Abstract
Sociocentric network maps of entire populations, when combined with data on the nature of constituent dyadic relationships, offer the dual promise of advancing understanding of the relevance of networks for disease transmission and of improving epidemic forecasts. Here, using detailed sociocentric data collected over 4 years in a population of 24 702 people in 176 villages in Honduras, along with diarrhoeal and respiratory disease prevalence, we create a social-network-powered transmission model and identify super-spreading nodes as well as the nodes most vulnerable to infection, using agent-based Monte Carlo network simulations. We predict the extent of outbreaks for communicable diseases based on detailed social interaction patterns. Evidence from three waves of population-level surveys of diarrhoeal and respiratory illness indicates a meaningful positive correlation with the computed super-spreading capability and relative vulnerability of individual nodes. Previous research has identified super-spreaders through retrospective contact tracing or simulated networks. By contrast, our simulations predict that a node's super-spreading capability and its vulnerability in real communities are significantly affected by their connections, the nature of the interaction across these connections, individual characteristics (e.g. age and sex) that affect a person's ability to disperse a pathogen, and also the intrinsic characteristics of the pathogen (e.g. infectious period and latency). This article is part of the theme issue 'Data science approach to infectious disease surveillance'.
Highlights
Previous studies of biological and sociological features of human social interactions—including the evolutionary biology and genomics of social networks, their physiological implications and their possibly ancient heritage—suggest that natural selection has shaped social network structure and function [1,2,3,4]
Other research has revealed how pathogens affect transmission, documenting that transmission is an essential combination of pathogen infectious period and its overlap with host social interactions [12,13,14]
We introduce the pathogen to these networks, which, with its own characteristics—such as infectious period, incubation time and transmission probability—and host-specific characteristics transform these social edges into temporal probabilistic paths for disease transmission
Summary
Previous studies of biological and sociological features of human social interactions—including the evolutionary biology and genomics of social networks, their physiological implications and their possibly ancient heritage—suggest that natural selection has shaped social network structure and function [1,2,3,4]. The spread of infection in human communities has been analysed using compartmental epidemiological models like SIR/SEIR models [5] These models generally assume uniform and fully mixed populations, which often lead to incorrect estimates of predicted infection counts and R0 (basic reproduction number) [6,7]. We need approaches for characterizing possible heterogeneity in transmission across individuals, which, in particular, is defined based on a host’s social interactions (quantity and quality of interactions); their intrinsic ability to disperse a pathogen (e.g. based on their age and sex); and the transmission characteristics of the pathogens themselves (e.g. infectious periods and probability of transmission). A previous study has reported a very well-illustrated characterization of heterogeneity in transmission based on variation across individuals in their ability to spread a pathogen [8]. Our results show that network topology, quality of interaction and pathogen-specific dispersion play a crucial role in determining how vulnerable or super-spreading a node is
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