COVID-19: Data-Driven optimal allocation of ventilator supply under uncertainty and risk

•Multi-stage stochastic epidemics-ventilator-logistics compartmental model.•Optimize ventilator allocation under asymptomatic uncertainty and risk.•Epidemiological, population, migration, and cost data-driven model.•New region-based sub-problem and bounds improving optimality gap.•A general model th...

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Vydáno v:European journal of operational research Ročník 304; číslo 1; s. 255 - 275
Hlavní autoři: Yin, Xuecheng, Büyüktahtakın, İ. Esra, Patel, Bhumi P.
Médium: Journal Article
Jazyk:angličtina
Vydáno: Netherlands Elsevier B.V 01.01.2023
Témata:
COVID-19
Mean-CVaR multi-stage stochastic mixed-integer programming model
OR in health services
Pandemic resource and ventilator allocation
Risk-averse optimization
Pandemic resource and ventilator allocation
Mean-CVaR multi-stage stochastic mixed-integer programming model
COVID-19
Risk-averse optimization
OR in health services
ISSN:0377-2217, 1872-6860, 0377-2217
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Shrnutí:•Multi-stage stochastic epidemics-ventilator-logistics compartmental model.•Optimize ventilator allocation under asymptomatic uncertainty and risk.•Epidemiological, population, migration, and cost data-driven model.•New region-based sub-problem and bounds improving optimality gap.•A general model that could be extended to other infectious diseases. This study presents a new risk-averse multi-stage stochastic epidemics-ventilator-logistics compartmental model to address the resource allocation challenges of mitigating COVID-19. This epidemiological logistics model involves the uncertainty of untested asymptomatic infections and incorporates short-term human migration. Disease transmission is also forecasted through a new formulation of transmission rates that evolve over space and time with respect to various non-pharmaceutical interventions, such as wearing masks, social distancing, and lockdown. The proposed multi-stage stochastic model overviews different scenarios on the number of asymptomatic individuals while optimizing the distribution of resources, such as ventilators, to minimize the total expected number of newly infected and deceased people. The Conditional Value at Risk (CVaR) is also incorporated into the multi-stage mean-risk model to allow for a trade-off between the weighted expected loss due to the outbreak and the expected risks associated with experiencing disastrous pandemic scenarios. We apply our multi-stage mean-risk epidemics-ventilator-logistics model to the case of controlling COVID-19 in highly-impacted counties of New York and New Jersey. We calibrate, validate, and test our model using actual infection, population, and migration data. We also define a new region-based sub-problem and bounds on the problem and then show their computational benefits in terms of the optimality and relaxation gaps. The computational results indicate that short-term migration influences the transmission of the disease significantly. The optimal number of ventilators allocated to each region depends on various factors, including the number of initial infections, disease transmission rates, initial ICU capacity, the population of a geographical location, and the availability of ventilator supply. Our data-driven modeling framework can be adapted to study the disease transmission dynamics and logistics of other similar epidemics and pandemics.
Bibliografie:ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0377-2217
1872-6860
0377-2217
DOI:10.1016/j.ejor.2021.11.052