Litcius/Paper detail

Active and inactive quarantine in epidemic spreading on adaptive activity-driven networks

Marco Mancastroppa, Raffaella Burioni, Vittoria Colizza, A. Vezzani

2020Physical review. E39 citationsDOIOpen Access PDF

Abstract

We consider an epidemic process on adaptive activity-driven temporal networks, with adaptive behavior modeled as a change in activity and attractiveness due to infection. By using a mean-field approach, we derive an analytical estimate of the epidemic threshold for susceptible-infected-susceptible (SIS) and susceptible-infected-recovered (SIR) epidemic models for a general adaptive strategy, which strongly depends on the correlations between activity and attractiveness in the susceptible and infected states. We focus on strong social distancing, implementing two types of quarantine inspired by recent real case studies: an active quarantine, in which the population compensates the loss of links rewiring the ineffective connections towards nonquarantining nodes, and an inactive quarantine, in which the links with quarantined nodes are not rewired. Both strategies feature the same epidemic threshold but they strongly differ in the dynamics of the active phase. We show that the active quarantine is extremely less effective in reducing the impact of the epidemic in the active phase compared to the inactive one and that in the SIR model a late adoption of measures requires inactive quarantine to reach containment.

Topics & Concepts

QuarantineAttractivenessEpidemic modelPopulationComputer scienceCoronavirus disease 2019 (COVID-19)Social distanceBiologyDemographyEcologyMedicinePsychologySociologyDiseaseInfectious disease (medical specialty)PathologyPsychoanalysisComplex Network Analysis TechniquesCOVID-19 epidemiological studiesOpinion Dynamics and Social Influence