Author: Bertsimas, Dimitris; Digalakis Jr, Vassilis; Jacquillat, Alexander; Li, Michael Lingzhi; Previero, Alessandro
Title: Where to locate COVIDâ€19 mass vaccination facilities? Cord-id: 9bnnd2wu Document date: 2021_6_11
ID: 9bnnd2wu
Snippet: The outbreak of COVIDâ€19 led to a recordâ€breaking race to develop a vaccine. However, the limited vaccine capacity creates another massive challenge: how to distribute vaccines to mitigate the nearâ€end impact of the pandemic? In the United States in particular, the new Biden administration is launching mass vaccination sites across the country, raising the obvious question of where to locate these clinics to maximize the effectiveness of the vaccination campaign. This paper tackles this qu
Document: The outbreak of COVIDâ€19 led to a recordâ€breaking race to develop a vaccine. However, the limited vaccine capacity creates another massive challenge: how to distribute vaccines to mitigate the nearâ€end impact of the pandemic? In the United States in particular, the new Biden administration is launching mass vaccination sites across the country, raising the obvious question of where to locate these clinics to maximize the effectiveness of the vaccination campaign. This paper tackles this question with a novel dataâ€driven approach to optimize COVIDâ€19 vaccine distribution. We first augment a stateâ€ofâ€theâ€art epidemiological model, called DELPHI, to capture the effects of vaccinations and the variability in mortality rates across age groups. We then integrate this predictive model into a prescriptive model to optimize the location of vaccination sites and subsequent vaccine allocation. The model is formulated as a bilinear, nonconvex optimization model. To solve it, we propose a coordinate descent algorithm that iterates between optimizing vaccine distribution and simulating the dynamics of the pandemic. As compared to benchmarks based on demographic and epidemiological information, the proposed optimization approach increases the effectiveness of the vaccination campaign by an estimated 20%, saving an extra 4000 extra lives in the United States over a 3â€month period. The proposed solution achieves critical fairness objectives—by reducing the death toll of the pandemic in several states without hurting others—and is highly robust to uncertainties and forecast errors—by achieving similar benefits under a vast range of perturbations.
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