Open AccessThe statistics of epidemic transitions
Author(s) -
John M. Drake,
Tobias Brett,
Shiyang Chen,
Bogdan I. Epureanu,
Matthew J. Ferrari,
Éric Marty,
Paige B. Miller,
Eamon B. O’Dea,
Suzanne M. O’Regan,
Andrew Park,
Pejman Rohani
Publication year - 2019
Publication title -
plos computational biology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.628
H-Index - 182
eISSN - 1553-7358
pISSN - 1553-734X
DOI - 10.1371/journal.pcbi.1006917
Subject(s) - statistical physics , dynamical systems theory , dynamics (music) , observable , transition (genetics) , system dynamics , computer science , perspective (graphical) , physics , biology , artificial intelligence , biochemistry , quantum mechanics , acoustics , gene
Emerging and re-emerging pathogens exhibit very complex dynamics, are hard to model and difficult to predict. Their dynamics might appear intractable. However, new statistical approaches—rooted in dynamical systems and the theory of stochastic processes—have yielded insight into the dynamics of emerging and re-emerging pathogens. We argue that these approaches may lead to new methods for predicting epidemics. This perspective views pathogen emergence and re-emergence as a “critical transition,” and uses the concept of noisy dynamic bifurcation to understand the relationship between the system observables and the distance to this transition. Because the system dynamics exhibit characteristic fluctuations in response to perturbations for a system in the vicinity of a critical point, we propose this information may be harnessed to develop early warning signals. Specifically, the motion of perturbations slows as the system approaches the transition.
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