Using a population-based Kalman estimator to model the COVID-19 epidemic in France: estimating associations between disease transmission and non-pharmaceutical interventions

• Published in: The international journal of biostatistics Vol. 20; no. 1; pp. 13 - 41
• Main Authors: Collin, Annabelle, Hejblum, Boris P., Vignals, Carole, Lehot, Laurent, Thiébaut, Rodolphe, Moireau, Philippe, Prague, Mélanie
• Format: Journal Article
• Language: English
• Published: Germany De Gruyter 30.05.2024; Walter de Gruyter GmbH
• Subjects: COVID-19; Disease transmission; epidemic modeling; Epidemics; Kalman filters; non-pharmaceutical interventions; population estimation; COVID-19; epidemic modeling; population estimation; Kalman filters; non-pharmaceutical interventions
• ISSN: 1557-4679; 2194-573X; 1557-4679
• DOI: 10.1515/ijb-2022-0087

In response to the COVID-19 pandemic caused by SARS-CoV-2, governments have adopted a wide range of non-pharmaceutical interventions (NPI). These include stringent measures such as strict lockdowns, closing schools, bars and restaurants, curfews, and barrier gestures such as mask-wearing and social distancing. Deciphering the effectiveness of each NPI is critical to responding to future waves and outbreaks. To this end, we first develop a dynamic model of the French COVID-19 epidemics over a one-year period. We rely on a global extended Susceptible-Infectious-Recovered (SIR) mechanistic model of infection that includes a dynamic transmission rate over time. Multilevel data across French regions are integrated using random effects on the parameters of the mechanistic model, boosting statistical power by multiplying integrated observation series. We estimate the parameters using a new population-based statistical approach based on a Kalman filter, used for the first time in analysing real-world data. We then fit the estimated time-varying transmission rate using a regression model that depends on the NPIs while accounting for vaccination coverage, the occurrence of variants of concern (VoC), and seasonal weather conditions. We show that all NPIs considered have an independent significant association with transmission rates. In addition, we show a strong association between weather conditions that reduces transmission in summer, and we also estimate increased transmissibility of VoC.