Abstract
There is a rich history of models for the interaction of a biological contagion like influenza with the spread of related information such as an influenza vaccination campaign. Recent work on the spread of interacting contagions on networks has highlighted that these interacting contagions can have counter-intuitive interplay with network structure. Here we generalize one of these frameworks to tackle three important features of the spread of awareness and disease: one, we model the dynamics on highly clustered, cliquish, networks to mimic the role of workplaces and households; two, the awareness contagion affects the spread of the biological contagion by reducing its transmission rate where an aware or vaccinated individual is less likely to be infected; and three, the biological contagion also affects the spread of the awareness contagion but by increasing its transmission rate where an infected individual is more receptive and more likely to share information related to the disease. Under these conditions, we find that increasing network clustering, which is known to hinder disease spread, can actually allow them to sustain larger epidemics of the disease in models with awareness. This counter-intuitive result goes against the conventional wisdom suggesting that random networks are justifiable as they provide worst-case scenario forecasts. To further investigate this result, we provide a closed-form criterion based on a two-step branching process (i.e., the numbers of expected tertiary infections) to identify different regions in parameter space where the net effect of clustering and co-infection varies. Altogether, our results highlight once again the need to go beyond random networks in disease modeling and illustrate the type of analysis that is possible even in complex models of interacting contagions.
Highlights
Models of contagion are used to study the transmission dynamics of a pathogen or information being transmitted through a structured population
We can use the previous analysis to (i) identify whether the disease can maintain an outbreak despite clustering and awareness (i.e., if R1(D) > 1) and (ii) evaluate whether a clustered network structure will lead to larger epidemic peaks than an equivalent random network (i.e., if R1(D)/R1(A) is larger with C > 0)
We explored the effects of awareness in a model that looks at both disease and awareness as cocontagions in a parasitic relationship: spread of the disease leads to transmission of awareness which in turn leads to decreased disease prevalence as a result of reduced disease transmission around aware individuals
Summary
Models of contagion are used to study the transmission dynamics of a pathogen or information being transmitted through a structured population. Most of these are defined as compartmental models [1], which mathematically distinguishes individuals based on their state; i.e., whether they are susceptible to a contagion or infectious with that contagion. Of particular interest is the coupling of an infectious disease with the spread of preventative information related to the disease [2] We typically expect this “disease awareness” to at least hinder, if not completely stop, the spread of the pathogen. Our results raise potential questions about optimal coupling between the epidemiological parameters of a disease, the behavioral parameters of awareness, and the network structure of the population
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