A six-compartment model for COVID-19 with transmission dynamics and public health strategies

The global crisis of the COVID-19 pandemic has highlighted the need for mathematical models to inform public health strategies. The present study introduces a novel six-compartment epidemiological model that uniquely incorporates a higher isolation rate for unreported symptomatic cases of COVID-19 c...

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Bibliographic Details
Published in:Scientific reports 2024-09, Vol.14 (1), p.22226-22, Article 22226
Main Authors: Ambalarajan, Venkatesh, Mallela, Ankamma Rao, Sivakumar, Vinoth, Dhandapani, Prasantha Bharathi, Leiva, VĂ­ctor, Martin-Barreiro, Carlos, Castro, Cecilia
Format: Article
Language:English
Subjects:
639/705/1041
639/705/794
692/699/255
Basic Reproduction Number
Cost analysis
Cost-Benefit Analysis
Cost-effectiveness analysis
COVID-19
COVID-19 - epidemiology
COVID-19 - transmission
Disease transmission
Emergent behavior
Epidemic models
Epidemiological Models
Epidemiology
Health promotion
Humanities and Social Sciences
Humans
India - epidemiology
Infectious diseases
Mathematical models
Model calibration
Models, Theoretical
multidisciplinary
Non-linear dynamics
Numerical simulation
Pandemics
Pandemics - prevention & control
Public Health
SARS-CoV-2 - isolation & purification
Science
Science (multidisciplinary)
Sensitivity analysis
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Description
Summary:The global crisis of the COVID-19 pandemic has highlighted the need for mathematical models to inform public health strategies. The present study introduces a novel six-compartment epidemiological model that uniquely incorporates a higher isolation rate for unreported symptomatic cases of COVID-19 compared to reported cases, aiming to enhance prediction accuracy and address the challenge of initial underreporting. Additionally, we employ optimal control theory to assess the cost-effectiveness of interventions and adapt these strategies to specific epidemiological scenarios, such as varying transmission rates and the presence of asymptomatic carriers. By applying this model to COVID-19 data from India (30 January 2020 to 24 November 2020), chosen to capture the initial outbreak and subsequent waves, we calculate a basic reproduction number of 2.147, indicating the high transmissibility of the virus during this period in India. A sensitivity analysis reveals the critical impact of detection rates and isolation measures on disease progression, showing the robustness of our model in estimating the basic reproduction number. Through optimal control simulations, we demonstrate that increasing isolation rates for unreported cases and enhancing detection reduces the spread of COVID-19. Furthermore, our cost-effectiveness analysis establishes that a combined strategy of isolation and treatment is both more effective and economically viable. This research offers novel insights into the efficacy of non-pharmaceutical interventions, providing a tool for strategizing public health interventions and advancing our understanding of infectious disease dynamics.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-024-72487-9