In this paper, an epidemic model is investigated for infectious diseases that can be transmitted through both the infectious individuals and the asymptomatic carriers (i.e., infected individuals who are contagious but do not show any disease symptoms). We propose a dose-structured vaccination model with multiple transmission pathways. Based on the range of the explicitly computed basic reproduction number, we prove the global stability of the disease-free when this threshold number is less or equal to the unity. Moreover, whenever it is greater than one, the existence of the unique endemic equilibrium is shown and its global stability is established for the case where the changes of displaying the disease symptoms are independent of the vulnerable classes. Further, the model is shown to exhibit a transcritical bifurcation with the unit basic reproduction number being the bifurcation parameter. The impacts of the asymptomatic carriers and the effectiveness of vaccination on the disease transmission are discussed through through the local and the global sensitivity analyses of the basic reproduction number. Finally, a case study of hepatitis B virus disease (HBV) is considered, with the numerical simulations presented to support the analytical results. They further suggest that, in high HBV prevalence countries, the combination of effective vaccination (i.e. doses of HepB vaccine), the diagnosis of asymptomatic carriers and the treatment of symptomatic carriers may have a much greater positive impact on the disease control.
Citation: Martin Luther Mann Manyombe, Joseph Mbang, Jean Lubuma, Berge Tsanou. Global dynamics of a vaccination model for infectious diseases with asymptomatic carriers[J]. Mathematical Biosciences and Engineering, 2016, 13(4): 813-840. doi: 10.3934/mbe.2016019
Related Papers:
[1]
Lusha Shi, Jianghong Hu, Zhen Jin .
Dynamics analysis of strangles with asymptomatic infected horses and long-term subclinical carriers. Mathematical Biosciences and Engineering, 2023, 20(10): 18386-18412.
doi: 10.3934/mbe.2023817
[2]
Lili Han, Mingfeng He, Xiao He, Qiuhui Pan .
Synergistic effects of vaccination and virus testing on the transmission of an infectious disease. Mathematical Biosciences and Engineering, 2023, 20(9): 16114-16130.
doi: 10.3934/mbe.2023719
[3]
Xing Zhang, Zhitao Li, Lixin Gao .
Stability analysis of a SAIR epidemic model on scale-free community networks. Mathematical Biosciences and Engineering, 2024, 21(3): 4648-4668.
doi: 10.3934/mbe.2024204
[4]
María Guadalupe Vázquez-Peña, Cruz Vargas-De-León, Jorge Fernando Camacho-Pérez, Jorge Velázquez-Castro .
Analysis and Bayesian estimation of a model for Chikungunya dynamics with relapse: An outbreak in Acapulco, Mexico. Mathematical Biosciences and Engineering, 2023, 20(10): 18123-18145.
doi: 10.3934/mbe.2023805
[5]
Suxia Zhang, Hongbin Guo, Robert Smith? .
Dynamical analysis for a hepatitis B transmission model with immigration and infection age. Mathematical Biosciences and Engineering, 2018, 15(6): 1291-1313.
doi: 10.3934/mbe.2018060
[6]
Maria Guadalupe Vazquez-Peña, Cruz Vargas-De-León, Jorge Velázquez-Castro .
Global stability for a mosquito-borne disease model with continuous-time age structure in the susceptible and relapsed host classes. Mathematical Biosciences and Engineering, 2024, 21(11): 7582-7600.
doi: 10.3934/mbe.2024333
[7]
Steady Mushayabasa, Drew Posny, Jin Wang .
Modeling the intrinsic dynamics of foot-and-mouth disease. Mathematical Biosciences and Engineering, 2016, 13(2): 425-442.
doi: 10.3934/mbe.2015010
Darja Kalajdzievska, Michael Yi Li .
Modeling the effects of carriers on transmission dynamics of infectious diseases. Mathematical Biosciences and Engineering, 2011, 8(3): 711-722.
doi: 10.3934/mbe.2011.8.711
[10]
Tingting Xue, Long Zhang, Xiaolin Fan .
Dynamic modeling and analysis of Hepatitis B epidemic with general incidence. Mathematical Biosciences and Engineering, 2023, 20(6): 10883-10908.
doi: 10.3934/mbe.2023483
Abstract
In this paper, an epidemic model is investigated for infectious diseases that can be transmitted through both the infectious individuals and the asymptomatic carriers (i.e., infected individuals who are contagious but do not show any disease symptoms). We propose a dose-structured vaccination model with multiple transmission pathways. Based on the range of the explicitly computed basic reproduction number, we prove the global stability of the disease-free when this threshold number is less or equal to the unity. Moreover, whenever it is greater than one, the existence of the unique endemic equilibrium is shown and its global stability is established for the case where the changes of displaying the disease symptoms are independent of the vulnerable classes. Further, the model is shown to exhibit a transcritical bifurcation with the unit basic reproduction number being the bifurcation parameter. The impacts of the asymptomatic carriers and the effectiveness of vaccination on the disease transmission are discussed through through the local and the global sensitivity analyses of the basic reproduction number. Finally, a case study of hepatitis B virus disease (HBV) is considered, with the numerical simulations presented to support the analytical results. They further suggest that, in high HBV prevalence countries, the combination of effective vaccination (i.e. doses of HepB vaccine), the diagnosis of asymptomatic carriers and the treatment of symptomatic carriers may have a much greater positive impact on the disease control.
References
[1]
Biomath, 4 (2015), 1507241, 30pp.
[2]
Oxford University Press, 1991.
[3]
SIAM J. Appl. Math., 64 (2003), 260-276.
[4]
Springer, New York, 2001.
[5]
Math.Biosci.Eng, 1 (2004), 361-404.
[6]
Math. Biosci., 180 (2002), 29-48.
[7]
Math. Biosci., 185 (2003), 89-109.
[8]
Vaccine, 19 (2001), 3799-3815.
[9]
Appl. Math. Comput., 152 (2004), 385-402.
[10]
Math. Biosci. Eng.,2 (2005), 753-769.
[11]
Int. J. Epidemiol., 34 (2005), 1329-1339.
[12]
Master Thesis, University of Tennessee, Knoxville, 2012.
[13]
Appl. Math. Comp, 143 (2003), 409-419.
[14]
Math. Biosci. Eng., 3 (2006), 513-525.
[15]
Math. Biosci. Eng., 3 (2006), 89-100.
[16]
Math. Biosci. Eng., 8 (2011), 711-722.
[17]
Bull. Math. Bio., 40 (1978), 707-718.
[18]
Bull. Math. Bio., 71 (2009), 75-83.
[19]
Regional Conference Series in Applied Mathematics, SIAM, Philadelphia, 1976.
[20]
J. Theor. Biol, 254 (2008), 178-196.
[21]
Nat. Med., 7 (2001), 617-624.
[22]
Nonlinear Analysis: Modelling and Control, 13 (2008), 331-350.
Miller Cerón Gómez, Eduardo Ibarguen Mondragon, Patricia Lopez Molano,
Global stability analysis for a model with carriers and non-linear incidence rate,
2020,
14,
1751-3758,
409,
10.1080/17513758.2020.1772998
2.
A. Feukouo Fossi, J. Lubuma, C. Tadmon, B. Tsanou,
Mathematical modeling and nonstandard finite difference scheme analysis for the environmental and spillover transmissions of Avian Influenza A model,
2021,
1468-9367,
1,
10.1080/14689367.2021.1872503
3.
Tsanou Berge, Samuel Bowong, Jean Lubuma, Martin Luther Mann Manyombe,
Modeling ebola virus disease transmissions with reservoir in a complex virus life ecology,
2017,
15,
1551-0018,
21,
10.3934/mbe.2018002
4.
Leontine Nkague Nkamba, Thomas Timothee Manga, Franklin Agouanet, Martin Luther Mann Manyombe,
Mathematical model to assess vaccination and effective contact rate impact in the spread of tuberculosis,
2019,
13,
1751-3758,
26,
10.1080/17513758.2018.1563218
5.
M.L. Mann Manyombe, B. Tsanou, J. Mbang, S. Bowong,
A metapopulation model for the population dynamics of anopheles mosquito,
2017,
307,
00963003,
71,
10.1016/j.amc.2017.02.039
6.
Jean Pierre II Kouenkam, Joseph Mbang, Yves Emvudu,
Global dynamics of a model of hepatitis B virus infection in a sub-Saharan African rural area,
2020,
13,
1793-5245,
2050054,
10.1142/S1793524520500540
7.
Hana M. Dobrovolny, Giovanni Lo Iacono,
Modeling the role of asymptomatics in infection spread with application to SARS-CoV-2,
2020,
15,
1932-6203,
e0236976,
10.1371/journal.pone.0236976
8.
Abdel-Hady El-Gilany,
COVID-19: The enigma of asymptomatic carriers and silent transmission,
2021,
10,
2278-344X,
11,
10.4103/ijhas.IJHAS_135_20
9.
Phongchai Jittamai, Natdanai Chanlawong, Wanyok Atisattapong, Wanwarat Anlamlert, Natthiya Buensanteai,
Reproduction number and sensitivity analysis of cassava mosaic disease spread for policy design,
2021,
18,
1551-0018,
5069,
10.3934/mbe.2021258
Martin Luther Mann Manyombe, Joseph Mbang, Jean Lubuma, Berge Tsanou. Global dynamics of a vaccination model for infectious diseases with asymptomatic carriers[J]. Mathematical Biosciences and Engineering, 2016, 13(4): 813-840. doi: 10.3934/mbe.2016019
Martin Luther Mann Manyombe, Joseph Mbang, Jean Lubuma, Berge Tsanou. Global dynamics of a vaccination model for infectious diseases with asymptomatic carriers[J]. Mathematical Biosciences and Engineering, 2016, 13(4): 813-840. doi: 10.3934/mbe.2016019
DownLoad: