RI-MUHC researchers demonstrate that exposure to relatively low levels of air pollution in Canada is associated with lower lung function and COPD.
Montreal, May 26, 2022 – Long-term exposure to air pollution is linked to an increased prevalence of chronic obstructive pulmonary disease (COPD), which lowers lung function and makes breathing difficult for over 2 million people in Canada, and hundreds of millions worldwide. While most studies have looked at areas with high levels of pollution, a collaborative Canadian research network led by scientists from the Research Institute of the McGill University Health Centre (RI-MUHC) decided to examine the situation in Canada. According to their research work, even exposure to low concentrations of outdoor air pollution is associated with lower lung function in adults, i.e. the ability of the lungs to exchange oxygen and carbon dioxide through breathing. Their findings also show that individuals with dysanaptic lungs – a developmental mismatch between airway and lung size – could be more susceptible to the long-term effects of air pollution on lung function and COPD. Published in the American Journal of Respiratory and Critical Care Medicine, their study is the first to scrutinize these associations in the Canadian population.
“Few studies have examined the relationship between air pollution and the lung health of adults in areas where air pollution concentrations are low, such as in Canada,” says Dr. Jean Bourbeau senior scientist in the Translational Research in Respiratory Diseases Program (RESP) at the RI-MUHC, professor in the Department of Medicine at McGill University and senior author on this publication. “Our study shows that even in this setting, long-term exposure to outdoor air pollution has significant negative impacts on lung function. We saw that small increases in fine particulate matter and nitrogen dioxide air pollution led to clinically relevant decreases in lung function.”
Lung structure, air pollution and COPD
The team of researchers did not stop at examining how air pollution affects lung health in the Canadian population. They also assessed how an individual’s susceptibility to lung problems may be impacted by the structure of their lungs. They found that individuals with smaller airways had lower lung function and were 87 per cent more likely to develop COPD compared to people with larger airways with similar exposure to air pollution.
“For the first time, common differences in lung structure that arise early in life were shown to increase susceptibility to the harmful effects of air pollution later in life,” says study author Dany Doiron, PhD, a Research Associate at the RI-MUHC.
“Our results suggest that a relatively important proportion of the Canadian population is particularly susceptible to inhaled air pollutants,” adds co-author of the study Dr. Benjamin Smith, a scientist in the Translational Research in Respiratory Diseases Program (RESP) at the RI-MUHC and an associate professor in the Department of Medicine at McGill University. “While exposure to air pollution during childhood has been shown to adversely affect lung function and lung development, our study suggests that early-life lung development could in turn play a key role in protecting from, or increasing susceptibility to, air pollution-induced reductions in lung function and COPD in adulthood.”
Understanding risk factors for COPD
Chronic obstructive pulmonary disease (COPD) is a major cause of hospitalizations in Canada and a leading cause of death. It is characterized by an inflammation and partial blockage of the airways in the lungs, making breathing difficult.
While tobacco smoke is the best-known risk factor for COPD, up to half of COPD cases worldwide are due to non-tobacco-related risk factors including occupational exposures, infectious diseases, early life events and air pollution, notably, fine particulate matter and nitrogen dioxide. Fine particulate matter is made up of small inhalable particles thirty times smaller than the width of a human hair, and it can travel deep into the respiratory tract. Key sources for fine particulate matter are industrial emissions, wildfire smoke, residential wood heating, cooking, agriculture and vehicle traffic. Nitrogen dioxide is a result of fossil fuel burning and an indicator of traffic-related air pollution. In September 2021, considering the damage air pollution inflicts on human health, the World Health Organization released new air quality guidelines, recommending significant reductions in these two kinds of pollutants.
Other recent studies have also shown that smaller airways relative to lung size are another major risk factor for COPD, even among individuals who have never smoked. However, until now, the interaction between air pollution and this condition called dysanapsis was unknown.
A cross-sectional study based on the CanCOLD study data
To perform their analysis, the study team used health data from the Canadian Cohort of Obstructive Lung Disease (CanCOLD) study co-lead by Dr. Bourbeau at the RI-MUHC and McGill University, and Dr. Wan-Cheng Tan at the University of British Columbia. CanCOLD includes 1,500 individuals aged 40 years and older from nine different Canadian cities. Ambient air pollution data was provided by the Canadian Urban Environmental Health Research Consortium (CANUE).
To measure lung function, participants in the CanCOLD study completed spirometry tests, a simple test that measures how much air can be expressed in one forced breath. CT Scans were used to determine the size of an individual’s airways relative to size of their lungs. Lifestyle and behavioural risk factors were assessed using questionnaires, and validated methods were used to estimate air pollution concentrations at each participant’s residential location. Researchers also accounted for individual factors such as age, sex, body size, socioeconomic status, tobacco use and intensity, environmental tobacco smoke and biomass smoke exposure, and respiratory medication intake.
“Our study can help inform clinical management of chronic respiratory disease by identifying individuals with increased susceptibility to air pollutants,” says Dr. Bourbeau, “Our findings emphasize that even low levels of air pollution should not be considered safe.”
About the study
Read the publication in the American Journal of Respiratory and Critical Care Medicine
The authors gratefully acknowledge support from the Canadian Institutes of Health Research (CIHR, grant # 453225) and GlaxoSmithKline (study # 213021).
The authors thank CanCOLD study participants and individuals in the CanCOLD Collaborative Research Group and the Canadian Respiratory Research Network. The authors also acknowledge the Canadian Urban Environmental Health Research Consortium (CANUE) for providing ambient air pollution data used in their study.
About the RI-MUHC
The Research Institute of the McGill University Health Centre (RI-MUHC) is a world-renowned biomedical and healthcare research centre. The institute, which is affiliated with the Faculty of Medicine of McGill University, is the research arm of the McGill University Health Centre (MUHC) – an academic health centre located in Montreal, Canada, that has a mandate to focus on complex care within its community. The RI-MUHC supports over 450 researchers and around 1,200 research trainees devoted to a broad spectrum of fundamental, clinical and health outcomes research at the Glen and the Montreal General Hospital sites of the MUHC. Its research facilities offer a dynamic multidisciplinary environment that fosters collaboration and leverages discovery aimed at improving the health of individual patients across their lifespan. The RI-MUHC is supported in part by the Fonds de recherche du Québec – Santé (FRQS). rimuhc.ca