Abstract
Models of disease spreading are critical for predicting infection growth in a population and evaluating public health policies. However, standard models typically represent the dynamics of disease transmission between individuals using macroscopic parameters that do not accurately represent person-to-person variability. To address this issue, we present a dynamic network model that provides a straightforward way to incorporate both disease transmission dynamics at the individual scale as well as the full spatiotemporal history of infection at the population scale. We find that disease spreads through a social network as a traveling wave of infection, followed by a traveling wave of recovery, with the onset and dynamics of spreading determined by the interplay between disease transmission and recovery. We use these insights to develop a scaling theory that predicts the dynamics of infection for diverse diseases and populations. Furthermore, we show how spatial heterogeneities in susceptibility to infection can either exacerbate or quell the spread of disease, depending on its infectivity. Ultimately, our dynamic network approach provides a simple way to model disease spreading that unifies previous findings and can be generalized to diverse diseases, containment strategies, seasonal conditions, and community structures.
Highlights
Epidemic spreads—such as the 1918 flu, HIV/AIDS, and COVID-19 pandemics—highlight the critical importance of infectious disease modeling in our everyday lives
Our approach is inspired by dynamic network modeling of fluiddriven transport in heterogeneous media, which seeks to predict spatiotemporal features of spreading in complex settings [46,47,48,49,50,51,52,53,54,55,56,57]
For diverse diseases and populations, disease spreading can be understood as a process of infection percolation through a social network
Summary
Epidemic spreads—such as the 1918 flu, HIV/AIDS, and COVID-19 pandemics—highlight the critical importance of infectious disease modeling in our everyday lives. In one representation, members of a population are divided into three intermixed groups: those who are susceptible to infection (S), currently infected (I), or recovered from infection (R), with transitions from S → I and I → R occurring at prescribed rates. This standard model, known as the SIR model or the SI model in the absence of recovery, can successfully predict the initial exponential and eventual logistic dynamics of the total amount of infection in a population for many diseases [3,4,5,6]. The SIR model provides a useful approach for disease modeling that is well-established
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