrative scales from molecular to population and global levels. Apart from its public health importance, measles is an excellent test bed for such an analysis. Simple mechanistic models have successfully illuminated measles dynamics at the city and country levels, revealing seasonal forcing of transmission as a major driver of long-term epidemic behavior. Seasonal forcing ties closely to patterns of school aggregation at the individual and community levels, but there are few explicit estimates of school transmission due to the relative lack of epidemic data at this scale. Here, we use data from a 1904 measles outbreak in schools in Woolwich, London, coupled with a stochastic Susceptible-Infected-Recovered model to analyze measles incidence data. Our results indicate that transmission within schools and age classes is higher than previous populationlevel serological data would suggest. This analysis sheds quantitative light on the role of school-aged children in measles cross-scale dynamics, as we illustrate with references to the contemporary vaccination landscape.cross-scale dynamics | measles | mathematical model | childhood infection | vaccine refusal

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mentioning

confidence: 99%

Estimating enhanced prevaccination measles transmission hotspots in the context of cross-scale dynamics

Becker

Birger

Teillant

et al. 2016

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

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“…Here, the mixing parameter α indicates homogeneous frequency-dependent contact rate between cases in each province. We fixed the mixing parameter due to the tradeoff between capturing heterogeneity in transmission or mixing, a method commonly used in tSIR studies focused on transmission dynamics [10,53–56]. Given the similar transmission dynamics of chikungunya and Zika, we set the mixing parameter equal to 0.74, the value for chikungunya calculated in the Perkins et al study [2,51].…”

Section: Methodsmentioning

confidence: 99%

Climate drives spatial variation in Zika epidemics in Latin America

Harris

Caldwell

Mordecai

2018

Preprint

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24Between 2015 and 2017, Zika virus spread rapidly through populations in the Americas with no 25 prior exposure to the disease. Although climate is a known determinant of many Aedes- 26 transmitted diseases, it is currently unclear whether climate was a major driver the of Zika 27 epidemic and how climate might have differentially impacted outbreak intensity across locations 28 within Latin America. Here, we estimated force of infection for Zika over time and across 29 provinces in Latin America using a time-varying Susceptible Infectious Recovered model. 30 Climate factors explained less than 5% of the variation in weekly transmission intensity in a 31 spatiotemporal model of force of infection by province over time, suggesting that week to week 32 transmission within provinces may be too stochastic to predict. By contrast, climate and 33 population factors were highly predictive of spatial variation in the presence and intensity of 34 Zika transmission among provinces, with pseudo R 2 values between 0.33 and 0.60. Temperature, 35 temperature range, rainfall, and population size were the most important predictors of where 36 Zika transmission occurred, while rainfall, relative humidity, and a nonlinear effect of 37 temperature were the best predictors of Zika intensity and burden. Surprisingly, force of 38 infection was greatest in locations with temperatures near 24°C, much lower than previous 39 estimates from mechanistic models, potentially suggesting that existing vector control programs 40 and/or prior exposure to other mosquito-borne diseases may have limited transmission in 41 locations most suitable for Aedes aegypti, the main vector of Zika, dengue, and chikungunya 42 viruses in Latin America. 43 44 45 46 48health concern, yet trends in mosquito-borne disease transmission are hard to predict because 49 they are influenced by the underlying immunity in the population, which is usually unknown [1-50 3]. The emergence and spread of Zika virus through Latin America in a population with no prior 51 exposure or immunity to the disease provides an opportunity to characterize relationships among 52 the environment, populations, and disease transmission without the confounding effects of pre-53 existing immunity (although cross-reactivity between dengue antibodies and Zika virus may 54 provide some protection) [4]. Between 2015 and 2017, Zika rapidly spread to 51 countries and 55 territories in the Americas, with over 800,000 cases reported [5]. Here, we quantified the force of 56 infection for Zika and studied factors that contributed to variation in transmission across time 57 and space as Zika emerged. 58 Force of infection, or the per capita rate at which susceptible individuals contract an 59 infection, can be used to compare disease transmission over the course of an outbreak and across 60 geographic regions [2,6]. Force of infection estimates can account for variation in the number of 61 immune individuals and entomological factors that influence the time it takes for mosquito-borne 62dise...

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“…The R 2 ranged from 0.98 -0.92 for large cities, and was still reasonably high (0.74) for small communities. Extensions of measles modeling to small communities that have highly stochastic dynamics still achieved R 2 of 0.86 to 0.55, with 5 out of 6 communities scoring higher than 0.73 (Caudron et al, 2015). A recent review gives a comprehensive account of the predictability of influenza outbreaks, comparing time series modeling, individual-based, compartmental and metapopulation models (Nsoesie et al, 2014).…”

Section: Epidemiologymentioning

confidence: 99%

The practice of prediction: What can ecologists learn from applied, ecology-related fields?

Pennekamp

Adamson

Petchey

et al. 2017

Ecological Complexity

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The pervasive influence of human induced global environmental change affects biodiversity across the globe, and there is great uncertainty as to how the biosphere will react on short and longer time scales. To adapt to what the future holds and to manage the impacts of global change, scientists need to predict the expected effects with some confidence and communicate these predictions to policy makers. However, recent reviews found that we currently lack a clear understanding of how predictable ecology is, with views seeing it as mostly unpredictable to potentially predictable, at least over short time frames. However, in applied, ecology-related fields predictions are more commonly formulated and reported, as well as evaluated in hindsight, potentially allowing one to define baselines of predictive proficiency in these fields. We searched the literature for representative case studies in these fields and collected information about modeling approaches, target variables of prediction, predictive proficiency achieved, as well as the availability of data to parameterize predictive models. We find that some fields such as epidemiology achieve high predictive proficiency, but even in the more predictive fields proficiency is evaluated in different ways. Both phenomenological and mechanistic approaches are used in most fields, but differences are often small, with no clear superiority of one approach over the other. Data availability is limiting in most fields, with long-term studies being rare and detailed data for parameterizing mechanistic models being in short supply. We suggest that ecologists adopt a more rigorous approach to report and assess predictive proficiency, and embrace the challenges of real world decision making to strengthen the practice of prediction in ecology.

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Predictability in a highly stochastic system: final size of measles epidemics in small populations

Cited by 19 publications

References 19 publications

Estimating enhanced prevaccination measles transmission hotspots in the context of cross-scale dynamics

Estimating enhanced prevaccination measles transmission hotspots in the context of cross-scale dynamics

Climate drives spatial variation in Zika epidemics in Latin America

The practice of prediction: What can ecologists learn from applied, ecology-related fields?

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