Effects of isolation and slaughter strategies in different species on emerging zoonoses
Pages: 1119  1140,
Issue 5/6,
October/December
2017
doi:10.3934/mbe.2017058 Abstract
References
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JingAn Cui  School of Science, Beijing University of Civil Engineering and Architecture, No. 1, Zhanlanguan Road, Xicheng District, Beijing 100044, China (email)
Fangyuan Chen  School of Science, Beijing University of Civil Engineering and Architecture, No. 1, Zhanlanguan Road, Xicheng District, Beijing 100044, China (email)
1 
L. J. S. Allen, Mathematical Modeling of Viral Zoonoses in Wildlife, Natural Resource Modeling, 25 (2012), 551. 

2 
J. Arino, R. Jordan and P. V. D. Driessche, Quarantine in a multispecies epidemic model with spatial dynamics, Mathematical Biosciences, 206 (2007), 4660. 

3 
R. M. Atlas and S. Maloy, One Health: People, Animals, and the Environment, ASM Press, 2014. 

4 
R. G. Bengis, F. A. Leighton and J. R. Fischer, The role of wildlife in emerging and reemerging zoonoses, Revue Scientifique Et Technique, 23 (2004), 497511. 

5 
F. Brauer and C. Chavez, Mathematical Models in Population Biology and Epidemiology, $2^{nd}$ edition, Springer, 2001. 

6 
N. Busquets, J. Segals and L. Crdoba, Experimental infection with H1N1 European swine influenza virus protects pigs from an infection with the 2009 pandemic H1N1 human influenza virus, Veterinary Research, 41 (2010), 571584. 

7 
China Agricultural Yearbook Editing Committee, ChinaAgriculture Yearbook, China Agriculture Press, China, 2012. 

8 
G. Chowell, Model parameters and outbreak control for SARS, Emerging Infectious Diseases, 10 (2004), 12581263. 

9 
B. J. Coburn, B. G. Wagner and S. Blower, Modeling influenza epidemics and pandemics: Insights into the future of swine flu (H1N1), Bmc Medicine, 7 (2009), p30. 

10 
B. J. Coburn, C. Cosne and S. Ruan, Emergence and dynamics of influenza superstrains, Bmc Public Health, 11 (2011), 597615. 

11 
R. W. Compans and M. B. A. Oldstone, Influenza Pathogenesis and Control  Volume I, Current Topics in Microbiology & Immunology, 2014. 

12 
M. R. Conover, Human Diseases from Wildlife, Boca Raton: CRC Press, Taylor & Francis Group, 2014. 

13 
M. Derouich and A. Boutayeb, An avian influenza mathematical model, Applied Mathematical Sciences, 2 (2008), 17491760. 

14 
K. Dietz, W. H. Wernsdorfer and I. Mcgregor, Mathematical Models for Transmission and Control of Malaria, Malaria, 1988. 

15 
A. Dobson, Population dynamics of pathogens with multiple host species, American Naturalist, 164 (2004), 6478. 

16 
P. Van Den Driessche and J. Watmough, Reproduction numbers and subthreshold endemic equilibria for compartmental models of disease transmission, Mathematical Biosciences, 180 (2002), 2948. 

17 
X. Fang, The Role of Mammals in Epidemiology, Acta Theriologica Sinica, 2 (1981), 219224. 

18 
Z. Feng, Final and peak epidemic sizes for SEIR models with quarantine and isolation, Mathematical Biosciences & Engineering, 4 (2007), 675686. 

19 
Z. Feng, Applications of Epidemiological Models to Public Health Policymaking, World Scientific, 2014. 

20 
A. Fritsche, R. Engel and D. Buhl, Mycobacterium bovis tuberculosis: From animal to man and back, International Journal of Tuberculosis & Lung Disease the Official Journal of the International Union Against Tuberculosis & Lung Disease, 8 (2004), 903904. 

21 
S. Iwami, Y. Takeuchi and X. Liu, AvianChuman influenza epidemic model, Mathematical Biosciences, 207 (2007), 125. 

22 
A. M. Kilpatrick and S. E. Randolph, Drivers, dynamics, and control of emerging vectorborne zoonotic diseases, Lancet, 380 (2012), 19461955. 

23 
J. Lee, J. Kim and H. D. Kwon, Optimal control of an influenza model with seasonal forcing and agedependent transmission rates, Journal of Theoretical Biology, 317 (2013), 310320. 

24 
J. S. Mackenzie, One Health: The HumanAnimalEnvironment Interfaces in Emerging Infectious Diseases, Springer, Berlin, 2013. 

25 
A. Mubayi, A costbased comparison of quarantine strategies for new emerging diseases, Mathematical Biosciences & Engineering, 7 (2010), 687717. 

26 
R. A. Saenz, H. W. Hethcote and G. C. Gray, Confined animal feeding operations as amplifiers of influenza, Vector Borne & Zoonotic Diseases, 6 (2006), 338346. 

27 
P. M. Sharp and B. H. Hahn, Crossspecies transmission and recombination of 'AIDS' viruses, Philosophical Transactions of the Royal Society B Biological Sciences, 349 (1995), 4147. 

28 
A. Sing, Zoonoses  Infections Affecting Humans and Animals, Springer Netherlands, Berlin, 2015. 

29 
S. Towers and Z. Feng, Pandemic H1N1 influenza: predicting the course of a pandemic and assessing the efficacy of the planned vaccination programme in the United States, European Communicable Disease Bulletin, 14 (2009), 68. 

30 
Q. Xian, L. Cui and Y. Jiao, Antigenic and genetic characterization of a European avianlike H1N1 swine influenza virus from a boy in China in 2011, Archives of Virology, 158 (2013), 3953. 

31 
W. D. Zhang, Optimized strategy for the control and prevention of newly emerging influenza revealed by the spread dynamics model, Plos One, 91 (2014), 551. 

32 
J. Zhang, Z. Jin and G. Q. Sun, Modeling seasonal rabies epidemics in China, Bulletin of Mathematical Biology, 74 (2012), 12261251. 

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