Stochastic fluctuations in epidemics on networks

The effects of demographic stochasticity on the long-term behaviour of endemic infectious diseases have been considered for long as a necessary addition to an underlying deterministic theory. The latter would explain the regular behaviour of recurrent epidemics and the former the superimposed noise of observed incidence patterns. Recently, a stochastic theory based on a mechanism of resonance with internal noise has shifted the role of stochasticity closer to the centre stage, by showing that the major dynamic patterns found in the incidence data can be explained as resonant fluctuations, whose behaviour is largely independent of the amplitude of seasonal forcing, and by contrast very sensitive to the basic epidemiological parameters. Here we elaborate on that approach, by adding an ingredient which is missing in standard epidemic models, the ‘mixing network’ through which infection may propagate. We find that spatial correlations have a major effect on the enhancement of the amplitude and the coherence of the resonant stochastic fluctuations, providing the ordered patterns of recurrent epidemics, whose period may differ significantly from that of the small oscillations around the deterministic equilibrium. We also show that the inclusion of a more realistic, time-correlated recovery profile instead of exponentially distributed infectious periods may, even in the random-mixing limit, contribute to the same effect.

[1]  Aravind Srinivasan,et al.  Modelling disease outbreaks in realistic urban social networks , 2004, Nature.

[2]  Matt J Keeling,et al.  Modeling dynamic and network heterogeneities in the spread of sexually transmitted diseases , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[3]  R. May,et al.  Infection dynamics on scale-free networks. , 2001, Physical review. E, Statistical, nonlinear, and soft matter physics.

[4]  A L Lloyd,et al.  Realistic distributions of infectious periods in epidemic models: changing patterns of persistence and dynamics. , 2001, Theoretical population biology.

[5]  S. Riley Large-Scale Spatial-Transmission Models of Infectious Disease , 2007, Science.

[6]  Norman T. J. Bailey,et al.  The Mathematical Theory of Infectious Diseases , 1975 .

[7]  Alessandro Vespignani,et al.  Epidemic spreading in scale-free networks. , 2000, Physical review letters.

[8]  A J McKane,et al.  Predator-prey cycles from resonant amplification of demographic stochasticity. , 2005, Physical review letters.

[9]  Bryan Grenfell,et al.  Sexually transmitted diseases: Epidemic cycling and immunity , 2005, Nature.

[10]  N M Ferguson,et al.  Mass vaccination to control chickenpox: the influence of zoster. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[11]  Wendi Wang,et al.  Epidemic models with nonlinear infection forces. , 2005, Mathematical biosciences and engineering : MBE.

[12]  J. Benoit,et al.  Pair approximation models for disease spread , 2005, q-bio/0510005.

[13]  Pejman Rohani,et al.  Appropriate Models for the Management of Infectious Diseases , 2005, PLoS medicine.

[14]  Albert-László Barabási,et al.  Statistical mechanics of complex networks , 2001, ArXiv.

[15]  H. Hethcote,et al.  An age-structured model for pertussis transmission. , 1997, Mathematical biosciences.

[16]  M. Keeling The implications of network structure for epidemic dynamics. , 2005, Theoretical population biology.

[17]  A. J. Hall Infectious diseases of humans: R. M. Anderson & R. M. May. Oxford etc.: Oxford University Press, 1991. viii + 757 pp. Price £50. ISBN 0-19-854599-1 , 1992 .

[18]  Alun L Lloyd,et al.  Estimating variability in models for recurrent epidemics: assessing the use of moment closure techniques. , 2004, Theoretical population biology.

[19]  M. Newman,et al.  Network theory and SARS: predicting outbreak diversity , 2004, Journal of Theoretical Biology.

[20]  A L Lloyd,et al.  Destabilization of epidemic models with the inclusion of realistic distributions of infectious periods , 2001, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[21]  D. Zanette Dynamics of rumor propagation on small-world networks. , 2001, Physical review. E, Statistical, nonlinear, and soft matter physics.

[22]  D. Earn,et al.  Transients and attractors in epidemics , 2003, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[23]  B. T. Grenfell,et al.  Disease Extinction and Community Size: Modeling the Persistence of Measles , 1997, Science.

[24]  D. Earn,et al.  A simple model for complex dynamical transitions in epidemics. , 2000, Science.

[25]  Bernard Cazelles,et al.  Large-scale comparative analysis of pertussis population dynamics: periodicity, synchrony, and impact of vaccination. , 2005, American journal of epidemiology.

[26]  D. Gillespie A General Method for Numerically Simulating the Stochastic Time Evolution of Coupled Chemical Reactions , 1976 .

[27]  A. B. Bortz,et al.  A new algorithm for Monte Carlo simulation of Ising spin systems , 1975 .

[28]  M. Kuperman,et al.  Small world effect in an epidemiological model. , 2000, Physical review letters.

[29]  M. Keeling,et al.  Networks and epidemic models , 2005, Journal of The Royal Society Interface.

[30]  W M Schaffer,et al.  Oscillations and chaos in epidemics: a nonlinear dynamic study of six childhood diseases in Copenhagen, Denmark. , 1988, Theoretical population biology.

[31]  Duncan J. Watts,et al.  Collective dynamics of ‘small-world’ networks , 1998, Nature.

[32]  M. M. Telo da Gama,et al.  Epidemics in small world networks , 2005, q-bio/0509044.

[33]  C. Fraser,et al.  Transmission Dynamics of the Etiological Agent of SARS in Hong Kong: Impact of Public Health Interventions , 2003, Science.

[34]  Roch Roy,et al.  Stochastic modeling of empirical time series of childhood infectious diseases data before and after mass vaccination , 2006, Emerging themes in epidemiology.

[35]  J. Dushoff,et al.  Dynamical resonance can account for seasonality of influenza epidemics. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[36]  Ingemar Nåsell,et al.  A new look at the critical community size for childhood infections. , 2005, Theoretical population biology.

[37]  Lauren Ancel Meyers,et al.  SIR epidemics in dynamic contact networks , 2007, 0705.2105.

[38]  J. Wylie,et al.  Gonorrhoea and chlamydia core groups and sexual networks in Manitoba , 2002, Sexually transmitted infections.

[39]  G. Szabó,et al.  Cooperation for volunteering and partially random partnerships. , 2004, Physical review. E, Statistical, nonlinear, and soft matter physics.

[40]  M. Bartlett Measles Periodicity and Community Size , 1957 .

[41]  M. Pascual,et al.  Stochastic amplification in epidemics , 2007, Journal of The Royal Society Interface.

[42]  Pejman Rohani,et al.  Seasonnally forced disease dynamics explored as switching between attractors , 2001 .

[43]  S. N. Dorogovtsev,et al.  Evolution of networks , 2001, cond-mat/0106144.

[44]  M M Telo da Gama,et al.  Recurrent epidemics in small world networks. , 2004, Journal of theoretical biology.

[45]  O. Bjørnstad,et al.  Travelling waves and spatial hierarchies in measles epidemics , 2001, Nature.

[46]  J Wallinga,et al.  Mixing patterns and the spread of close-contact infectious diseases , 2006, Emerging themes in epidemiology.

[47]  L. Allen,et al.  Stochastic epidemic models with a backward bifurcation. , 2006, Mathematical biosciences and engineering : MBE.