Dynamics of a stochastic COVID-19 epidemic model with jump-diffusion

Tesfay, Almaz; Saeed, Tareq; Zeb, Anwar; Tesfay, Daniel; Khalaf, Anas D.; Brannan, James R.

doi:10.1186/s13662-021-03396-8

Cited by 22 publications

(9 citation statements)

References 37 publications

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“…In COVID-19 modeling, different types of models are used to understand SARS-CoV-2 transmission, such as deterministic models, stochastic models [18][19][20][21][22][23][24][25], agent-based models [26,27], discrete models [28,29], spatial models [30][31][32], network models [33,34], etc. COVID-19 stochastic models are sometimes compartmental models with the introduction of white noise, such as Gaussian noise or Brownian noise, to create randomness in order to find the condition of extinction and persistence on average of the disease and to prove the existence and uniqueness of the global positive solution of the model.…”

Section: Methodsmentioning

confidence: 99%

Analytical insights of the effects of Non-Pharmaceutical Interventions on SRAS-CoV-2 Dynamic with Application to West African Data

Traore,

Houenou,

Glèlè Kakaï

2023

Contemp. Math.

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The COVID-19 pandemic was caused by the rapid spread of a new coronavirus (SARS-CoV-2) worldwide. COVID-19 pandemic mitigation measures caused significant social and economic disruption, especially in regions with weak economic and fragile healthcare systems like West Africa. Therefore, accurate knowledge of the impact of these measures on its dynamics is important in decision-making. In this study, we formulated and used a deterministic compartmental model, considering two sub-classes of susceptible individuals (S1 and S2), where S1 is the population living around the epicenter of the epidemic and S2 is the population living far from the epicenter of the epidemic. The aim was to (i) theoretically assess the impact of measures reducing the transmission rate of the disease (ψ) on the epidemic dynamics and (ii) analyze the impact of measures reducing the probability of contact between infected and susceptible individuals (detection and isolation rates, θap, θs) on the epidemic dynamics. We determined the expressions of the basic and control reproduction numbers and studied the sensitivity and elasticity of the control reproduction number with respect to ψ, θap, θs, and heterogeneity factor, k(S1/S2). Application to the COVID-19 first-wave data from West Africa revealed that the basic reproduction number was 1.85. Moreover, the results indicated that a 50% reduction in the transmission rate of COVID-19 or the detection and isolation of 10% of infected individuals per day should help to reach the peak of the epidemic. Furthermore, a 100% increase in the heterogeneity factor induces a 16% increase in the control reproduction number when θap = 0.15 and a 14% increase in the control reproduction number when θap = 0.6. These conclusions could help design control measures to curtail future epidemics.

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Section: Methodsmentioning

confidence: 99%

Analytical insights of the effects of Non-Pharmaceutical Interventions on SRAS-CoV-2 Dynamic with Application to West African Data

Traore,

Houenou,

Glèlè Kakaï

2023

Contemp. Math.

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“…However, natural and massive phenomena such as Covid-19, earthquakes, tsunamis, and volcanoes cannot be modeled by the stochastic differential equation because these phenomena cause to break the continuity of the solution and provoke jumps in the system. Consequently, including a jump process (Lévy process [30,37,38]) in a stochastic system may well model these phenomena. This paper is aimed at studying the effect of environmental fluctuations on the model (1).…”

Section: Model Formulationmentioning

confidence: 99%

The Impact of Random Noise on the Dynamics of COVID-19 Epidemic Model

Koufi

Bennar

et al. 2022

Journal of Applied Mathematics

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At the end of 2019, the world knew the propagation of a new pandemic named COVID-19. This disease harmed the exercises of humankind and changed our way of life. For modeling and studying infectious illness transmission, mathematical models are helpful tools. Thus, in this paper, taking into account the effect of the intensity of the noises, we define a threshold value Π s of the model, which determines the extinction and persistence of the COVID-19 pandemic. We give numerical simulations to illustrate the analytical results.

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“…( 2021 ); Zhang and Alzahrani ( 2020 ); Tesfay et al. ( 2021 ) and with discrete delay in El-Metwally et al. ( 2021 ); Almutairi et al.…”

Section: Introductionmentioning

confidence: 99%

Modeling the stochastic within-host dynamics SARS-CoV-2 infection with discrete delay

2022

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In this paper, a new mathematical model that describes the dynamics of the within-host COVID-19 epidemic is formulated. We show the stochastic dynamics of Target-Latent-Infected-Virus free within the human body with discrete delay and noise. Positivity and uniqueness of the solutions are established. Our study shows the extinction and persistence of the disease inside the human body through the stability analysis of the disease-free equilibrium $$E_0$$ E 0 and the endemic equilibrium $$E^*$$ E ∗ , respectively. Moreover, we show the impact of delay tactics and noise on the extinction of the disease. The most interesting result is even if the deterministic system is inevitably pandemic at a specific point, extinction will become possible in the stochastic version of our model.

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Dynamics of a stochastic COVID-19 epidemic model with jump-diffusion

Cited by 22 publications

References 37 publications

Analytical insights of the effects of Non-Pharmaceutical Interventions on SRAS-CoV-2 Dynamic with Application to West African Data

Analytical insights of the effects of Non-Pharmaceutical Interventions on SRAS-CoV-2 Dynamic with Application to West African Data

The Impact of Random Noise on the Dynamics of COVID-19 Epidemic Model

Modeling the stochastic within-host dynamics SARS-CoV-2 infection with discrete delay

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