Sage Journals: Discover world-class research

Abstract

Despite advances in clinical care for the coronavirus (COVID-19) pandemic, population-wide interventions are vital to effectively manage the pandemic due to its rapid spread and the emergence of different variants. One of the most important interventions to control the spread of the disease is vaccination. In this study, an extended Susceptible-Infected Healed (SIR) model based on System Dynamics was designed, considering the factors affecting the rate of spread of the COVID-19 pandemic. The model predicts how long it will take to reach 70% herd immunity based on the number of vaccines administered. The designed simulation model is modeled in AnyLogic 8.7.2 program. The model was performed for three different vaccine supply scenarios and for Turkey with ~83 million population. The results show that, with a monthly supply of 15 million vaccines, social immunity reached the target value of 70% in 161 days, while this number was 117 days for 30 million vaccines and 98 days for 40 million vaccines.

Keywords

System Dynamics SIR models vaccine logistics simulation herd immunity

Get full access to this article

View all access options for this article.

References

Ciotti

Ciccozzi

Terrinoni

, et al. The COVID-19 pandemic. Crit Rev Clin Lab Sci 2020; 57: 365–388.

Majumder

Mandal

. Screening of plant-based natural compounds as a potential COVID-19 main protease inhibitor: an in silico docking and molecular dynamics simulation approach. J Biomol Struct Dyn 2022; 40: 696–711.

WHO Coronavirus (COVID-19) dashboard, 10 February 2022, https://covid19.who.int/

Prakash Tripathi

Tripath

. Adaptive nonlinear control scheme for containment of COVID-19 spread. Simulation 2022; 98: 729–736.

Sarkodie

Owusu

. Global assessment of environment, health and economic impact of the novel coronavirus (COVID-19). Env Dev Sust 2021; 23: 5005–5015.

Cutler

Summers

. The COVID-19 pandemic and the $16 trillion virus. JAMA 2020; 324: 1495–1496.

Zimmer

Corum

Wee

, et al. Coronavirus vaccine tracker, 10 June 2022, https://www.nytimes.com/interactive/2020/science/coronavirus-vaccine-tracker.html

Ganasegeran

Ch’ng

ASH

Looi

. What is the estimated covid-19 reproduction number and the proportion of the population that needs to be immunized to achieve herd immunity in Malaysia? A mathematical epidemiology synthesis. COVID 2021; 1: 3–19.

Fahrni

Ismail

IAN

Refi

, et al. Management of COVID-19 vaccines cold chain logistics: a scoping review. J Pharm Policy Pract 2022; 15: 1–14.

10.

Currie

Fowler

Kotiadis

, et al. How simulation modelling can help reduce the impact of COVID-19. J Sim 2020; 14: 83–97.

11.

Forrester

. Industrial dynamics. J Oper Res Soc 1997; 48: 1037–1041.

12.

Bernardo

Miguel

, et al. Policy development for pandemic response using system dynamics: a case study on COVID-19. Process Integr Optim Sustain 2020; 4: 497–501.

13.

Jia

Fang

. System dynamics analysis of COVID-19 prevention and control strategies. Environ Sci Pollut Res 2022; 29: 3944–3957.

14.

Allahi

Fateh

Revetria

, et al. The COVID-19 epidemic and evaluating the corresponding responses to crisis management in refugees: a system dynamic approach. J Humanit Logist Supply Chain Manag 2021; 11: 347–366.

15.

Abdolhamid

Pishvaee

Aalikhani

, et al. A system dynamics approach to COVID-19 pandemic control: a case study of Iran. Kybernetes 2021; 51: 2481–2507.

16.

Wang

Flessa

. Modelling Covid-19 under uncertainty: what can we expect? Eur J Health Econ 2020; 21: 665–668.

17.

Buckland

. The process development challenge for a new vaccine. Nat Med 2005; 11: 16–19.

18.

Edejer

TTT

Baltussen

Tan-Torres

, et al. Making choices in health: WHO guide to cost-effectiveness analysis. Geneva: World Health Organization, 2003.

19.

Calafiore

Novara

Possieri

. A modified SIR model for the COVID-19 contagion in Italy. In: 59th IEEE conference on decision and control, Jeju Island, Republic of Korea, 14–18 December 2020, pp. 3889–3894. New York: IEEE.

20.

Kudryashov

Chmykhov

Vigdorowitsch

. Analytical features of the SIR model and their applications to COVID-19. Appl Math Model 2021; 90: 466–473.

21.

Pornphol

Chittayasothorn

. System dynamics model of COVID-19 pandemic situation: the case of Phuket Thailand. In: Proceedings of the 12th international conference on computer modeling and simulation, Brisbane, QLD, Australia, 22–24 June 2020, pp. 77–81. https://doi.org/10.1145/3408066.3408086

22.

Estadilla

CDS

Uyheng

de Lara-Tuprio

, et al. Impact of vaccine supplies and delays on optimal control of the COVID-19 pandemic: mapping interventions for the Philippines. Infect Dis Poverty 2021; 10: 46–59.

23.

Peng

Sun

. SEIR modeling of the COVID-19 and its dynamics. Nonlinear Dyn 2020; 101: 1667–1680.

24.

Ching

San Juan

, et al. Systems dynamics modeling of pandemic influenza for strategic policy development: a simulation-based analysis of the COVID-19 case. Process Integr Optim Sustain 2021; 5: 461–474.

25.

Homer

Hirsch

. System dynamics modeling for public health: background and opportunities. Am J Public Health 2006; 96: 452–458.

26.

Feng

. Simulation analysis of the coronavirus disease 2019 (COVID-19) spread based on system dynamics model. In: IEEE international conference on systems, man, and cybernetics (SMC), Toronto, ON, Canada, 11–14 October 2020, pp. 498–501. New York: IEEE.

27.

Bush

Stright

Huggins

, et al. Simulation process and data flow for a large system dynamics model. Simulation 2022; 98: 823–833.

28.

Onggo

Kunc

, et al. Small Island Developing States (SIDS) COVID-19 post-pandemic tourism recovery: a system dynamics approach. Curr Issues Tour 2021; 25: 1481–1508.

29.

Bernardo

Miguel

, et al. Policy development for pandemic response using system dynamics: a case study on COVID-19. Process Integr Optim Sustain 2020; 4: 497–501.

30.

Box

GEP

. Science and statistics. J Am Stat Assoc 1976; 71: 791–799.

31.

Sargent

. Verification and validation of simulation models. In: Proceedings of the 2010 winter simulation conference, Baltimore, MD, 5–8 December 2010, pp. 166–183. New York: IEEE.

32.

Alam

Ahmed

Ali

, et al. Challenges to COVID-19 vaccine supply chain: implications for sustainable development goals. Int J Prod Econ 2021; 239: 108193.

33.

Brisson

Edmunds

. Economic evaluation of vaccination programs: the impact of herd-immunity. Med Decis Making 2003; 23: 76–82.

34.

Betsch

Böhm

Korn

, et al. On the benefits of explaining herd immunity in vaccine advocacy. Nat Hum Behav 2017; 1: 1–6.

35.

Velavan

Pollard

Kremsner

. Herd immunity and vaccination of children for COVID-19. Int J Infect Dis 2020; 98: 14–15.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.02 MB