An Efficient Immunization Strategy for Community Networks

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2013 Dec 31

PMID 24376708

Citations 10

Authors

Kai Gong

Ming Tang

Pak Ming Hui

Hai Feng Zhang

Do Younghae

Ying-Cheng Lai

Affiliations

Soon will be listed here.

Abstract

An efficient algorithm that can properly identify the targets to immunize or quarantine for preventing an epidemic in a population without knowing the global structural information is of obvious importance. Typically, a population is characterized by its community structure and the heterogeneity in the weak ties among nodes bridging over communities. We propose and study an effective algorithm that searches for bridge hubs, which are bridge nodes with a larger number of weak ties, as immunizing targets based on the idea of referencing to an expanding friendship circle as a self-avoiding walk proceeds. Applying the algorithm to simulated networks and empirical networks constructed from social network data of five US universities, we show that the algorithm is more effective than other existing local algorithms for a given immunization coverage, with a reduced final epidemic ratio, lower peak prevalence and fewer nodes that need to be visited before identifying the target nodes. The effectiveness stems from the breaking up of community networks by successful searches on target nodes with more weak ties. The effectiveness remains robust even when errors exist in the structure of the networks.

Citing Articles

Vaccination strategies on dynamic networks with indirect transmission links and limited contact information.

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COVID-19 Spread in Saudi Arabia: Modeling, Simulation and Analysis.

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Immunization strategies in networks with missing data.

Rosenblatt S, Smith J, Gauthier G, Hebert-Dufresne L PLoS Comput Biol. 2020; 16(7):e1007897.

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Coupled effects of local movement and global interaction on contagion.

Zhong L, Xu W, Chen R, Qiu T, Shi Y, Zhong C Physica A. 2020; 436:482-491.

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Immunization strategy based on the critical node in percolation transition.

Liu Y, Wei B, Wang Z, Deng Y Phys Lett A. 2020; 379(43):2795-2801.

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