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Eliminate COVID-19? It’s Possible Based on New Mathematical Models

COVID-19, Pandemic, Infectious Diseases, Mathematical Models, Social Distancing, Economy, Economic Impacts, Human Behavior, Disease Elimination

Researchers are the first to introduce a novel mathematical framework to study the interplay between infectious diseases, human behavior – specifically social distancing – and economic growth.


By gisele galoustian | 10/13/2021

During the COVID-19 pandemic, governments around the world were faced with the trade-off between shutting down their economies to reduce the burden of the pandemic and the stress on healthcare systems or remaining open. Either way, each option relies on human response to respect or not to respect the chosen measure.

The impetus of a Florida Atlantic University study is to illuminate the impact of human behavior on controlling influenza-like illnesses with a focus on economic impact that uses an analytical and numerical perspective. , Ph.D., study author and an associate professor in the , FAU , and collaborators from the are the first to introduce a novel mathematical framework to study the interplay between infectious diseases, human behavior, and economic growth.

Their robust framework explores the interaction between infectious diseases that can be controlled using non-pharmaceutical interventions – specifically social distancing – and human response to this intervention and economic growth impacts. Many infectious disease models fail to account for the joint contributions of these three components, let alone considering all three components in a single framework.

For the study, published in the , researchers introduced two models: a coupled disease-human behavior (or disease-game theoretic) model to study the impact of full social distancing, and a coupled disease-human behavior model with an economic component to study the interplay between infectious diseases, human response to disease control measures, and the associated economic impact.

Results reveal that disease elimination might be possible. According to the first model, this is possible only if the entire population practices complete social distancing. The second model, however, highlights the role of the economy. If the economy is weaker than the social norms, then elimination of the disease is only possible if the entire population practices complete social distancing – a scenario that is probably not very realistic. However, if the economy is stronger than the social norms, then elimination is possible with some portion of the population practicing complete social distancing at the expense of the economy.

“The lack of economic perspective has been identified as a serious drawback of the multiple COVID-19 mathematical models that have emerged since the beginning of the pandemic,” said Tuncer.  “In fact, the question is so important that it has driven some preliminary studies with limited mathematical discussion, which is what inspired us to develop our models, which combine epidemiological, evolutionary game theory and socio-economic perspectives in a single framework.” 

The first model can have five different kinds of equilibria: a disease-free, social-distancing free equilibrium; a disease-free, full social-distancing equilibrium; and an intermediate level of full social distancing. The second model of social distancing with an economic compartment has 10 possible equilibria. The economic model, based on the neoclassical economic growth model, emphasizes structural relationships between different factors of production such as capital (e.g. equipment, infrastructure, education, health, among others), labor, and economic productivity. Specifically, the neoclassical growth model describes the change in capital with time according to the equation.

“Because this interdependence between disease and economic activities is not limited to COVID-19, our new models lead to new dynamics, new insights at the interface of disease-human behavior-economics, and new conclusions,” said Tuncer.

Study co-authors are Maia Martcheva, Ph.D., Department of Mathematics; and Calistus N. Ngonghala, Ph.D., Emerging Pathogens Institute, both at the University of Florida.

-FAU-