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International Journal of Computer Mathematics Volume 87, 2010 - Issue 10
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Section B

Effect of cross-immunity on the transmission dynamics of two strains of dengue

S. M. Garba Department of Mathematics, University of Manitoba, Winnipeg, Manitoba, Canada; Department of Mathematics, Universiti Putra Malaysia, Serdang, Selangor, MalaysiaView further author information
&
A. B. Gumel Department of Mathematics, University of Manitoba, Winnipeg, Manitoba, CanadaCorrespondence[email protected]
Pages 2361-2384 | Received 11 Sep 2008, Accepted 05 Nov 2008, Published online: 25 May 2010

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Li-Ming Cai, Maia Martcheva & Xue-Zhi Li. (2013) Competitive exclusion in a vector–host epidemic model with distributed delay†. Journal of Biological Dynamics 7:sup1, pages 47-67.
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Articles from other publishers (27)

P. Muthu & Bikash Modak. (2023) Stochastic SIV in-host model of dengue virus transmission. International Journal of Dynamics and Control 12:4, pages 1003-1016.
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Pritam Saha, Gopal Chandra Sikdar, Jayanta Kumar Ghosh & Uttam Ghosh. (2023) Disease dynamics and optimal control strategies of a two serotypes dengue model with co-infection. Mathematics and Computers in Simulation 209, pages 16-43.
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Poosan Muthu & Bikash Modak. (2023) Within-host models of dengue virus transmission with immune response. Computational and Mathematical Biophysics 11:1.
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Salman Safdar & Abba B. Gumel. 2023. Mathematics of Public Health. Mathematics of Public Health 243 294 .
Ting Cui & Peijiang Liu. (2022) Fractional transmission analysis of two strains of influenza dynamics. Results in Physics 40, pages 105843.
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U. B. Odionyenma, A. Omame, N. O. Ukanwoke & I. Nometa. (2021) Optimal control of Chlamydia model with vaccination. International Journal of Dynamics and Control 10:1, pages 332-348.
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Mudassar Imran, Muhammad Usman, Muhammad Dur-e-Ahmad & Adnan Khan. (2017) Transmission Dynamics of Zika Fever: A SEIR Based Model. Differential Equations and Dynamical Systems 29:3, pages 463-486.
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Wasfi Shatanawi, Ali Raza, Muhammad Shoaib Arif, Muhammad Rafiq, Mairaj Bibi & MuhammadMohsin. (2021) Essential Features Preserving Dynamics of Stochastic Dengue Model. Computer Modeling in Engineering & Sciences 126:1, pages 201-215.
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Jayanta Kumar Ghosh, Uttam Ghosh & Susmita Sarkar. (2020) Qualitative Analysis and Optimal Control of a Two-Strain Dengue Model with its Co-infections. International Journal of Applied and Computational Mathematics 6:6.
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Salisu M. Garba & Usman A. Danbaba. (2020) Modeling the effect of temperature variability on malaria control strategies. Mathematical Modelling of Natural Phenomena 15, pages 65.
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Xue-Zhi Li, Junyuan Yang & Maia MartchevaXue-Zhi Li, Junyuan Yang & Maia Martcheva. 2020. Age Structured Epidemic Modeling. Age Structured Epidemic Modeling 211 257 .
Usman A. Danbaba & Salisu M. Garba. (2018) Modeling the transmission dynamics of Zika with sterile insect technique. Mathematical Methods in the Applied Sciences 41:18, pages 8871-8896.
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Mudassar Imran, Muhammad Usman, Tufail Malik & Ali R. Ansari. (2018) Mathematical analysis of the role of hospitalization/isolation in controlling the spread of Zika fever. Virus Research 255, pages 95-104.
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E. Iboi, K. Okuneye, O. Sharomi & A. B. Gumel. (2018) Comments on “A Mathematical Study to Control Visceral Leishmaniasis: An Application to South Sudan”. Bulletin of Mathematical Biology 80:4, pages 825-839.
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Yi Jing, Xia Wang, Sanyi Tang & Jianhong Wu. (2017) Data informed analysis of 2014 dengue fever outbreak in Guangzhou: Impact of multiple environmental factors and vector control. Journal of Theoretical Biology 416, pages 161-179.
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Yanxia Dang, Zhipeng Qiu & Xuezhi Li. (2017) Competitive exclusion in an infection-age structured vector-host epidemic model. Mathematical Biosciences and Engineering 14:4, pages 901-931.
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Folashade B. Agusto, Shamise Easley, Kenneth Freeman & Madison Thomas. (2016) Mathematical Model of Three Age-Structured Transmission Dynamics of Chikungunya Virus. Computational and Mathematical Methods in Medicine 2016, pages 1-31.
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D. Okuonghae, A.B. Gumel & M.A. Safi. (2015) Dynamics of a two-strain vaccination model for polio. Nonlinear Analysis: Real World Applications 25, pages 167-189.
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F. B. Agusto, J. Cook, P. D. Shelton & M. G. Wickers. (2015) Mathematical Model of MDR-TB and XDR-TB with Isolation and Lost to Follow-Up. Abstract and Applied Analysis 2015, pages 1-21.
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Adnan Khan, Muhammad Hassan & Mudassar Imran. (2014) Estimating the basic reproduction number for single-strain dengue fever epidemics. Infectious Diseases of Poverty 3:1.
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D. H. BARMAK, C. O. DORSO, M. OTERO & H. G. SOLARI. (2013) Modelling interventions during a dengue outbreak. Epidemiology and Infection 142:3, pages 545-561.
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Sutawas Janreung & Wirawan Chinviriyasit. (2014) Dengue Fever with Two Strains in Thailand. International Journal of Applied Physics and Mathematics 4:1, pages 55-61.
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Salisu M. GARBA & Mohammad A. SAFI. (2013) Mathematical Analysis of West Nile Virus Model with Discrete Delays. Acta Mathematica Scientia 33:5, pages 1439-1462.
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S.M. Garba, M.A. Safi & A.B. Gumel. (2013) Cross-immunity-induced backward bifurcation for a model of transmission dynamics of two strains of influenza. Nonlinear Analysis: Real World Applications 14:3, pages 1384-1403.
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F.B. Agusto & A.B. Gumel. (2013) Qualitative dynamics of lowly- and highly-pathogenic avian influenza strains. Mathematical Biosciences 243:2, pages 147-162.
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Adnan Khan, Muhammad Hassan & Mudassar Imran. (2013) The Effects of a Backward Bifurcation on a Continuous Time Markov Chain Model for the Transmission Dynamics of Single Strain Dengue Virus. Applied Mathematics 04:04, pages 663-674.
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. (2012) A mathematical model for within-host <em>Toxoplasma gondii</em> invasion dynamics. Mathematical Biosciences and Engineering 9:3, pages 647-662.
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