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Literature DB >> 20421468

Individual identity and movement networks for disease metapopulations.

Matt J Keeling¹, Leon Danon, Matthew C Vernon, Thomas A House.

Abstract

The theory of networks has had a huge impact in both the physical and life sciences, shaping our understanding of the interaction between multiple elements in complex systems. In particular, networks have been extensively used in predicting the spread of infectious diseases where individuals, or populations of individuals, interact with a limited set of others-defining the network through which the disease can spread. Here for such disease models we consider three assumptions for capturing the network of movements between populations, and focus on two applied problems supported by detailed data from Great Britain: the commuter movement of workers between local areas (wards) and the permanent movement of cattle between farms. For such metapopulation networks, we show that the identity of individuals responsible for making network connections can have a significant impact on the infection dynamics, with clear implications for detailed public health and veterinary applications.

Entities: Chemical

Mesh：

Year: 2010 PMID： 20421468 PMCID： PMC2889353 DOI： 10.1073/pnas.1000416107

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

28 in total

Individual identity and movement networks for disease metapopulations.

1. Modeling the influence of settlement structure on the spread of influenza among communities.

2. Epidemiology. How viruses spread among computers and people.

3. Assessing the impact of airline travel on the geographic spread of pandemic influenza.

4. Modelling disease outbreaks in realistic urban social networks.

5. Comparison of smallpox outbreak control strategies using a spatial metapopulation model.

6. The role of the airline transportation network in the prediction and predictability of global epidemics.

7. Collective dynamics of 'small-world' networks.

8. Social networks and infectious disease: the Colorado Springs Study.

9. The role of routine versus random movements on the spread of disease in Great Britain.

10. Representing the UK's cattle herd as static and dynamic networks.

1. Optimizing surveillance for livestock disease spreading through animal movements.

2. Invasion threshold in structured populations with recurrent mobility patterns.

3. Paradoxical effects of coupling infectious livestock populations and imposing transport restrictions.

Review 4. Connecting Mobility to Infectious Diseases: The Promise and Limits of Mobile Phone Data.

5. Contact, Travel, and Transmission: The Impact of Winter Holidays on Influenza Dynamics in the United States.

6. Human mobility patterns predict divergent epidemic dynamics among cities.

7. Socially structured human movement shapes dengue transmission despite the diffusive effect of mosquito dispersal.

8. Forecasting the spatial transmission of influenza in the United States.

9. Interventions for avian influenza A (H5N1) risk management in live bird market networks.

10. Comparing metapopulation dynamics of infectious diseases under different models of human movement.