Comprehensive Compartmental Model and Calibration Algorithm for the Study of Clinical Implications of the Population-Level Spread of COVID-19: A Study Protocol: Article No. e052681

Brandon Robinson, Jodi Edwards, Tetyana Kendzerska, Chris Pettit, Dominique Poirel, John Daly, Mehdi Ammi, Mohammad Khalil, Peter Taillon, Rimple Sandhu, Shirley Mills, Sunita Mulpuru, Thomas Walker, Valerie Percival, Victorita Dolean, Abhijit Sarkar

Research output: Contribution to journalArticlepeer-review

Abstract

The complex dynamics of the coronavirus disease 2019 (COVID-19) pandemic has made obtaining reliable long-term forecasts of the disease progression difficult. Simple mechanistic models with deterministic parameters are useful for short-term predictions but have ultimately been unsuccessful in extrapolating the trajectory of the pandemic because of unmodelled dynamics and the unrealistic level of certainty that is assumed in the predictions. We propose a 22-compartment epidemiological model that includes compartments not previously considered concurrently, to account for the effects of vaccination, asymptomatic individuals, inadequate access to hospital care, post-acute COVID-19 and recovery with long-term health complications. Additionally, new connections between compartments introduce new dynamics to the system and provide a framework to study the sensitivity of model outputs to several concurrent effects, including temporary immunity, vaccination rate and vaccine effectiveness. Subject to data availability for a given region, we discuss a means by which population demographics (age, comorbidity, socioeconomic status, sex and geographical location) and clinically relevant information (different variants, different vaccines) can be incorporated within the 22-compartment framework. Considering a probabilistic interpretation of the parameters allows the model's predictions to reflect the current state of uncertainty about the model parameters and model states. We propose the use of a sparse Bayesian learning algorithm for parameter calibration and model selection. This methodology considers a combination of prescribed parameter prior distributions for parameters that are known to be essential to the modelled dynamics and automatic relevance determination priors for parameters whose relevance is questionable. This is useful as it helps prevent overfitting the available epidemiological data when calibrating the parameters of the proposed model. Population-level administrative health data will serve as partial observations of the model states.
Original languageAmerican English
Number of pages8
JournalBMJ Open
Volume12
StatePublished - 2022

NREL Publication Number

  • NREL/JA-5000-79768

Keywords

  • Bayesian inference
  • COVID-19
  • sparse learning

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