%0 Journal Article %1 Ames2011 %A Ames, Gregory M. %A George, Dylan B. %A Hampson, Christian P. %A Kanarek, Andrew R. %A McBee, Cayla D. %A Lockwood, Dale R. %A Achter, Jeffrey D. %A Webb, Colleen T. %D 2011 %J Proc. R. Soc. B %K clustering epidemics epidemiology graphs moment-closure networks sis-model %R 10.1098/rspb.2011.0290 %T Using network properties to predict disease dynamics on human contact networks %X Recent studies have increasingly turned to graph theory to model more realistic contact structures that characterize disease spread. Because of the computational demands of these methods, many researchers have sought to use measures of network structure to modify analytically tractable differential equation models. Several of these studies have focused on the degree distribution of the contact network as the basis for their modifications. We show that although degree distribution is sufficient to predict disease behaviour on very sparse or very dense human contact networks, for intermediate density networks we must include information on clustering and path length to accurately predict disease behaviour. Using these three metrics, we were able to explain more than 98 per cent of the variation in endemic disease levels in our stochastic simulations.

@article{Ames2011, abstract = {Recent studies have increasingly turned to graph theory to model more realistic contact structures that characterize disease spread. Because of the computational demands of these methods, many researchers have sought to use measures of network structure to modify analytically tractable differential equation models. Several of these studies have focused on the degree distribution of the contact network as the basis for their modifications. We show that although degree distribution is sufficient to predict disease behaviour on very sparse or very dense human contact networks, for intermediate density networks we must include information on clustering and path length to accurately predict disease behaviour. Using these three metrics, we were able to explain more than 98 per cent of the variation in endemic disease levels in our stochastic simulations.}, added-at = {2011-05-10T16:44:51.000+0200}, author = {Ames, Gregory M. and George, Dylan B. and Hampson, Christian P. and Kanarek, Andrew R. and McBee, Cayla D. and Lockwood, Dale R. and Achter, Jeffrey D. and Webb, Colleen T.}, biburl = {https://www.bibsonomy.org/bibtex/2af372c9db7f2ced6a8e77275e225f5e9/rincedd}, doi = {10.1098/rspb.2011.0290}, file = {Ames2011 - Using network properties to predict disease dynamics on human contact networks.pdf:Contact Processes/Ames2011 - Using network properties to predict disease dynamics on human contact networks.pdf:PDF}, groups = {public}, interhash = {d308e8fac5765275b4b854d2c4882f25}, intrahash = {c896873fdabd8ca422ece812fccfa932}, journal = {Proc. R. Soc. B}, keywords = {clustering epidemics epidemiology graphs moment-closure networks sis-model}, note = {published online before print}, timestamp = {2011-05-10T16:47:09.000+0200}, title = {Using network properties to predict disease dynamics on human contact networks}, username = {rincedd}, year = 2011 }