On the Parametrization of Epidemiologic Models-Lessons from Modelling COVID-19 Epidemic

• Published in: Viruses Vol. 14; no. 7; p. 1468
• Main Authors: Kheifetz, Yuri, Kirsten, Holger, Scholz, Markus
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 02.07.2022; MDPI
• Subjects: Age; Asymptomatic; Bayes Theorem; Bayesian analysis; Bayesian knowledge synthesis; COVID-19; COVID-19 - epidemiology; COVID-19 - prevention & control; COVID-19 epidemiologic models; Embedding; Epidemics; Epidemiology; extended multi-compartment SIR-type model; Forecasting; Humans; Immunization; Infections; Infectious diseases; input-output non-linear dynamical system; Intensive care; Mathematical models; Pandemics; Pandemics - prevention & control; Parameter estimation; parametrization; Patients; Pharmaceuticals; Prediction models; SARS-CoV-2; Severe acute respiratory syndrome coronavirus 2; Time series; Vaccination; Germany; COVID-19 epidemiologic models; extended multi-compartment SIR-type model; parametrization; input-output non-linear dynamical system; Bayesian knowledge synthesis
• ISSN: 1999-4915; 1999-4915
• DOI: 10.3390/v14071468

Numerous prediction models of SARS-CoV-2 pandemic were proposed in the past. Unknown parameters of these models are often estimated based on observational data. However, lag in case-reporting, changing testing policy or incompleteness of data lead to biased estimates. Moreover, parametrization is time-dependent due to changing age-structures, emerging virus variants, non-pharmaceutical interventions, and vaccination programs. To cover these aspects, we propose a principled approach to parametrize a SIR-type epidemiologic model by embedding it as a hidden layer into an input-output non-linear dynamical system (IO-NLDS). Observable data are coupled to hidden states of the model by appropriate data models considering possible biases of the data. This includes data issues such as known delays or biases in reporting. We estimate model parameters including their time-dependence by a Bayesian knowledge synthesis process considering parameter ranges derived from external studies as prior information. We applied this approach on a specific SIR-type model and data of Germany and Saxony demonstrating good prediction performances. Our approach can estimate and compare the relative effectiveness of non-pharmaceutical interventions and provide scenarios of the future course of the epidemic under specified conditions. It can be translated to other data sets, i.e., other countries and other SIR-type models.