A mathematical model for the spread of West Nile virus in migratory and resident birds. (English) Zbl 1343.92461
Summary: We develop a mathematical model for transmission of West Nile virus (WNV) that incorporates resident and migratory host avian populations and a mosquito vector population. We provide a detailed analysis of the model’s basic reproductive number and demonstrate how the exposed infected, but not infectious, state for the bird population can be approximated by a reduced model. We use the model to investigate the interplay of WNV in both resident and migratory bird hosts. The resident host parameters correspond to the American Crow (Corvus brachyrhynchos), a competent host with a high death rate due to disease, and migratory host parameters to the American Robin (Turdus migratorius), a competent host with low WNV death rates. We find that yearly seasonal outbreaks depend primarily on the number of susceptible migrant birds entering the local population each season. We observe that the early growth rates of seasonal outbreaks is more influenced by the the migratory population than the resident bird population. This implies that although the death of highly competent resident birds, such as American Crows, are good indicators for the presence of the virus, these species have less impact on the basic reproductive number than the competent migratory birds with low death rates, such as the American Robins. The disease forecasts are most sensitive to the assumptions about the feeding preferences of North American mosquito vectors and the effect of the virus on the hosts. Increased research on the these factors would allow for better estimates of these important model parameters, which would improve the quality of future WNV forecasts.
MSC:
| 92D30 | Epidemiology |
Keywords:
West Nile virus; mathematical model; resident birds; migrating birds; basic reproduction number; seasonality; host preferenceReferences:
| [1] | A. Abdelrazec, Transmission dynamics of west nile virus in mosquitoes and corvids and non-corvids,, Journal of mathematical biology, 68, 1553 (2014) · Zbl 1284.92049 · doi:10.1007/s00285-013-0677-3 |
| [2] | L. Arriola, Sensitivity analysis for uncertainty quantification in mathematical models,, in Mathematical and Statistical Estimation Approaches in Epidemiology, 195 (2009) · Zbl 1345.92001 · doi:10.1007/978-90-481-2313-1_10 |
| [3] | L. M. Arriola, Being sensitive to uncertainty,, Computing in Science & Engineering, 9, 10 (2007) · doi:10.1109/MCSE.2007.27 |
| [4] | T. A. Beveroth, Changes in seroprevalence of west nile virus across illinois in free-ranging birds from 2001 through 2004,, The American journal of tropical medicine and hygiene, 74, 174 (2006) |
| [5] | D. B. Botkin, Mortality rates and survival of birds,, American Naturalist, 108, 181 (1974) · doi:10.1086/282898 |
| [6] | C. Bowman, A mathematical model for assessing control strategies against west nile virus,, Bulletin of mathematical biology, 67, 1107 (2005) · Zbl 1334.92392 · doi:10.1016/j.bulm.2005.01.002 |
| [7] | C. A. Bradley, Urban land use predicts west nile virus exposure in songbirds,, Ecological Applications, 18, 1083 (2008) · doi:10.1890/07-0822.1 |
| [8] | S. Chatterjee, Role of migratory birds under environmental fluctuation: a mathematical study,, Journal of Biological Systems, 16, 81 (2008) · Zbl 1148.92030 · doi:10.1142/S0218339008002423 |
| [9] | N. Chitnis, Bifurcation analysis of a mathematical model for malaria transmission,, SIAM Journal on Applied Mathematics, 67, 24 (2006) · Zbl 1107.92047 · doi:10.1137/050638941 |
| [10] | N. Chitnis, Determining important parameters in the spread of malaria through the sensitivity analysis of a mathematical model,, Bulletin of mathematical biology, 70, 1272 (2008) · Zbl 1142.92025 · doi:10.1007/s11538-008-9299-0 |
| [11] | N. Chitnis, Modelling vertical transmission in vector-borne diseases with applications to Rift Valley fever,, Journal of Biological Dynamics, 7, 11 (2013) · Zbl 1447.92407 · doi:10.1080/17513758.2012.733427 |
| [12] | D. Chowell-Puente, <em>The Impact of Mosquito-Bird Interaction on the Spread of West Nile Virus to Human Populations</em>,, Department of Biometrics |
| [13] | L. Colton, Quantification of west nile virus in vector mosquito saliva,, Journal of the American Mosquito Control Association, 21, 49 (2005) |
| [14] | G. Cruz-Pacheco, Modelling the dynamics of west nile virus,, Bulletin of mathematical biology, 67, 1157 (2005) · Zbl 1334.92397 · doi:10.1016/j.bulm.2004.11.008 |
| [15] | G. Cruz-Pacheco, Multi-species interactions in west nile virus infection,, Journal of Biological Dynamics, 6, 281 (2012) · Zbl 1447.92409 · doi:10.1080/17513758.2011.571721 |
| [16] | G. Cruz-Pacheco, Seasonality and outbreaks in west nile virus infection,, Bulletin of mathematical biology, 71, 1378 (2009) · Zbl 1171.92338 · doi:10.1007/s11538-009-9406-x |
| [17] | B. Durand, A metapopulation model to simulate west nile virus circulation in western africa, southern europe and the mediterranean basin,, Veterinary research, 41 |
| [18] | D. S. Farner, Age groups and longevity in the american robin: Comments, further discussion, and certain revisions,, The Wilson Bulletin, 68 |
| [19] | C. for Disease Control, Statistics, surveillance, and control archive,, <a href= (2012) |
| [20] | C. for Disease Control, West nile virus clinical description,, <a href= (2012) |
| [21] | C. for Disease Control, West nile virus questions and answers,, <a href= (2012) |
| [22] | L. B. Goddard, Vertical transmission of west nile virus by three california culex (diptera: Culicidae) species,, Journal of medical entomology, 40, 743 (2003) · doi:10.1603/0022-2585-40.6.743 |
| [23] | J. Heffernan, Perspectives on the basic reproductive ratio,, Journal of the Royal Society Interface, 2, 281 (2005) · doi:10.1098/rsif.2005.0042 |
| [24] | A. M. Kilpatrick, Predicting the global spread of h5n1 avian influenza,, Proceedings of the National Academy of Sciences, 103, 19368 (2006) · doi:10.1073/pnas.0609227103 |
| [25] | A. M. Kilpatrick, West nile virus epidemics in north america are driven by shifts in mosquito feeding behavior,, PLoS Biol, 4 (2006) · doi:10.1371/journal.pbio.0040082 |
| [26] | N. Komar, West nile virus: epidemiology and ecology in north america,, Advances in virus research, 61, 185 (2003) |
| [27] | J. L. Kwan, Antecedent avian immunity limits tangential transmission of west nile virus to humans,, PLoS ONE, 7 (2012) · doi:10.1371/journal.pone.0034127 |
| [28] | J. Mackenzie, Emerging flaviviruses: The spread and resurgence of japanese encephalitis, west nile and dengue viruses,, Nature medicine, 10 (2004) · doi:10.1038/nm1144 |
| [29] | C. A. Manore, Towards an early warning system for forecasting human west nile virus incidence,, PLoS currents, 6 (2014) · doi:10.1371/currents.outbreaks.f0b3978230599a56830ce30cb9ce0500 |
| [30] | C. A. Manore, Comparing dengue and chikungunya emergence and endemic transmission in A. aegypti and A. albopictus,, Journal of theoretical biology, 356, 174 (2014) · Zbl 1412.92292 · doi:10.1016/j.jtbi.2014.04.033 |
| [31] | R. G. McLean, West nile virus transmission and ecology in birds,, Annals of the New York Academy of Sciences, 951, 54 (2001) · doi:10.1111/j.1749-6632.2001.tb02684.x |
| [32] | S. Moore, Spatiotemporal model of barley and cereal yellow dwarf virus transmission dynamics with seasonality and plant competition,, Bulletin of Mathematical Biology, 73, 2707 (2011) · Zbl 1334.92420 · doi:10.1007/s11538-011-9654-4 |
| [33] | F. Morneau, Reproduction of american robin (turdus migratorius) in a suburban environment,, Landscape and urban planning, 32, 55 (1995) |
| [34] | A. T. Peterson, Migratory birds modeled as critical transport agents for west nile virus in north america,, Vector-Borne and Zoonotic Diseases, 3, 27 (2003) · doi:10.1089/153036603765627433 |
| [35] | Z. Qiu, Dynamics of an epidemic model with host migration,, Applied Mathematics and Computation, 218, 4614 (2011) · Zbl 1244.92050 · doi:10.1016/j.amc.2011.10.045 |
| [36] | W. K. Reisen, Overwintering of west nile virus in southern california,, Journal of medical entomology, 43, 344 (2006) · doi:10.1093/jmedent/43.2.344 |
| [37] | W. K. Reisen, Population dynamics of adult culex mosquitoes (diptera: Culicidae) along the kern river, kern county, california, in 1990,, Journal of medical entomology, 29, 531 (1992) · doi:10.1093/jmedent/29.3.531 |
| [38] | R. Rosà, Early warning of west nile virus mosquito vector: Climate and land use models successfully explain phenology and abundance of culex pipiens mosquitoes in north-western italy,, Parasites & vectors, 7 (2014) |
| [39] | M. R. Sardelis, Vector competence of selected north american culex and coquillettidia mosquitoes for west nile virus,, Emerging infectious diseases, 7 (2001) |
| [40] | J. E. Simpson, Vector host-feeding preferences drive transmission of multi-host pathogens: West nile virus as a model system,, Proceedings of the Royal Society B: Biological Sciences, 279, 925 (2012) · doi:10.1098/rspb.2011.1282 |
| [41] | J. P. Swaddle, Increased avian diversity is associated with lower incidence of human west nile infection: Observation of the dilution effect,, PloS one, 3 (2008) · doi:10.1371/journal.pone.0002488 |
| [42] | D. Thomas, A model describing the evolution of west nile-like encephalitis in new york city,, Mathematical and computer modelling, 34, 771 (2001) · Zbl 0999.92025 · doi:10.1016/S0895-7177(01)00098-X |
| [43] | S. Tiawsirisup, Susceptibility of ochlerotatus trivittatus (coq.), aedes albopictus (skuse), and culex pipiens (l.) to west nile virus infection,, Vector-Borne & Zoonotic Diseases, 4, 190 (2004) |
| [44] | S. Tiawsirisup, A comparision of west nile virus transmission by ochlerotatus trivittatus (coq.), culex pipiens (l.), and aedes albopictus (skuse),, Vector-Borne & Zoonotic Diseases, 5, 40 (2005) |
| [45] | M. J. Turell, Potential for north american mosquitoes to transmit west nile virus,, American Journal of Tropical Medicine and Hygiene, 62, 413 (2000) |
| [46] | R. Unnasch, A dynamic transmission model of eastern equine encephalitis virus,, Ecological modelling, 192, 425 (2006) · doi:10.1016/j.ecolmodel.2005.07.011 |
| [47] | P. Van den Driessche, Reproduction numbers and sub-threshold endemic equilibria for compartmental models of disease transmission,, Mathematical Biosciences, 180, 29 (2002) · Zbl 1015.92036 · doi:10.1016/S0025-5564(02)00108-6 |
| [48] | E. B. Vinogradova, <em>Culex pipiens pipiens mosquitoes: taxonomy, distribution, ecology, physiology, genetics, applied importance and control</em>,, Pensoft Publishers (2000) |
| [49] | T. P. Weber, Ecologic immunology of avian influenza (h5n1) in migratory birds,, Emerging infectious diseases, 13 (2007) · doi:10.3201/eid1308.070319 |
| [50] | M. J. Wonham, Transmission assumptions generate conflicting predictions in host-vector disease models: A case study in west nile virus,, Ecology Letters, 9, 706 (2006) · doi:10.1111/j.1461-0248.2006.00912.x |
| [51] | M. Wonham, An epidemiological model for west nile virus: Invasion analysis and control applications,, Proceedings of the Royal Society of London. Series B: Biological Sciences, 271, 501 (2004) · doi:10.1098/rspb.2003.2608 |
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