Canada's Provincial COVID-19 Pandemic Modelling Efforts: A Review of Mathematical Models and Their Impacts on the Responses

Overview

Journal Can J Public Health

Publisher Springer Nature

Specialty Public Health

Date 2024 Jul 26

PMID 39060710

Authors

Yiqing Xia

Jorge Luis Flores Anato

Caroline Colijn

Naveed Janjua

Mike Irvine

Tyler Williamson

Marie B Varughese

Michael Li

Nathaniel Osgood

David J D Earn

Beate Sander

Lauren E Cipriano

Kumar Murty

Fanyu Xiu

Arnaud Godin

David Buckeridge

Amy Hurford

Sharmistha Mishra

Mathieu Maheu-Giroux

Affiliations

Soon will be listed here.

Abstract

Setting: Mathematical modelling played an important role in the public health response to COVID-19 in Canada. Variability in epidemic trajectories, modelling approaches, and data infrastructure across provinces provides a unique opportunity to understand the factors that shaped modelling strategies.

Intervention: Provinces implemented stringent pandemic interventions to mitigate SARS-CoV-2 transmission, considering evidence from epidemic models. This study aimed to summarize provincial COVID-19 modelling efforts. We identified modelling teams working with provincial decision-makers, through referrals and membership in Canadian modelling networks. Information on models, data sources, and knowledge translation were abstracted using standardized instruments.

Outcomes: We obtained information from six provinces. For provinces with sustained community transmission, initial modelling efforts focused on projecting epidemic trajectories and healthcare demands, and evaluating impacts of proposed interventions. In provinces with low community transmission, models emphasized quantifying importation risks. Most of the models were compartmental and deterministic, with projection horizons of a few weeks. Models were updated regularly or replaced by new ones, adapting to changing local epidemic dynamics, pathogen characteristics, vaccines, and requests from public health. Surveillance datasets for cases, hospitalizations and deaths, and serological studies were the main data sources for model calibration. Access to data for modelling and the structure for knowledge translation differed markedly between provinces.

Implication: Provincial modelling efforts during the COVID-19 pandemic were tailored to local contexts and modulated by available resources. Strengthening Canadian modelling capacity, developing and sustaining collaborations between modellers and governments, and ensuring earlier access to linked and timely surveillance data could help improve pandemic preparedness.

Citing Articles

Early COVID-19 Pandemic Preparedness: Informing Public Health Interventions and Hospital Capacity Planning Through Participatory Hybrid Simulation Modeling.

Tian Y, Basran J, McDonald W, Osgood N Int J Environ Res Public Health. 2025; 22(1).

PMID: 39857491 PMC: 11764793. DOI: 10.3390/ijerph22010039.

Mathematical modelling for pandemic preparedness in Canada: Learning from COVID-19.

Ogden N, Acheson E, Brown K, Champredon D, Colijn C, Diener A Can Commun Dis Rep. 2024; 50(10):345-356.

PMID: 39380801 PMC: 11460797. DOI: 10.14745/ccdr.v50i10a03.

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