Theory of early warning signals of disease emergenceand leading indicators of elimination

O’Regan, Suzanne M.; Drake, John M.

doi:10.1007/s12080-013-0185-5

Cited by 90 publications

(178 citation statements)

References 50 publications

(43 reference statements)

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“…A maladapted pathogen with R 0 < 1 can cause an epidemic if its R 0 exceeds 1 (due to, for instance, mutations or changes in the host population), which is how new pathogens can emerge by crossing the species barrier [13]. From a phase transition point-of-view, Reference [14] have studied the change in epidemiological quantities while approaching the critical point, in order to see if they can be used for anticipating the emergence of criticality and potential elimination of such dynamics. Their results suggest that theoretically, we can predict critical thresholds in epidemics [14], which could be of a substantial value in health care.…”

Section: Introductionmentioning

confidence: 99%

“…From a phase transition point-of-view, Reference [14] have studied the change in epidemiological quantities while approaching the critical point, in order to see if they can be used for anticipating the emergence of criticality and potential elimination of such dynamics. Their results suggest that theoretically, we can predict critical thresholds in epidemics [14], which could be of a substantial value in health care. In practice, one of the challenges lies in pinpointing such critical thresholds in finite-size systems, where a precise identification of phase transitions requires an estimation of the rate of change of the order parameter, often from finite and/or distributed data [15,16].…”

Section: Introductionmentioning

confidence: 99%

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Criticality and Information Dynamics in Epidemiological Models

Erten

Lizier

Piraveenan

et al. 2017

Entropy

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Abstract:Understanding epidemic dynamics has always been a challenge. As witnessed from the ongoing Zika or the seasonal Influenza epidemics, we still need to improve our analytical methods to better understand and control epidemics. While the emergence of complex sciences in the turn of the millennium have resulted in their implementation in modelling epidemics, there is still a need for improving our understanding of critical dynamics in epidemics. In this study, using agent-based modelling, we simulate a Susceptible-Infected-Susceptible (SIS) epidemic on a homogeneous network. We use transfer entropy and active information storage from information dynamics framework to characterise the critical transition in epidemiological models. Our study shows that both (bias-corrected) transfer entropy and active information storage maximise after the critical threshold (R 0 = 1). This is the first step toward an information dynamics approach to epidemics. Understanding the dynamics around the criticality in epidemiological models can provide us insights about emergent diseases and disease control.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Criticality and Information Dynamics in Epidemiological Models

Erten

Lizier

Piraveenan

et al. 2017

Entropy

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“…This critical transition becomes possible when the average number of infections caused by a single infectious individual in an entirely susceptible population (called R 0 ) becomes greater than 1-at this point the population is often referred to as supercritical [15,16]. Forecasting this critical transition is the goal of earlywarning systems [17 -19] of disease emergence [12]. In addition to knowing when a population will become supercritical [12], accurate forecasting also requires estimating the time of the first major outbreak or epidemic of a newly emerging or re-emerging disease.…”

Section: Introductionmentioning

confidence: 99%

Waiting time to infectious disease emergence

Dibble

O’Dea

Park

et al. 2016

J. R. Soc. Interface.

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Emerging diseases must make a transition from stuttering chains of transmission to sustained chains of transmission, but this critical transition need not coincide with the system becoming supercritical. That is, the introduction of infection to a supercritical system results in a significant fraction of the population becoming infected only with a certain probability. Understanding the waiting time to the first major outbreak of an emerging disease is then more complicated than determining when the system becomes supercritical. We treat emergence as a dynamic bifurcation, and use the concept of bifurcation delay to understand the time to emergence after a system becomes supercritical. Specifically, we consider an SIR model with a time-varying transmission term and random infections originating from outside the population. We derive an analytic density function for the delay times and find it to be, in general, in agreement with stochastic simulations. We find the key parameters to be the rate of introduction of infection and the rate of change of the basic reproductive ratio. These findings aid our understanding of real emergence events, and can be incorporated into early-warning systems aimed at forecasting disease risk.

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“…However, ENMs operate on a broader temporal scale than required for short‐term outbreak anticipation efforts. Early warning systems (EWSs), based on leading indicators (O'Regan & Drake, ; Brett, Drake & Rohani, ) or on climatic covariates (Thomson et al ., ; Semenza et al ., ), address the problem of outbreak prediction on a shorter timescale, and are a high priority for development for many diseases – but to our knowledge, these models have yet to be developed and deployed for anthrax. The existence of long‐term outbreak data sets from long‐term research sites like Etosha or Kruger could likely support the development of these tools, but the transferability of these models to other regions would be limited both by the selection of statistical fitting procedures, and by differences in the underlying eco‐epidemiological process across systems.…”

Section: Anthrax: a Case Study In Slow Integrationmentioning

confidence: 99%

Spores and soil from six sides: interdisciplinarity and the environmental biology of anthrax (Bacillus anthracis)

et al. 2018

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Environmentally transmitted diseases are comparatively poorly understood and managed, and their ecology is particularly understudied. Here we identify challenges of studying environmental transmission and persistence with a six-sided interdisciplinary review of the biology of anthrax (Bacillus anthracis). Anthrax is a zoonotic disease capable of maintaining infectious spore banks in soil for decades (or even potentially centuries), and the mechanisms of its environmental persistence have been the topic of significant research and controversy. Where anthrax is endemic, it plays an important ecological role, shaping the dynamics of entire herbivore communities. The complex eco-epidemiology of anthrax, and the mysterious biology of Bacillus anthracis during its environmental stage, have necessitated an interdisciplinary approach to pathogen research. Here, we illustrate different disciplinary perspectives through key advances made by researchers working in Etosha National Park, a long-term ecological research site in Namibia that has exemplified the complexities of the enzootic process of anthrax over decades of surveillance. In Etosha, the role of scavengers and alternative routes (waterborne transmission and flies) has proved unimportant relative to the long-term * Authors for correspondence: (Colin J. Carlson-Tel.: +1 (510) 990 2258; E-mail: ccarlson@sesync.org; Wayne M. Getz-Tel.: +1 510 642 8745; E-mail: wgetz@berkeley.edu; Nils C. Stenseth-Tel.: +47-22854584/+47-22854400; E-mail: n.c.stenseth@ibv.uio.no).Biological Reviews (2018) 000-000 © 2018 Cambridge Philosophical Society 2 Colin J. Carlson and others persistence of anthrax spores in soil and their infection of herbivore hosts. Carcass deposition facilitates green-ups of vegetation to attract herbivores, potentially facilitated by the role of anthrax spores in the rhizosphere. The underlying seasonal pattern of vegetation, and herbivores' immune and behavioural responses to anthrax risk, interact to produce regular 'anthrax seasons' that appear to be a stable feature of the Etosha ecosystem. Through the lens of microbiologists, geneticists, immunologists, ecologists, epidemiologists, and clinicians, we discuss how anthrax dynamics are shaped at the smallest scale by population genetics and interactions within the bacterial communities up to the broadest scales of ecosystem structure. We illustrate the benefits and challenges of this interdisciplinary approach to disease ecology, and suggest ways anthrax might offer insights into the biology of other important pathogens. Bacillus anthracis, and the more recently emerged Bacillus cereus biovar anthracis, share key features with other environmentally transmitted pathogens, including several zoonoses and panzootics of special interest for global health and conservation efforts. Understanding the dynamics of anthrax, and developing interdisciplinary research programs that explore environmental persistence, is a critical step forward for understanding these emerging threats.

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Theory of early warning signals of disease emergenceand leading indicators of elimination

Cited by 90 publications

References 50 publications

Criticality and Information Dynamics in Epidemiological Models

Criticality and Information Dynamics in Epidemiological Models

Waiting time to infectious disease emergence

Spores and soil from six sides: interdisciplinarity and the environmental biology of anthrax (Bacillus anthracis)

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