Acute and Chronic Exposure to Air Pollution in Relation with Incidence, Prevalence, Severity and Mortality of COVID-19: a Rapid Systematic Review

Overview

Journal Environ Health

Publisher Biomed Central

Specialty Environmental Health

Date 2021 Apr 11

PMID 33838685

Citations 32

Authors

Patrick D M C Katoto

Amanda S Brand

Buket Bakan

Paul Musa Obadia

Carsi Kuhangana

Tony Kayembe-Kitenge

Joseph Pyana Kitenge

Celestin Banza Lubaba Nkulu

Jeroen Vanoirbeek

Tim S Nawrot

Peter Hoet

Benoit Nemery

Affiliations

Soon will be listed here.

Abstract

Background: Air pollution is one of the world's leading mortality risk factors contributing to seven million deaths annually. COVID-19 pandemic has claimed about one million deaths in less than a year. However, it is unclear whether exposure to acute and chronic air pollution influences the COVID-19 epidemiologic curve.

Methods: We searched for relevant studies listed in six electronic databases between December 2019 and September 2020. We applied no language or publication status limits. Studies presented as original articles, studies that assessed risk, incidence, prevalence, or lethality of COVID-19 in relation with exposure to either short-term or long-term exposure to ambient air pollution were included. All patients regardless of age, sex and location diagnosed as having COVID-19 of any severity were taken into consideration. We synthesised results using harvest plots based on effect direction.

Results: Included studies were cross-sectional (n = 10), retrospective cohorts (n = 9), ecological (n = 6 of which two were time-series) and hypothesis (n = 1). Of these studies, 52 and 48% assessed the effect of short-term and long-term pollutant exposure, respectively and one evaluated both. Pollutants mostly studied were PM (64%), NO (50%), PM (43%) and O (29%) for acute effects and PM (85%), NO (39%) and O (23%) then PM (15%) for chronic effects. Most assessed COVID-19 outcomes were incidence and mortality rate. Acutely, pollutants independently associated with COVID-19 incidence and mortality were first PM then PM, NO and O (only for incident cases). Chronically, similar relationships were found for PM and NO. High overall risk of bias judgments (86 and 39% in short-term and long-term exposure studies, respectively) was predominantly due to a failure to adjust aggregated data for important confounders, and to a lesser extent because of a lack of comparative analysis.

Conclusion: The body of evidence indicates that both acute and chronic exposure to air pollution can affect COVID-19 epidemiology. The evidence is unclear for acute exposure due to a higher level of bias in existing studies as compared to moderate evidence with chronic exposure. Public health interventions that help minimize anthropogenic pollutant source and socio-economic injustice/disparities may reduce the planetary threat posed by both COVID-19 and air pollution pandemics.

Citing Articles

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Prepared for the polycrisis? The need for complexity science and systems thinking to address global and national evidence gaps.

Kwamie A, Causevic S, Tomson G, Sie A, Sauerborn R, Rasanathan K BMJ Glob Health. 2024; 9(9).

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Seasonal patterns of influenza incidence and the influence of meteorological and air pollution factors in Thailand during 2009-2019.

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Correlation between Exposure to UFP and ACE/ACE2 Pathway: Looking for Possible Involvement in COVID-19 Pandemic.

Botto L, Bulbarelli A, Lonati E, Cazzaniga E, Palestini P Toxics. 2024; 12(8).

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Exploring the association between ambient air pollution and COVID-19 risk: A comprehensive meta-analysis with meta-regression modelling.

Musonye H, He Y, Bekele M, Jiang L, Cao F, Xu Y Heliyon. 2024; 10(12):e32385.

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