Does the size of air pollution particles affect a person's risk of death from stroke?
Living in areas with higher air pollution is associated with an increased risk of in-hospital death from stroke, and the risk varies depending on the size of the air pollution particles, according to a new study published in the May 25, 2022, online issue ofNeurology.
The study looked at three sizes of air pollution particulate matter. Particulate matter consists of liquids or solids suspended in air. Submicron particulate matter, PM1, is less than one micron in diameter and includes soot and smog. Fine particulate matter, PM2.5, is less than 2.5 microns in diameter and includes fly ash from coal combustion. Respirable particulate matter, PM10, is less than 10 microns in diameter and includes cement dust.
"Air pollution has been previously linked to a greater risk ofstroke, and stroke is a leading cause of death worldwide," said study author Hualiang Lin, Ph.D., of Sun Yat-sen University in Guangzhou, China. "What is lesser known is how the different sizes of particulate matter affect that risk. Our research found that the size of air pollution particles may affect a person's risk of dying from stroke."
For the study, researchers examinedelectronic medical recordsin China to identify over 3.1 million hospitalizations for stroke, both ischemic stroke caused by a blood clot, and hemorrhagic stroke caused by bleeding in the brain. Participants had an average age of 67. Of this group, 32,140 people, or 1%, died of stroke while hospitalized.
Researchers identified individual levels of air pollution exposure for each participant by using their home addresses and an air pollution data source that records daily concentrations of different types of particulate matter. Researchers then calculated seven-day air pollution exposure immediately before hospitalization for stroke, which was 31.38 micrograms per cubic meter (µg/m3) of PM1, 45.43 µg/m3of PM2.5and 78.75 µg/m3of PM10. They also calculated a person's average daily exposure to pollution particles in the year before hospitalization, which was 32.98 µg/m3of PM1, 49.08 µg/m3of PM2.5and 87.32 µg/m3of PM10.
After adjusting for factors such as age, sex,socioeconomic status, diabetes andhigh blood pressure, researchers found each 10 μg/m3increase in annual average exposure to particulate matter was associated with increased risk of dying of stroke while hospitalized, with a 24% greater risk for exposure to PM1, a 11% greater risk for exposure to PM2.5, and a 9% greater risk for exposure to PM10. The seven-day average exposure to particulate matter included a 6% increased risk for exposure to PM1, a 4% increased risk for exposure to PM2.5, and a 3% increased risk for exposure to PM10.
The risks were stronger in people with ischemic stroke than in people withhemorrhagic stroke. The greatest risk of death from stroke was in people withischemic strokeand exposure to the smallest air pollution particles, PM1.
Yet researchers also found that a reduction in PM10would have the largest impact on reducing overall deaths from stroke, reducing the number of hospital deaths by 10% for short-term exposure and 21% for long-term exposure.
Lin said it is important to note that the study results do not prove that air pollution causes stroke deaths, they only show an association.
"Our study includes measurements of PM1, which may be small enough to be inhaled deeply into lungs, pass throughlung tissue, and circulate in the bloodstream," said Lin. "Obtaining a deeper understanding of the risk factors of allparticulate mattersizes and the magnitude of their possible effects may help reduce the number of deaths and improve the outcomes for people with stroke."
A limitation of the study was that results were not adjusted for a person's smoking status or the severity of stroke. Researchers also examined air pollution exposure only at a person's current residence and not at previous residences.