Showing total 30 results

1. Stability and bifurcation analysis of an infectious disease model with different optimal control strategies.

Author

Kumar, Arjun, Gupta, Ashvini, Dubey, Uma S., and Dubey, Balram

Subjects

*PONTRYAGIN'S minimum principle, *COMMUNICABLE diseases, *OPTIMAL control theory, *BASIC reproduction number, *MEDICAL model, *HEALTH facilities

Abstract

This paper deals with the non-linear Susceptible–Infected–Hospitalized–Recovered model with Holling type II incidence rate, treatment with saturated type functional response for the prevention and control of disease with limited healthcare facilities. The well-posedness of the model is ensured with the help of the non-negativity and boundedness of the solution of the system. The feasibility of the model with DFE (Disease-free equilibrium) and EE (endemic equilibrium) is analysed. The local and global stability are discussed with the help of the computed basic reproduction number R 0. At R 0 = 1 , we use the Centre manifold theory to analyse the transcritical bifurcation exhibited by the system. It is found that the disease is not eradicated even if R 0 < 1 due to the occurrence of backward bifurcation. The occurrence condition of Hopf bifurcation is obtained. The optimal control theory is used to analyse the effects of the minimum possible medical facilities, hospital beds, and awareness creation on the population dynamics. The Hamiltonian function is constructed with the extended optimal control model and solved by Pontryagin's maximum principle to get the minimum possible expenditure. Different types of control strategies are shown by numerical simulation. The sensitivity analysis is discussed with the help of a crucial parameter that depends on the reproduction number. Further, the model is simulated numerically to support the theoretical studies. This paper emphasizes the significance of treatment intensity, the total number of hospital bed available and their occupancy rate as vital parameters for prevention of disease prevalence. • A nonlinear model is proposed to study the spread and control of infectious diseases with limited healthcare facilities. • Due to backward bifurcation, R 0 < 1 is insufficient to eliminate the disease, and the system exhibits periodic oscillation due to the emergence of Hopf bifurcation. • Using Pontryagin's maximum principle, effects of the limited medical facilities, hospital beds, and awareness-building initiatives are examined to determine the minimum possible expenses. • Sensitivity analysis is used to determine the appropriate control parameter and cost-effectiveness analysis is used for finding most optimal strategy. [ABSTRACT FROM AUTHOR]

Published

2023

2. Bifurcation analysis and chaos for a double-strains HIV coinfection model with intracellular delays, saturated incidence and Logistic growth.

Author

Chen, Wei, Zhang, Long, Wang, Ning, and Teng, Zhidong

Subjects

*BASIC reproduction number, *MIXED infections, *HOPF bifurcations, *VIRAL load, *HIV infection transmission, *HIV

Abstract

In this paper, a class of virus-to-cell HIV model with intracellular delays, saturated incidence and Logistic growth is proposed to characterize the interaction between two types HIV strains, i.e., wild-type and drug-resistant strains. First, a series of threshold criteria on the locally and globally asymptotic stability of (infection-free, dominant, coexistence) equilibria are discussed based on the basic reproduction number R 0. Furthermore, a detailed Hopf bifurcation analysis is performed on the coexistence equilibrium using two delays as bifurcation parameters. We find that the Hopf bifurcations induced by double-strains are evidently different and more complicated than that of single strain, the former switches from stability (periodic branches) to un-stability (chaos) more frequently and earlier than the latter since double-strains would yield more pairs of imaginary roots in the characteristic equations. Meanwhile, the total viral load of double-strains would be higher than that of single-strain as well. The emergence of drug resistance imposes either negative or positive influences on the survival of wild-type strain, which would further facilitate the transmission of HIV. [ABSTRACT FROM AUTHOR]

Published

2024

3. Co-infection dynamics between HIV-HTLV-I disease with the effects of Cytotoxic T-lymphocytes, saturated incidence rate and study of optimal control.

Author

Chowdhury, Sourav, Ghosh, Jayanta Kumar, and Ghosh, Uttam

Subjects

*CYTOTOXIC T cells, *T cells, *VIRUS diseases, *MIXED infections, *BASIC reproduction number, *HIV infections

Abstract

The spreading of HIV or HTLV-I among the cells has received the great attention in recent modelling study to explore the virus infection dynamics. The co-infection of HIV and HTLV-I with the effect of Cytotoxic T-lymphocytes (CTLs) immune response is also important from epidemiological point of view. To identify the co-infection scenario of HIV and HTLV-I with the CTLs effect we proposed in this paper a six compartmental ODE-model with uninfected, HIV-infected, HTLV-I infected CD4+T cells and free HIV virus particles with HIV specific CTLs and HTLV-I specific CTLs. The rates of infection of the cases are considered here saturated type and proliferation rate of uninfected and HIV infected CD4+ T-cells are of logistic terms. To establish the well-posedness of the model we have shown that the solution of the proposed model is non-negative and bounded. We obtain the basic reproduction number which is the maximum of the HIV-related reproduction and the HTLV-I related reproduction number. Along with the disease free equilibrium point the system contains other seven endemic equilibrium points containing infection by single disease or both. Analytically, we establish the local and global stability conditions of the equilibrium points and also we establish that the system experiences transcritical bifurcation by the generation of only HIV or HTLV-I infected endemic equilibrium point. Using numerical simulations, we validate the theoretical results and found two infection paths, one initiating with HIV and other with HTLV-I, both cases ultimately become co-infected. Finally, using the optimal control analysis we found the optimal policy for treatment using AVR, RTI & PI for HIV or AZT for HTLV-I control and lastly concluded by some recommendations. • A co-infected HIV & HTLV-I infection model in vivo. • Proliferation of CD4+ T-cells are taken in logistic form. • Incidence rate is taken as saturated type. • Verified competitive exclusive principle. • Spreading path has been studied using Flow-diagram. • Three types of control strategies are investigated. [ABSTRACT FROM AUTHOR]

Published

2024

4. Role of ART and PrEP treatments in a stochastic HIV/AIDS epidemic model.

Author

Luo, Yantao, Huang, Jianhua, Teng, Zhidong, and Liu, Qun

Subjects

*BASIC reproduction number, *AIDS, *HIV, *PRE-exposure prophylaxis, *EPIDEMICS, *STOCHASTIC models

Abstract

In this paper, a stochastic HIV/AIDS epidemic model is presented to study the synthetic effect of ART (antiretroviral therapy) and PrEP (pre-exposure prophylaxis) treatments among MSM (men who have sex with men). Firstly, we give the global stability of disease-free equilibrium and the endemic equilibrium in terms of basic reproduction number R 0 for deterministic model. And then the existence of global positive solutions and the existence of unique ergodic stationary distribution under R 0 S > 1 for stochastic model are given. Further, the long-time stochastic dynamic of the model is investigated, including the criteria on the extinction and persistence in mean for the stochastic model. Finally, we give some numerical simulations to illustrate our theoretical results, and the sensitive analysis shows that ART (antiretroviral therapy) and PrEP (pre-exposure prophylaxis) treatments can effectively control the spread of AIDS among MSM population. [ABSTRACT FROM AUTHOR]

Published

2024

5. Mathematical analysis for an age-space structured HIV model with latency.

Author

Zhang, Lidong, Wang, Jinliang, and Zhang, Ran

Subjects

*MATHEMATICAL analysis, *BASIC reproduction number, *HIV

Abstract

This paper aims to study an HIV model with age structure and latently in a spatially homogeneous environment. By applying the fixed point theorem, we obtain the existence of the global solution and the global attractor for the model. We also identify the explicit formula of the basic reproduction number by the mean of the Laplace transformation, and confirm that this number predicts whether the infection occurs or not. Through analyzing the root distribution of the characteristic equation, the local stability of the equilibrium is obtained. By appealing to the appropriate Lyapunov functionals, we further study the global stability of the equilibrium. Numerical simulations also validate our theoretical results. [ABSTRACT FROM AUTHOR]

Published

2024

6. Dynamics and optimal control for a spatial heterogeneity model describing respiratory infectious diseases affected by air pollution.

Author

Zhou, Qi, Li, Xining, Hu, Jing, and Zhang, Qimin

Subjects

*BASIC reproduction number, *AIR pollution, *PONTRYAGIN'S minimum principle, *RESPIRATORY diseases, *HETEROGENEITY, *ENDEMIC diseases, *PHASE coding

Abstract

Air pollution has a serious impact on the spread of respiratory infectious diseases. However, the concentration of air pollution is not the same in different places. In order to characterize the spatial heterogeneity and the diffusion of pollutants, this paper proposes a spatial heterogeneity model, where the transmission rate is closely related to air pollution. The dynamics are established in terms of the basic reproduction number R 0 : if R 0 ≤ 1 , the disease-free equilibrium is globally asymptotically stable; if R 0 > 1 , there exists at least one endemic equilibrium and the disease is uniformly persistent. Our findings suggest that spatial heterogeneity, increased pollutants emission, and limited movement of infected individuals will all contribute to the spread of the respiratory infectious diseases. Subsequently, the corresponding strategies are introduced into the model to control the prevalence of the diseases. Under the minimization of the objective function, the necessary condition for the optimal control is acquired with the help of Pontryagin's maximum principle. Numerical simulations are applied to validate the theoretical results of threshold dynamics and to demonstrate the influences of inflow and clearance rates of pollutants on threshold dynamics and optimal control. [ABSTRACT FROM AUTHOR]

Published

2024

7. An optimal combination of antiretroviral treatment and immunotherapy for controlling HIV infection.

Author

Nath, Bhagya Jyoti, Sadri, Khadijeh, Sarmah, Hemanta Kumar, and Hosseini, Kamyar

Subjects

*ANTIRETROVIRAL agents, *HIV infections, *ANTI-HIV agents, *BASIC reproduction number, *IMMUNOTHERAPY

Abstract

Antiretroviral (ART) drugs have been used to treat HIV patients over last two decades. But, the daily use of these drugs in order to control HIV load in patients' body results different side effects and high cost over long period of time. Motivated by these, researchers have been trying to find other treatment strategy whose combination with antiretroviral treatments can control HIV without use of large quantities of drugs. Immunotherapy is one of such treatment which assist natural immune system of patients in order to get control over viral infection. Administration of immunotherapy in combination with antiretroviral drugs has been found safe and effective after different clinical trials on humans and other animals. In this paper, we propose a mathematical model to describe HIV dynamics under antiretroviral treatment and immunotherapy combination. We find that our model is biologically feasible and the findings of the clinical trials support the dynamics of our model. The stability analyses of HIV-free equilibrium point are performed and found the basic reproduction number as a threshold parameter. Also, we calculate a critical efficacy for overall antiretroviral treatment such that when the efficacy of overall treatment exceeds this value HIV will be completely removed. Also, we have found that critical drug efficacy for antiretroviral drugs decreases with increasing immunotherapy, which indicates combination of immunotherapy with antiretroviral treatments minimize the quantity of antiretroviral drugs for HIV eradication, hence minimize the side effects and cost of antiretroviral drugs. Numerical simulations are carried out to substantiate the analytical results and to illustrate different drug administration scenarios. Moreover, an optimal combination of drugs which can control HIV with lower costs and side effects, is obtained by solving an optimal control problem numerically. [ABSTRACT FROM AUTHOR]

Published

2024

8. A delayed deterministic and stochastic [formula omitted] model: Hopf bifurcation and stochastic analysis.

Author

Hajri, Youssra, Allali, Amina, and Amine, Saida

Subjects

*STOCHASTIC analysis, *HOPF bifurcations, *BASIC reproduction number, *WHITE noise, *STOCHASTIC models

Abstract

In this paper, we present a delayed deterministic and stochastic S I R I C V models to investigate the effects of the white noise intensities and the waning immunity of vaccinated individuals in the evolution of the disease. For the deterministic S I R I C V model, the basic reproduction number R 0 and the equilibrium points are calculated. The local stability of equilibrium points is analyzed. Particularly, when R 0 < 1 the disease-free equilibrium is locally stable for any positive value of τ. Furthermore, when R 0 > 1 , the local stability and sufficient conditions to ensure the occurrence of Hopf bifurcation for the endemic equilibrium point are established by considering the time delay τ as a bifurcation parameter. For the stochastic S I R I C V model, the conditions of the extinction and persistence of the disease are given by using the stochastic basic reproduction numbers R 0 s and R 0 s ∗. Numerical simulations are presented to enhance our analytical results and contrast the deterministic and stochastic models. [ABSTRACT FROM AUTHOR]

Published

2024

9. A reaction–diffusion epidemic model with virus mutation and media coverage: Theoretical analysis and numerical simulation.

Author

Tu, Yunbo and Meng, Xinzhu

Subjects

*VIRAL mutation, *BASIC reproduction number, *COVID-19 pandemic, *NUMERICAL analysis, *EPIDEMICS

Abstract

In this paper, a novel COVID-19 reaction–diffusion model with virus mutation and media coverage is investigated. First, the solution's uniform boundedness for the system is established. Then, the basic reproduction numbers for ordinary and mutant viruses spread in heterogeneous environments are defined. Furthermore, the endemic equilibrium's asymptotic distribution for the system is explored. In addition, when one diffusion coefficient tends to zero and the other diffusion coefficients are greater than zero and fixed, the solution of the system will asymptotically approach endemic equilibrium. Next, a theoretical analysis of how high-frequency media coverage affects the development of the COVID-19 epidemic is conducted. Theoretical research shows that high-frequency media coverage will lead to the disappearance of the disease. Meantime, global sensitivity analysis on the basic reproduction numbers R 01 and R 02 are performed. Finally, theoretical simulations and instance predictions are carried out. Because of the complexity of the Shanghai epidemic and changes in management and control, the infection rates β 1 (t) , β 2 (t) are given in the form of a piecewise function with more practical significance, and they are used to predict the epidemic trend of COVID-19 in Shanghai. Through a series of numerical simulations and analysis, the key indicators of the Shanghai COVID-19 epidemic are as follows : (1) The basic reproduction numbers in the early, middle, and late stages of COVID-19 are R ¯ 0 (1 : 34) = 0. 9152 , R ¯ 0 (35 : 49) = 3. 1476 , and R ¯ 0 (50 : 140) = 0. 6547 , respectively; (2) This epidemic round in Shanghai will peak at 3,270 new daily confirmed cases on the 49th day (April 15); (3) The final size of the epidemic will reach 63,470 confirmed cases; (4) This round of COVID-19 epidemic in Shanghai, China, is expected to be fully cleared in late June to early July. The above conclusions are basically consistent with the facts. Of course, with the rise in temperature and strict control, the epidemic situation in Shanghai, China, is expected to be cleared earlier. Our results provide new ideas for preventing and controlling the COVID-19 epidemic. • A reaction–diffusion model with virus mutation and media coverage is proposed. • The asymptotic properties of endemic equilibrium with small diffusion are explored. • Global sensitivity analysis for R 01 and R 02 and are performed. • Applying piecewise functions β 1 (t) , β 2 (t) , to predict the Shanghai COVID-19 epidemic. • Key indicators of COVID-19, such as R 0 , peak, final scale, clear time are obtained. [ABSTRACT FROM AUTHOR]

Published

2023

10. Threshold dynamics of an age-structured infectious disease model with limited medical resources.

Author

Yang, Jin, Chen, Zhuo, Tan, Yuanshun, Liu, Zijian, and Cheke, Robert A.

Subjects

*MEDICAL model, *COMMUNICABLE diseases, *BASIC reproduction number, *LYAPUNOV functions, *EQUILIBRIUM

Abstract

In this paper, an age-structured infectious disease dynamical model that considers two diseases simultaneously but with limited medical resources is proposed and analyzed. The asymptotic smoothness and persistence of the solution semi-flow are investigated. Then conditions for the existence of a global attractor are derived, which means that disease persists when ℜ 0 > 1. By using a Lyapunov function, it is shown that the infection-free equilibrium is globally asymptotically stable if ℜ 0 < 1 and the infection equilibrium is globally asymptotically stable if ℜ 0 > 1. In the presence of limited medical resources, the results suggest that equitable distribution for the limited medical resources is significant when treating low-risk and high-risk diseases and that keeping a resource sharing coefficient at a moderate level helps to eliminate the disease. • We proposed an age-structured infectious disease model with limited medical resources. • some important parameters were included in ℜ 0. • ℜ 0 determines the global stability of the equilibria. • Discussions of the effects of the parameters and biological significance were provided. [ABSTRACT FROM AUTHOR]

Published

2023

11. Mathematical analysis of an age-since infection and diffusion HIV/AIDS model with treatment adherence and Dirichlet boundary condition.

Author

Wu, Peng, Zhang, Ran, and Din, Anwarud

Subjects

*PATIENT compliance, *HIV infections, *BASIC reproduction number, *HIV infection transmission, *AIDS treatment, *MATHEMATICAL analysis, *ENDEMIC diseases

Abstract

In this paper, an epidemic model with homogeneous Dirichlet boundary condition is formulated to study the joint impact of spatial diffusion, infection age and treatment adherence on the HIV/AIDS transmission among humans. It is an interesting problem to understand the threshold dynamics of HIV/AIDS model with the above three factors. Since the complexity of the model and specificity of the boundary condition, there are two main mathematical challenges: i). the compactness of the solution map is not guaranteed; ii). the explicit expression of the basic reproduction cannot be given even if the parameters are spatially independent. We first discuss the well-posedness of the system, then we identify the basic reproduction number R 0 as the spectral radius of the next generation operator, followed by the global attractivity of disease-free steady state when R 0 < 1 , the uniform persistence of the disease and the existence of the endemic steady state when R 0 > 1. Numerical simulations are carried out to illustrate our theoretical results, which suggest that the diffusion of individuals has an opposite effect on the disease outbreaks, and improving the treatment compliance of HIV infected individuals can control HIV transmission among the population effectively. [ABSTRACT FROM AUTHOR]

Published

2023

12. A nonlinear mathematical model on the Covid-19 transmission pattern among diabetic and non-diabetic population.

Author

Anand, Monalisa, Danumjaya, P., and Rao, P. Raja Sekhara

Subjects

*BASIC reproduction number, *COVID-19, *MATHEMATICAL models, *DISEASE prevalence, *NUMBER systems

Abstract

In this paper, a three tier mathematical model describing the interactions between susceptible population, Covid-19 infected, diabetic population and Covid-19 infected, non diabetic population is proposed. Basic properties of such a dynamic model, namely, non negativity, boundedness of solutions, existence of disease-free and disease equilibria are studied and sufficient conditions are obtained. Basic reproduction number for the system is derived. Sufficient conditions on functionals and parameters of the system are obtained for the local as well as global stability of equilibria, thus, establishing the conditions for eventual prevalence of disease free or disease environment, as the case may be. The stability aspects are discussed in the context of basic reproduction number and vice versa. An important contribution of this article is that a novel technique is presented to estimate some key, influencing parameters of the system so that a pre-specified, assumed equilibrium state is approached eventually. This enables the society to prepare itself with the help of these key, influencing parameters so estimated. Several examples are provided to illustrate the results established and simulations are provided to visualize the examples. [ABSTRACT FROM AUTHOR]

Published

2023

13. Fractional-order deterministic epidemic model for the spread and control of HIV/AIDS with special reference to Mexico and India.

Author

Mangal, Shiv, Misra, O.P., and Dhar, Joydip

Subjects

*HIV, *AIDS, *BASIC reproduction number, *INFECTIOUS disease transmission, *EPIDEMICS, *IMMUNOLOGICAL deficiency syndromes

Abstract

This paper introduces a deterministic fractional-order epidemic model (FOEM) for studying the transmission dynamics of the human immunodeficiency virus (HIV) and acquired immunodeficiency syndrome (AIDS). The model highlights the substantial role of unaware and undetected HIV-infected individuals in spreading the disease. Control strategies, such as wielding condoms, level of preventive measures to avoid infection, and self-strictness of susceptibles in sexual contact, have been incorporated into the study. The basic reproduction number ℛ 0 α has been derived, which suggests the conditions for ensuring the persistence and elimination of the disease. Further, to validate the model, actual HIV data taken from Mexico and India separately have been used. The disease dynamics and its control in both countries are analyzed broadly. The values of biological parameters are estimated at which numerical solutions better match the actual data of HIV patients in the case of fractional-order (FO) instead of integer-order (IO). Moreover, in the light of ℛ 0 α , our findings forecast that the disease will abide in the population in Mexico, and at the same time, it will die out from India after a long time. [ABSTRACT FROM AUTHOR]

Published

2023

14. Disease dynamics and optimal control strategies of a two serotypes dengue model with co-infection.

Author

Saha, Pritam, Sikdar, Gopal Chandra, Ghosh, Jayanta Kumar, and Ghosh, Uttam

Subjects

*ARBOVIRUS diseases, *BASIC reproduction number, *MOSQUITO control, *PONTRYAGIN'S minimum principle, *DENGUE, *MIXED infections, *SEROTYPES, *STABILITY criterion

Abstract

This paper aims to explore stability and bifurcations with control analysis of a co-infected two serotypes dengue model in presence of three controls, namely protection control, treatment control and mosquito killing efforts. First we analyze the model incorporating with constant controls then find the control path considering variable control. We examine biological feasibility of the considered model along with existence and stability criteria of different equilibrium with respect to basic reproduction number. Stability of serotype-I, serotype-II free equilibrium and positive co-existence equilibrium are investigated. Center manifold theorem is used to prove the stability of the co-infected endemic equilibrium. The model experiences Transcritical bifurcation with respect to basic reproduction number. Sensitivity analysis has been employed to identify most influential model parameters to control the infection. The time dependent optimal control problem is solved analytically and numerically using Pontryagin's maximum principle. At last efficiency analysis has been carried out to find out more suitable control to combat the dengue disease. It is established from the analysis, protection control with treatment is more powerful than mosquito killing efforts by humans with treatment for controlling dengue. [ABSTRACT FROM AUTHOR]

Published

2023

15. Mathematical analysis of the impact of the media coverage in mitigating the outbreak of COVID-19.

Author

Koutou, Ousmane, Diabaté, Abou Bakari, and Sangaré, Boureima

Subjects

*COVID-19 pandemic, *BASIC reproduction number, *MATHEMATICAL analysis, *HERD immunity, *HOSPITAL patients

Abstract

In this paper, a mathematical model with a standard incidence rate is proposed to assess the role of media such as facebook, television, radio and tweeter in the mitigation of the outbreak of COVID-19. The basic reproduction number R 0 which is the threshold dynamics parameter between the disappearance and the persistence of the disease has been calculated. And, it is obvious to see that it varies directly to the number of hospitalized people, asymptomatic, symptomatic carriers and the impact of media coverage. The local and the global stabilities of the model have also been investigated by using the Routh–Hurwitz criterion and the Lyapunov's functional technique, respectively. Furthermore, we have performed a local sensitivity analysis to assess the impact of any variation in each one of the model parameter on the threshold R 0 and the course of the disease accordingly. We have also computed the approximative rate at which herd immunity will occur when any control measure is implemented. To finish, we have presented some numerical simulation results by using some available data from the literature to corroborate our theoretical findings. [ABSTRACT FROM AUTHOR]

Published

2023

16. Stochastic perturbation to 2-LTR dynamical model in HIV infected patients.

Author

Chinnadurai, M., Fatini, Mohamed El, and Rathinasamy, A.

Subjects

*STOCHASTIC models, *LYAPUNOV functions, *BASIC reproduction number

Abstract

In this paper, we proposed the stochastic perturbation to study the HIV viral dynamical model. The stochastic epidemic model of 2-LTR HIV infected patients is considered and we prove that the stochastic model admits a unique globally positive solution7 which is bounded and permanent. Then we analyze the necessary conditions for extinction and persistence of the disease by selecting the appropriate Lyapunov functions. The theoretical findings are confirmed by using suitable numerical experiments. [ABSTRACT FROM AUTHOR]

Published

2023

17. Numerical representations of global epidemic threshold for nonlinear infection-age SIR models.

Author

Cao, Shuxing, Chen, Zhijie, and Yang, Zhanwen

Subjects

*EULER method, *BASIC reproduction number, *ENDEMIC diseases, *ANALYTICAL solutions, *INFLUENZA

Abstract

In this paper, the global dynamical behavior of non-linear infection-age SIR models is investigated visually by numerical processes. Firstly, for an age-independent SIR model with diseased mortality and isolation rates, it has been shown that the linearly implicit Euler method reproduces the local dynamical behavior. For the study of the numerical global stability, numerical removed individuals are introduced and then the global behavior is represented by numerical processes for any stepsize. Generally, the numerical global behavior of the linearly implicit Euler method applied to non-linear infection-age SIR model is investigated. Using an infinite-dimensional Leslie operator, the disease-free equilibrium point is globally asymptotically stable for numerical processes when the numerical basic reproduction number of R h < 1. The numerical endemic disease equilibriums are globally asymptotically stable when the numerical threshold R h > 1. It is much more important that the global behavior of the analytical solutions is visually displayed by the numerical processes for the sufficiently small stepsize h. Finally, numerical applications to some the influenza models including HIV models and SIR models with protections are shown to illustrate our analysis. [ABSTRACT FROM AUTHOR]

Published

2023

18. Global threshold analysis on a diffusive host–pathogen model with hyperinfectivity and nonlinear incidence functions.

Author

Wang, Jinliang, Wu, Wenjing, and Kuniya, Toshikazu

Subjects

*BASIC reproduction number, *NONLINEAR functions, *GLOBAL analysis (Mathematics), *MATHEMATICAL analysis

Abstract

In this paper, we are concerned with the mathematical analysis of a host–pathogen model with diffusion, hyperinfectivity and nonlinear incidence. We define the basic reproduction number ℜ 0 by the spectral radius of the next generation operator, and study the relation between ℜ 0 and the principal eigenvalue of the problem linearized at the disease-free steady state (DFSS). Under some assumptions, we show the threshold property of ℜ 0 : if ℜ 0 < 1 , then the DFSS is globally asymptotically stable (GAS), whereas if ℜ 0 > 1 , then the system is uniformly persistent and a positive steady state (PSS) exists. Moreover, for the special case where all parameters are constants, we show that the PSS is GAS for ℜ 0 > 1. Numerical simulation suggests that the spatial heterogeneity could enhance the intensity of epidemic, whereas the diffusion effect could reduce it. [ABSTRACT FROM AUTHOR]

Published

2023

19. Analysis of SEIR epidemic patch model with nonlinear incidence rate, vaccination and quarantine strategies.

Author

Meng, Lan and Zhu, Wei

Subjects

*BASIC reproduction number, *EPIDEMICS, *INFECTIOUS disease transmission, *NONNEGATIVE matrices, *VACCINATION, *QUARANTINE

Abstract

In this paper, a susceptible–exposed–infectious–recovered (SEIR) epidemic patch model with nonlinear incidence rate, vaccination and quarantine strategies is presented. According to the properties of nonnegative matrices, the range of basic reproduction number is obtained. Moreover, the stability of disease-free equilibrium is studied. Some numerical simulations are given to validate the theoretical results. The effects of vaccination, quarantine strategies and population migration on disease transmission are also investigated by numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2022

20. Analysis of a degenerated reaction–diffusion cholera model with spatial heterogeneity and stabilized total humans.

Author

Wang, Jinliang, Wu, Wenjing, and Kuniya, Toshikazu

Subjects

*CHOLERA, *BASIC reproduction number, *LYAPUNOV functions, *HETEROGENEITY

Abstract

In this paper, we perform a complete analysis on a degenerated reaction–diffusion cholera model with stabilizing total humans and non-mobility of cholera bacteria in a spatially heterogeneous bounded domain. The existence of a global attractor is established through introducing the Kuratowski measure of non-compactness. The basic reproduction number and its equivalent characterizations have been used to analyze the threshold-type results, where the persistence and extinction of cholera can also be characterized by the dispersal rate of infected humans. In the homogeneous case, the global attractivity of the unique positive equilibrium is achieved by the Lyapunov function. Moreover, we compare the basic reproduction numbers for the models without and with considering the mobility of cholera bacteria. Our results suggest that: the basic reproduction numbers attain different values as the dispersal rates of infected humans and cholera approach to infinity, while they attain the same value as the dispersal rates of infected humans and cholera approach to zero. Numerical simulations support our analytical results and discuss the impact of the dispersal rate of infected humans on the transmission of cholera. [ABSTRACT FROM AUTHOR]

Published

2022

21. Maximal reproduction number estimation and identification of transmission rate from the first inflection point of new infectious cases waves: COVID-19 outbreak example.

Author

Waku, J., Oshinubi, K., and Demongeot, J.

Subjects

*COVID-19 pandemic, *BASIC reproduction number, *INFLECTION (Grammar), *EPIDEMICS

Abstract

The dynamics of COVID-19 pandemic varies across countries and it is important for​ researchers to study different kind of phenomena observed at different stages of the waves during the epidemic period. Our interest in this paper is not to model what happened during the endemic state but during the epidemic state. We proposed a continuous formulation of a unique maximum reproduction number estimate with an assumption that the epidemic curve is in form of the Gaussian curve and then compare the model with the discrete form and the observed basic reproduction number during the contagiousness period considered. Furthermore, we estimated the transmission rate from identification of the first inflection point of a wave of the curve of daily new infectious cases using the Bernoulli S–I (Susceptible–Infected) equation. We applied this new method to the real data from Cameroon COVID-19 outbreak both at national and regional levels. High correlation was observed between the socio-economic parameters and epidemiology parameters at regional level in Cameroon. Also, the method was applied to the second wave COVID-19 outbreak for the world data which is a period the phenomena we are considering were observed. Lastly, it was observed that the models presented results correspond with the epidemic dynamics in Cameroon and World data. We recommend that it is important to study what happened during the growth inflection point as some countries data did not climax. [ABSTRACT FROM AUTHOR]

Published

2022

22. Threshold dynamics and density function of a stochastic epidemic model with media coverage and mean-reverting Ornstein–Uhlenbeck process.

Author

Zhou, Baoquan, Jiang, Daqing, Han, Bingtao, and Hayat, Tasawar

Subjects

*ORNSTEIN-Uhlenbeck process, *STOCHASTIC models, *PROBABILITY density function, *INFECTIOUS disease transmission, *FOKKER-Planck equation, *BASIC reproduction number, *EPIDEMICS

Abstract

Infectious disease transmission, mainly affected by media coverage and stochastic perturbations, has imposed great social financial burden on the community in the past few decades and even threatened public health. However, there are few studies devoted to the theoretical dynamics of epidemic models with media coverage and biologically reasonable stochastic effect yet. In this sense, this paper mainly formulates and studies a stochastic epidemic model with media coverage and two mean-reverting Ornstein–Uhlenbeck processes. We first illustrate the biological implication and mathematically reasonable assumption of introducing the Ornstein–Uhlenbeck process as stochastic effect. It is theoretically proved that the solution to the stochastic model is unique and global, as well as the existence of an ergodic stationary distribution. After that, by solving the corresponding Fokker–Planck equation and using our developed algebraic equation theory, it is derived that the above global solution around the endemic equilibrium follows a unique probability density function. For completeness, the sufficient criteria for extinction exponentially of the model are established. Finally, several numerical simulations are provided to verify our theoretical results. Besides, the impact of stochastic noises and media coverage on epidemic transmission is studied by comparison with the previous results of a deterministic model. [ABSTRACT FROM AUTHOR]

Published

2022

23. Global stability analysis of viral infection model with logistic growth rate, general incidence function and cellular immunity.

Author

Gharahasanlou, Tohid Kasbi, Roomi, Vahid, and Hemmatzadeh, Zeynab

Subjects

*CELLULAR immunity, *GLOBAL analysis (Mathematics), *CELL physiology, *BASIC reproduction number, *VIRUS diseases

Abstract

It is well known that the mathematical biology and dynamical systems give very important information for the study and research of viral infection models such as HIV, HBV, HCV, Ebola and Influenza. This paper deals with the global dynamics of generalized virus model with logistic growth rate for target cells, general incidence rate and cellular immunity. The results will be obtained by using Lyapunov's second method and LaSalle's invariance principle. We prove the global stability of the rest points of the system by the value of basic reproduction number (R 0) and the immune response reproduction number (R CTL). We have found that if R 0 < 1 , then the infection-free equilibrium is globally asymptotically stable. For R 0 > 1 and R CTL < 1 , under certain conditions on incidence rate function, immune-free equilibrium is globally asymptotically stable. Finally, we prove that if R 0 > 1 and R CTL > 1 , then under certain conditions on incidence rate function the endemic equilibrium is globally asymptotically stable. Since the logistic growth rate for target cells and general incidence rate have been included in this manuscript, our obtained results are the generalization of those in the previous literatures. Moreover, the results have been obtained with weaker assumptions in comparison with the previous ones. Numerical simulations are presented to support and illustrate our analytical results. [ABSTRACT FROM AUTHOR]

Published

2022

24. Modelling and analysis of human–mosquito malaria transmission dynamics in Bangladesh.

Author

Kuddus, Md Abdul and Rahman, Azizur

Subjects

*BASIC reproduction number, *MALARIA, *INFECTIOUS disease transmission, *COMMUNICABLE diseases, *PLASMODIUM falciparum, *DEATH rate

Abstract

Malaria, a parasite based infectious disease spread by anopheles mosquitos, is widespread, affecting people of all ages. Malaria blood-borne pathogens cause approximately 110 million clinical cases of malaria and between one and two million deaths associated with Plasmodium falciparum each year worldwide, including Bangladesh. In this paper, we develop a human–mosquito transmission dynamics malaria model and analyse of the system properties and solutions. Both analytical and numerical results suggest that if the basic reproduction number R 0 < 1 , the disease-free equilibrium is asymptotically stable, meaning malaria naturally dies out. Further, if R 0 > 1 , the malaria disease persists in the population. We also provide the model calibration to estimate parameters with year-wise malaria incidence data from 2001 to 2014 in Bangladesh. Sensitivity analysis also performs to identify the most critical parameters through the partial rank correlation coefficient method. We found that the contact rate of both humans and mosquitoes had the most extensive influence on malaria prevalence. Finally, the impacts of progression rate, disease-related death rate, recovery rate and the rate of losing immunity are examined through numerical simulations and graphical analysis. [ABSTRACT FROM AUTHOR]

Published

2022

25. Stationary distribution and density function analysis of a stochastic epidemic HBV model.

Author

Ge, Junyan, Zuo, Wenjie, and Jiang, Daqing

Subjects

*HEPATITIS B virus, *DISTRIBUTION (Probability theory), *BASIC reproduction number, *PROBABILITY density function, *HEPATITIS B, *EPIDEMICS, *STOCHASTIC analysis

Abstract

In this paper, we present a stochastic hepatitis B virus (HBV) infection model and the dynamic behaviors of the model are investigated. When the fraction of vertical transmission μ ω ν C is not considered to be new infections, the existence and ergodicity of the stationary distribution of the model are obtained by constructing a suitable Lyapunov function, which determines a critical value ρ 0 s corresponding to the basic reproduction number of ODE system. This implies the persistence of the diseases when ρ 0 s > 1. Meanwhile, the sufficient conditions for the extinction of the diseases are derived when ρ 0 T < 0. What is more, we give the specific expression of the probability density function of the stochastic model around the unique endemic quasi-equilibrium by solving the Fokker–Planck equation. Finally, the numerical simulations are illustrated to verify the theoretical results and match the HBV epidemic data in China. • A stochastic HBV infection model is proposed and studied. • Existence and ergodicity of stationary distribution are proved. • Critical value ρ 0 s corresponding to basic reproduction number ρ 0 is obtained. • Density function of stochastic model near quasi-equilibrium is given. • Simulations match the HBV epidemic data in China. [ABSTRACT FROM AUTHOR]

Published

2022

26. A reaction–diffusion Susceptible–Vaccinated–Infected–Recovered model in a spatially heterogeneous environment with Dirichlet boundary condition.

Author

Wang, Jinliang, Zhang, Ran, and Kuniya, Toshikazu

Subjects

*BASIC reproduction number, *DISCRETIZATION methods

Abstract

In this paper, we study a Susceptible–Vaccinated–Infected–Recovered (SVIR) epidemic model in a spatially heterogeneous environment under the Dirichlet boundary condition. We define the basic reproduction number ℜ 0 by the spectral radius of the next generation operator, and show that it is a threshold parameter. The disease extinction and persistence in the case of a bounded domain are considered. More precisely, we show that the disease-free equilibrium is globally asymptotically stable if ℜ 0 < 1 ; the system is uniformly persistent and an endemic equilibrium exists if ℜ 0 > 1. To verify our theoretical results, we perform some numerical simulations, using the Fredholm discretization method to identify ℜ 0. [ABSTRACT FROM AUTHOR]

Published

2021

27. Effects of incubation and gestation periods in a prey–predator model with infection in prey.

Author

Basir, Fahad Al, Tiwari, Pankaj Kumar, and Samanta, Sudip

Subjects

*BASIC reproduction number, *PREGNANCY, *HOPF bifurcations, *PREDATION

Abstract

In this paper, we study a wide spectrum of dynamical features of a prey–predator model with infection in prey population only. In the model formulation, we consider nonlinear incidence for infection transmission and Holling type II as response function of predator. We analyze the model for local stability and Hopf bifurcation, and the theoretical results are validated and extrapolated by numerical simulations. Also, we perform sensitivity analysis to explore the significance of the crucial parameters influencing the densities of prey and predator populations. Our numerical results show that disease persists in the system even if the basic reproduction number is below unity. The rates of predation on susceptible and infected prey populations are shown to dramatically change the behavior of eco-epidemiological system. We extend our model by considering the fact that the newly infected prey becomes productively infectious after the effective contact between susceptible and infectious preys, and some time lag is involved in this biological process; also the conversion process conceals some time. We analyze our eco-epidemiological model with two time delays (incubation delay and predator's gestation delay) for stability and bifurcation. From numerical simulations, we observe that both the delay parameters substantially affect the stable configuration of the system. [ABSTRACT FROM AUTHOR]

Published

2021

28. Exploring the behavior of malware propagation on mobile wireless sensor networks: Stability and control analysis.

Author

Kumari, Sangeeta and Upadhyay, Ranjit Kumar

Subjects

*WIRELESS sensor networks, *MALWARE, *BASIC reproduction number, *SENSOR networks, *HOPF bifurcations

Abstract

This paper aims to explore the behavior of malware propagation on mobile wireless sensor networks (MWSNs). A new malware propagation model with nonlinear incidence rate and sigmoid type removal rate is established, and its global stability, spatiotemporal stability, and optimal control are analyzed. Specifically, the theoretical analysis shows that (i) a forward transcritical bifurcation occurs when the basic reproduction number R 0 > 1 ; (ii) time and space affect the spreading behavior of malware due to spatial distribution; (iii) the optimization technology can effectively control the malware spreading on MWSNs. Finally, some numerical simulations are performed to verify the obtained theoretical results, and the experimental results confirm that the generated patterns are consistent with the field observations of actual MWSNs. Our study helps in controlling the propagation of malware and applicable to design and prediction of the security and robustness of a sensor network. • A new malware propagation model with nonlinear incidence rate and sigmoid type removal rate is studied. • Global stability, spatiotemporal stability, and optimal control are analyzed. • Optimal control technique is employed to reduce the malware propagation. • Stability switching phenomena are obtained via Hopf bifurcation. • Spatio-temporal dynamics depends on transmission rate, time movement of nodes and its initial deployment. [ABSTRACT FROM AUTHOR]

Published

2021

29. Dynamic analysis of a fractional-order model for HIV with drug-resistance and CTL immune response.

Author

Shi, Ruiqing, Lu, Ting, and Wang, Cuihong

Subjects

*BASIC reproduction number, *IMMUNE response, *DRUG efficacy, *NUMBER systems

Abstract

In this paper, a fractional-order model for HIV with drug-resistance and CTL immune response is established. Two cases (subsystem with drug-sensitive and subsystem with drug-resistant) are considered. For both subsystems: firstly, the existence and uniqueness of the positive solution is proved; secondly, the sufficient conditions for the stability of the disease-free equilibrium are obtained; finally, some numerical simulations are performed to verify the theoretical results. After that, the main system is analyzed in a similar way. Calculation indicates that the basic reproduction number of the main system is the maximum value of the basic reproduction numbers of the corresponding subsystems. In addition, through numerical simulation, we know that the drug efficacy plays an important role in the treatment of HIV. • A fractional-order model for HIV with drug-resistance and CTL immune response is constructed. • The basic reproduction number of the main model is the maximum value of the corresponding two subsystems. • Through numerical simulations, the relationship of basic reproduction number with respect to fractional order was found. [ABSTRACT FROM AUTHOR]

Published

2021

30. Transmission dynamics, global stability and control strategies of a modified SIS epidemic model on complex networks with an infective medium.

Author

Xie, Yingkang and Wang, Zhen

Subjects

*INFECTIOUS disease transmission, *EPIDEMICS, *MATHEMATICAL analysis, *PROBABILITY theory, *PREVENTIVE medicine, *BASIC reproduction number

Abstract

In this paper, a new SIS (susceptible–infected–susceptible) epidemic model on complex networks with an infective medium is proposed. The infection rate is modified by applying the theory of probability. By using mean-field approximation, iterative analysis method and mathematical analysis, the epidemic threshold, stabilities of the disease-free equilibrium and the endemic equilibrium are studied. Moreover, some disease control strategies are proposed. The results show that the epidemic threshold plays an important role in the spread of disease. Finally, the theoretical results are confirmed by some simple numerical examples. [ABSTRACT FROM AUTHOR]

Published

2021