DYNAMICS OF A NONLOCAL DISPERSAL FOOT-AND-MOUTH DISEASE MODEL IN A SPATIALLY HETEROGENEOUS ENVIRONMENT

doi:10.1007/s10473-021-0217-y

Abstract

Abstract: Foot-and-mouth disease is one of the major contagious zoonotic diseases in the world. It is caused by various species of the genus Aphthovirus of the family Picornavirus, and it always brings a large number of infections and heavy financial losses. The disease has become a major public health concern. In this paper, we propose a nonlocal foot-and-mouth disease model in a spatially heterogeneous environment, which couples virus-to-animals and animals-to-animals transmission pathways, and investigate the dynamics of the disperal. The basic reproduction number $\mathcal R_0$ is defined as the spectral radius of the next generation operator $\mathcal R(x)$ by a renewal equation. The relationship between $\mathcal R_0$ and a principal eigenvalue of an operator $\mathcal L_0$ is built. Moreover, the proposed system exhibits threshold dynamics in terms of $\mathcal R_0,$ in the sense that $\mathcal R_0$ determines whether or not foot-and-mouth disease invades the hosts. Through numerical simulations, we have found that increasing animals' movements is an effective control measure for preventing prevalence of the disease.

Key words: Nonlocal diffusion, nonlocal infection, the basic reproduction number, compactness

CLC Number:

92D30

Xiaoyan WANG, Junyuan YANG. DYNAMICS OF A NONLOCAL DISPERSAL FOOT-AND-MOUTH DISEASE MODEL IN A SPATIALLY HETEROGENEOUS ENVIRONMENT[J].Acta mathematica scientia,Series B, 2021, 41(2): 552-572.

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References

[1] Carpenter T E, O'Brien J M, Hagerman A D, McCarl B A. Epidemic and economic impacts of delayed detection of foot-and-mouth disease:a case study of a simulated outbreak in California. J Vet Diagn Invest, 2011, 23:26-33
[2] Matthews K. A Review of Australias Preparedness for the Threat of Foot-and-Mouth Disease[M/OL]. Canberra, ACT:Australian Government Department of Agriculture, Fisheries and Forestry 2011[2020-03-20]. http://www.agriculture.gov.au/animal-plant-health/pests-diseases-weeds/animal/fmd/review-footand-mouth-disease
[3] Rushton J, Knight-Jones T J D, Donaldson A I, deLeeuw P W, Ferrari G, Domenech J. The Impact of Foot and Mouth Disease-Supporting Document N1. Paper prepared for the FAO/OIE Global Conference on Foot and Mouth Disease Control. Thailand:Bangkok, 2012
[4] Brito B P, Rodriguez L L, Hammond J M, Pinto J, Perez A M. Review of the global distribution of foot-and-mouth disease virus from 2007 to 2014[J/OL]. Transbound Emerg Dis, 2017, 64:316-332. https://doi.org/10.1111/tbed.12373
[5] Jamal S M, Belsham G J. Foot-and-mouth disease:past, present and future[J/OL]. Vet Res, 2013, 44:116. https://doi.org/10.1186/1297-9716-44-116
[6] Meyer R F, Knudsen R C. Foot-and-mouth disease:are view of the virus and the symptoms. J Environ Health, 2001, 64:21-23
[7] Zhang T L, Zhao X Q. Mathematical modelling for schistosomiasis with seasonal influence:a case study in China. SIAM J Appl Dynam Sys, 2020, 19(2):1438-1417
[8] Luo X F, Jin Z. A new insight into isolating the high-degree nodes in network to control infectious diseases. Commun Nonlinear Sci Numer Simul, 2020, 91:105363
[9] Duan X C, Li X Z, Martcheva M. Qualitative analysis on a diffusive age-structured heroin transmission model. Nonlinear Anal:RWA, 2020, 54:103105
[10] Li X Z, Yang J Y, Martcheva M. Age structured epidemic modelling. Switzerland AG:Springer, 2002
[11] Sellers R F, Gloster J. The Northumberland epidemic of foot-and-mouth disease. 1966. J Hyg (Lond), 1980, 85(1):129-140
[12] Mikkelsen T, Alexandersen S, Astrup P, et al. Investigation of airborne foot and mouth disease virus transmission during low-wind conditions in the early phase of the UK 2001 epidemic. Atmos Chem Phys, 2003, 3:2101-2110
[13] Kao R R. The role of mathematical modelling in the control of the 2001 FMD epidemic in the UK. Trends Microbiol, 2002, 10(6):279-286
[14] Ferguson N M, Donnelly C A, Anderson R M. The foot-and-mouth epidemic in Great Britain:pattern of spread and impact of interventions. Science, 2001, 292:1155-1160
[15] Ferguson N M, Donnelly C A, Anderson R M. Transmission intensity and impact of control policies on the foot and mouth epidemic in Great Britain. Nature, 2001, 413:542-548
[16] Bradhurst R A, Roche S E, East I J, et al. A hybrid modelling approach to simulating foot-and-mouth disease outbreaks in Australian livestock. Front Environ Sci, 2015, 3:17
[17] Keeling M J, et al. Dynamics of the 2001 UK foot and mouth epidemic:stochastic dispersal in a heterogeneous landscape. Science, 2001, 294:813-817
[18] Keeling M J, Woolhouse M E J, May R M, et al. Modelling vaccination strategies against foot and mouth disease. Nature, 2003, 421:136-142
[19] Orsel K, Bouma A. The effect of foot-and-mouth disease (FMD) vaccination on virus transmission and the significance for the field. Can vet J, 2009, 50:1059-1063
[20] Orsel K, Dekker A, Bouma A, et al. Vaccination against foot and mouth disease reduces virus transmission in groups of calves. Vaccine, 2005, 23(41):4887-4894
[21] Tildesley M J, Bessell P R, Keeling M J, Woolhouse M E J. The role of pre-emptive culling in the control of foot-and-mouth disease. Proc Roy Soc Lond, B, Biol Sci, 2009, 276(1671):3239-3248
[22] Bates P W, Zhao G. Existence, uniqueness and stability of the stationary solution to a nonlocal evolution equation arising in population dispersal. J Math Anal Appl, 2007, 332(1):428-440
[23] Han B S, Yang Y H. On a predator-prey reaction diffusion model with nonlocal effects. Commun Nonlinear Sci Numer Simulat, 2017, 46:49-61
[24] Zhao G, Ruan S. Spatial and temporal dynamics of a nonlocal viral infection model. SIAM J Appl Math, 2018, 78(4):1954-1980
[25] Kuniya T, Wang J. Global dynamics of an SIR epidemic modelwith nonlocal diffusion. Nonlinear Anal:RWA, 2018, 43:262-282
[26] Bates P W. On some nonlocal evolution equations arising in materials science//Brunner H, Xhao X-Q, Zhou X. Nonlinear Dynamics and Evolution Equations. Fields Institute Communications, 2006, 48:13-52
[27] Tian H, Ju L, Du Q. A conservative nonlocal convection diffusion model and asymptotically compatible finite difference discretization. Comput Meth Appl Mech Engin, 2017, 320:46-67
[28] Zhang J, Jin Z, Yuan Y. Assessing the spread of foot and mouth disease in mainland China by dynamical switching model. J Theor Biol, 2019, 460:209-219
[29] Pazy A. Semigroups of Linear Operators and Application to Partial Differential Equations. New York:Springer-Verlag, 1983
[30] Webb G F. Theory of Nonlinear Age-Dependent Population Dynamics. New York:Marcel Dekker Inc, 1985
[31] Wang X Y, Chen Y M, Yang J Y. Spatial and temporal dynamics of a virus infection model with two nonlocal effects[J/OL]. Complexity, 2019, Art ID5842942. https://doi.org/10.1155/2019/5842942
[32] Hale J K. Asymptotic Behavior of Dissipative Systems. Mathematical Surveys and Monographs. Providence:American Mathematical Society, 1998
[33] Yang J, Xu F. The computational approach for the basic reproduction number of epidemic models on complex networks. IEEE Access, 2019, 7:26474-26479
[34] Yang J Y, Jin Z, Xu F. Threshold dynamics of an age-space structured SIR model on heterogeneous environment. Appl Math Letters, 2019, 96:68-74
[35] Wang W, Zhao X. Basic reproduction numbers for reaction-diffusion epidemic models. SIAM J Appl Dyn Sys, 2011, 11(4):1652-1673
[36] Diekmann O, Heesterbeek J A P, Metz J A J. On the definition and the computation of the basic reproduction ratio R₀ in models for infectious diseases in heterogeneous populations. J Math Biol, 1990, 28:365-382
[37] LaSalle J P. Some extensions of Liapunov's second method. Ire Transactions on Circuit Theory, 1960, 7(4):520-527
[38] Amann H. Fixed point equations and nonlinear eigenvalue problems in ordered Banach spaces. SIAM Rev, 1976, 18:620-709
[39] Smith H L, Zhao X Q. Robust persistence for semidynamical systems. Nonlinear Anal:TMA, 2001, 47(9):6169-6179
[40] Smith H L, Thieme H R. Dynamical systems and population persistence. Providence:American Mathematical Society, 2011
[41] Walker J A. Dynamical Systems and Evolution Equations:Theory and Applications. New York:Plenum Press, 1980
[42] Chatelin F. The spectral approximation of linear operators with applications to the computation of eigenelements of differential and itegral operators. SIAM Rev, 1981, 23:495-522
[43] Muroya Y, Enatsu Y, Kuniya T. Global stability for a class of multi-group SIR epidemic models with patches through migration and cross path infection. Acta Mathematica Scientia, 2013, 33B(2):341-361