Sage Journals: Discover world-class research

Abstract

Background

Policy makers are facing more complicated challenges to balance saving lives and economic development in the post-vaccination era during a pandemic. Epidemic simulation models and pandemic control methods are designed to tackle this problem. However, most of the existing approaches cannot be applied to real-world cases due to the lack of adaptability to new scenarios and micro representational ability (especially for system dynamics models), the huge computation demand, and the inefficient use of historical information.

Methods

We propose a novel Pandemic Control decision making framework via large-scale Agent-based modeling and deep Reinforcement learning (PaCAR) to search optimal control policies that can simultaneously minimize the spread of infection and the government restrictions. In the framework, we develop a new large-scale agent-based simulator with vaccine settings implemented to be calibrated and serve as a realistic environment for a city or a state. We also design a novel reinforcement learning architecture applicable to the pandemic control problem, with a reward carefully designed by the net monetary benefit framework and a sequence learning network to extract information from the sequential epidemiological observations, such as number of cases, vaccination, and so forth.

Results

Our approach outperforms the baselines designed by experts or adopted by real-world governments and is flexible in dealing with different variants, such as Alpha and Delta in COVID-19. PaCAR succeeds in controlling the pandemic with the lowest economic costs and relatively short epidemic duration and few cases. We further conduct extensive experiments to analyze the reasoning behind the resulting policy sequence and try to conclude this as an informative reference for policy makers in the post-vaccination era of COVID-19 and beyond.

Limitations

The modeling of economic costs, which are directly estimated by the level of government restrictions, is rather simple. This article mainly focuses on several specific control methods and single-wave pandemic control.

Conclusions

The proposed framework PaCAR can offer adaptive pandemic control recommendations on different variants and population sizes. Intelligent pandemic control empowered by artificial intelligence may help us make it through the current COVID-19 and other possible pandemics in the future with less cost both of lives and economy.

Highlights

We introduce a new efficient, large-scale agent-based epidemic simulator in our framework PaCAR, which can be applied to train reinforcement learning networks in a real-world scenario with a population of more than 10,000,000.

We develop a novel learning mechanism in PaCAR, which augments reinforcement learning with sequence learning, to learn the tradeoff policy decision of saving lives and economic development in the post-vaccination era.

We demonstrate that the policy learned by PaCAR outperforms different benchmark policies under various reality conditions during COVID-19.

We analyze the resulting policy given by PaCAR, and the lessons may shed light on better pandemic preparedness plans in the future.

Keywords

agent-based modeling artificial intelligence COVID-19 epidemic simulation health policy infectious disease nonpharmaceutical interventions pandemic control reinforcement learning SARS-CoV-2

Get full access to this article

View all access options for this article.

References

Pharmaceutical Technology. Covid-19 pandemic, declared by the World Health Organization (WHO). 2020. Available from: https://www.pharmaceutical-technology.com/news/who-declares-covid-19-pandemic

Kissler

Tedijanto

Goldstein

, et al. Projecting the transmission dynamics of SARS-CoV-2 through the postpandemic period. Science 2020;368(6493):860–8.

McCluskey

. Complete global stability for an SIR epidemic model with delay—distributed or discrete. Nonlinear Analysis: Real World Applications. 2010;11:55–9.

Muldowney

. Global stability for the SEIR model in epidemiology. Math Biosci. 1995;125:155–64.

Silva

Cruz

Torres

DFM

, et al. Optimal control of the COVID-19 pandemic: controlled sanitary deconfinement in Portugal. Sci Rep. 2021;11:3451.

Chinazzi

Davis

Ajelli

, et al. The effect of travel restrictions on the spread of the 2019 novel coronavirus (COVID-19) outbreak. Science. 2020;368:395–400.

Tian

Liu

, et al. An investigation of transmission control measures during the first 50 days of the COVID-19 epidemic in China. Science. 2020;368:638–42.

Rao

Vallon

Brandeau

. Effectiveness of face masks in reducing the spread of COVID-19: a model-based analysis. Med Decis Making. 2021;41:988–1003.

Aleta

Martín-Corral

Pastore

Piontti

, et al. Modelling the impact of testing, contact tracing and household quarantine on second waves of COVID-19. Nat Hum Behav. 2020;4:964–71.

10.

Larremore

Wilder

Lester

, et al. Test sensitivity is secondary to frequency and turnaround time for COVID-19 screening. Sci Adv. 2021;7:eabd5393.

11.

Guo

Tong

Chen

, et al. The suppression effect of emotional contagion in the COVID-19 pandemic: a multi-layer hybrid modelling and simulation approach. PLoS One. 2021;16:e0253579.

12.

Perez

Dragicevic

. An agent-based approach for modeling dynamics of contagious disease spread. Int J Health Geogr. 2009;8:50.

13.

Cuevas

. An agent-based model to evaluate the COVID-19 transmission risks in facilities. Comput Biol Med. 2020;121:103827.

14.

Kamal

. Computational Cost Analysis of Large-Scale Agent-Based Epidemic Simulations. Virginia Polytechnic Institute and State University; 2015.

15.

Zhang

. Large-Scale Agent-Based Social Simulation: A Study on Epidemic Prediction and Control. Delft University of Technology; 2016.

16.

Agrawal

Bhandari

Bhattacharjee

, et al. City-scale agent-based simulators for the study of non-pharmaceutical interventions in the context of the COVID-19 epidemic: IISc-TIFR COVID-19 city-scale simulation team. J Indian Inst Sci. 2020;100:809–47.

17.

Chen

Vullikanti

Hoops

, et al. Medical costs of keeping the US economy open during COVID-19. Sci Rep. 2020;10:18422.

18.

Lee

Zabinsky

Wasserheit

, et al. COVID-19 Pandemic response simulation in a large city: impact of nonpharmaceutical interventions on reopening society. Med Decis Making. 2021;41:419–29.

19.

Mnih

Kavukcuoglu

Silver

, et al. Human-level control through deep reinforcement learning. Nature. 2015;518:529–33.

20.

Arango

Pelov

. COVID-19 pandemic cyclic lockdown optimization using reinforcement learning. arXiv pre-print.arXiv:200904647;2020.

21.

Kwak

Ling

Hui

. Deep reinforcement learning approaches for global public health strategies for COVID-19 pandemic. PLoS One. 2021;16:e0251550.

22.

Uddin

Ali Shah

Al-Khasawneh

, et al. Optimal policy learning for COVID-19 prevention using reinforcement learning. J Inform Sci. 2022;48(3):336–48.

23.

Wan

Zhang

Song

. Multi-objective model-based reinforcement learning for infectious disease control. In: Proceedings of the 27th ACM SIGKDD Conference on Knowledge Discovery & Data Mining; August 14–18, 2021; Virtual Event, Singapore.

24.

Song

Zong

, et al. Reinforced epidemic control: saving both lives and economy. arXiv preprint. arXiv:2008.01257;2020.

25.

Kompella

Capobianco

Jong

, et al. Reinforcement learning for optimization of COVID-19 mitigation policies. arXiv preprint. arXiv:201010560;2020.

26.

Vaswani

Shazeer

Parmar

, et al. Attention is all you need. In: Proceedings of the 31st International Conference on Neural Information Processing Systems; December 2017; Long Beach, CA.

27.

Devlin

Chang

M-W

Lee

, et al. BERT: pre-training of deep bidirectional transformers for language understanding. arXiv preprint. arXiv:181004805;2018.

28.

Guo

. SSAN: separable self-attention network for video representation learning. In: Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR); June 19–25, 2021; Virtual Event.

29.

Chen

Rajeswaran

, et al. Decision transformer: reinforcement learning via sequence modeling. arXiv preprint. arXiv:210601345;2021.

30.

Ohi

Mridha

Monowar

, et al. Exploring optimal control of epidemic spread using reinforcement learning. Sci Rep. 2020;10:22106.

31.

Riccardi

Gemignani

Fernández-Navarro

, et al. Optimisation of non-pharmaceutical measures in COVID-19 growth via neural networks. IEEE Trans Emerg Topics Comput Intell. 2021;5:79–91.

32.

Zaki

Mohamed

. The estimations of the COVID-19 incubation period: a scoping review of the literature. J Infect Public Health. 2021;14:638–46.

33.

Chao

Halloran

Obenchain

, et al. FluTE, a publicly available stochastic influenza epidemic simulation model. PLoS Comput Biol. 2010;6:e1000656.

34.

Haug

Geyrhofer

Londei

, et al. Ranking the effectiveness of worldwide COVID-19 government interventions. Nat Hum Behav. 2020;4:1303–12.

35.

Cipriano

Goldhaber-Fiebert

Liu

, et al. Optimal information collection policies in a Markov decision process framework. Med Decis Making. 2018;38:797–809.

36.

Yaesoubi

Havumaki

Chitwood

, et al. Adaptive policies to balance health benefits and economic costs of physical distancing interventions during the COVID-19 pandemic. Med Decis Making. 2021;41:386–92.

37.

Yaesoubi

Cohen

. Identifying cost-effective dynamic policies to control epidemics. Stat Med. 2016;35:5189–209.

38.

Maharaj

Kleczkowski

. Controlling epidemic spread by social distancing: do it well or not at all. BMC Public Health. 2012;12:679.

39.

Stinnett

Mullahy

. Net health benefits: a new framework for the analysis of uncertainty in cost-effectiveness analysis. Med Decis Making. 1998;18(2 suppl):S68–80.

40.

Zhou

Zhang

Peng

, et al. Informer: beyond efficient transformer for long sequence time-series forecasting. In: Proceedings of the AAAI Conference on Artificial Intelligence; February 2–9, 2021; Palo Alto, CA.

41.

USAFacts. King County, Washington coronavirus cases and deaths. 2021. Available from: https://usafacts.org/visualizations/coronavirus-covid-19-spread-map/

42.

Washington State Department of Health. COVID-19 Data Dashboard. 2021. Available from: https://www.doh.wa.gov/Emergencies/COVID19/DataDashboard

43.

Beijing Municipal Health Commission. Beijing Municipal Health Commission. 2021. Available from: http://wjw.beijing.gov.cn/wjwh/ztzl/xxgzbd/gzbdyqtb/index.html

44.

Beijing Municipal Health Commission. Data on COVID-19 vaccinations in Beijing. 2021. Available from: http://bj.bendibao.com/news/202133/289104.shtm

45.

U.S. Census Bureau. U.S. Census Bureau QuickFacts: King County, Washington. 2021. Available from: https://www.census.gov/quickfacts/kingcountywashington

46.

Beijing Municipal Bureau Statistics. Beijing statistical yearbook 2020. 2020. Available from:http://nj.tjj.beijing.gov.cn/nj/main/2020-tjnj/zk/indexch.htm

47.

Information Office of Beijing Municipality. The level of emergency response to public health emergencies in Beijing has been downgraded to level 2. 2021. Available from: http://www.xinhuanet.com/politics/2020-04/29/c_1125924570.htm

48.

The Public Health Agency of Sweden. Communicable Disease Control. 2021. Available from: http://www.folkhalsomyndigheten.se/the-public-health-agency-of-sweden/communicable-disease-control/

49.

Burki

. Lifting of COVID-19 restrictions in the UK and the Delta variant. Lancet Respir Med. 2021;9(8):e85.

50.

Lopez Bernal

Andrews

Gower

, et al. Effectiveness of Covid-19 vaccines against the B.1.617.2 (Delta) variant. N Engl J Med. 2021;385:585–94.

51.

Shapiro

Dean

Madewell

, et al. Efficacy estimates for various COVID-19 vaccines: what we know from the literature and reports. 2021. Available from: https://www.medrxiv.org/content/10.1101/2021.05.20.21257461v1

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

1.72 MB

PaCAR: COVID-19 Pandemic Control Decision Making via Large-Scale Agent-Based Modeling and Deep Reinforcement Learning

Abstract

Background

Methods

Results

Limitations

Conclusions

Highlights

Keywords

Get full access to this article

References

Supplementary Material