From Policy to Prediction: Forecasting COVID-19 Dynamics Under Imperfect Vaccination

• Published in: Bulletin of mathematical biology Vol. 84; no. 9; p. 90
• Main Authors: Wang, Xiunan, Wang, Hao, Ramazi, Pouria, Nah, Kyeongah, Lewis, Mark
• Format: Journal Article
• Language: English
• Published: New York Springer US 01.09.2022; Springer Nature B.V
• Subjects: Cell Biology; Coronaviruses; COVID-19; Covid-19 Publications; COVID-19 vaccines; Differential equations; Disease transmission; Forecasting; Immunization; Infectious diseases; Life Sciences; Machine learning; Mathematical and Computational Biology; Mathematical models; Mathematics; Mathematics and Statistics; Mobility; Original; Original Article; Pharmaceuticals; Policies; Public health; Vaccination; Generalized boosting machine learning model; COVID-19 modeling; Vaccination; Non-pharmaceutical interventions; Inverse method
• ISSN: 0092-8240; 1522-9602
• DOI: 10.1007/s11538-022-01047-x

Understanding the joint impact of vaccination and non-pharmaceutical interventions on COVID-19 development is important for making public health decisions that control the pandemic. Recently, we created a method in forecasting the daily number of confirmed cases of infectious diseases by combining a mechanistic ordinary differential equation (ODE) model for infectious classes and a generalized boosting machine learning model (GBM) for predicting how public health policies and mobility data affect the transmission rate in the ODE model (Wang et al. in Bull Math Biol 84:57, 2022). In this paper, we extend the method to the post-vaccination period, accordingly obtain a retrospective forecast of COVID-19 daily confirmed cases in the US, and identify the relative influence of the policies used as the predictor variables. In particular, our ODE model contains both partially and fully vaccinated compartments and accounts for the breakthrough cases, that is, vaccinated individuals can still get infected. Our results indicate that the inclusion of data on non-pharmaceutical interventions can significantly improve the accuracy of the predictions. With the use of policy data, the model predicts the number of daily infected cases up to 35 days in the future, with an average mean absolute percentage error of 20.15 % , which is further improved to 14.88 % if combined with human mobility data. Moreover, the most influential predictor variables are the policies of restrictions on gatherings, testing and school closing. The modeling approach used in this work can help policymakers design control measures as variant strains threaten public health in the future.