Mathematical Model Formulation and Analysis for COVID-19 Transmission with Virus Transfer Media and Quarantine on Arrival

Mathematical Model Formulation and Analysis for COVID-19 Transmission with Virus Transfer Media and Quarantine on Arrival

An outbreak of severe acute respiratory syndrome (COVID-19) killed 287,355 with 4, 257,578 cases worldwide as of May 12, 2020. In this paper, we propose an SEQIsIaRM deterministic mathematical model which contains compartments for both human-to-human transmission and transmission through contaminate...

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Veröffentlicht in:Computational and mathematical methods 2022-09, Vol.2022, p.1-16
Hauptverfasser: Ega, Tesfaye Tadesse, Ngeleja, Rigobert Charles
Format: Artikel
Sprache:eng
Schlagworte:
COVID-19 vaccines
Developing countries
Disease transmission
Fatalities
Influenza
Intensive care
LDCs
Mathematical models
Middle East respiratory syndrome
Mortality
Pandemics
Parameter identification
Parameter sensitivity
Pneumonia
Proteins
Respiratory diseases
Severe acute respiratory syndrome
Severe acute respiratory syndrome coronavirus 2
Viral diseases
Viruses
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Ngeleja, Rigobert Charles
description An outbreak of severe acute respiratory syndrome (COVID-19) killed 287,355 with 4, 257,578 cases worldwide as of May 12, 2020. In this paper, we propose an SEQIsIaRM deterministic mathematical model which contains compartments for both human-to-human transmission and transmission through contaminated surfaces. Without intervention, the role of symptomatic and asymptomatic cases in humans is found to be very high in the transmission of the virus. Sensitive parameters which are associated with increased transmission of the COVID-19 virus were identified. According to the sensitivity results, the most sensitive parameters were disease-induced death rates of symptomatic and asymptomatic infectious people (σ), the rate of removal of virus from surfaces and environment (ν), and the rate of infection by asymptomatic infectious people (λ2) and symptomatic infectious people (λ1). The numerical results of our model confirm the sensitivity results that there are more new incidences of asymptomatic cases than symptomatic cases, which escalates the transmission of the virus in the community. Combined interventions like increasing both the rate of removal of viruses from surfaces and environment and decreasing the rate of infection in asymptomatic cases can play a significant role in reducing the average number of secondary infection (R0) to less than unity, causing COVID-19 to die out.
doi_str_mv 10.1155/2022/2955885
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subjects COVID-19 vaccines
Developing countries
Disease transmission
Fatalities
Influenza
Intensive care
LDCs
Mathematical models
Middle East respiratory syndrome
Mortality
Pandemics
Parameter identification
Parameter sensitivity
Pneumonia
Proteins
Respiratory diseases
Severe acute respiratory syndrome
Severe acute respiratory syndrome coronavirus 2
Viral diseases
Viruses
title Mathematical Model Formulation and Analysis for COVID-19 Transmission with Virus Transfer Media and Quarantine on Arrival
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