South Middlesex Times

Climate-driven wildfire events are rapidly transferring harmful particulate matter containing toxic chemicals over long distances, compromising air quality in the New Jersey and New York City areas, according to Rutgers Health research.

Published in Environmental Science & Technology and to be featured on the cover of the journal’s next issue, the study assessed the physical and chemical characteristics of wildfire-related particulate matter and was the first to report this characterization from a climate-driven wildfire event in the densely populated Northeast region.

“Particulate matter is a leading environmental factor in the global burden of disease, with climate-driven wildfires being a major source,” said lead author Jose Guillermo "Memo" Cedeño Laurent, assistant professor at the Rutgers School of Public Health and director of the Rutgers Climate Adaptive and Restorative Environments Lab. “In the U.S., climate change-driven wildfires are reversing decade-long improvements in ambient air quality.”

The issue is pressing as there is an increasing body of evidence suggesting wildfire pollution is associated with worsened health impacts compared to non-wildfire pollution. Emerging evidence includes recent epidemiological studies linking the wildfire event to respiratory and cardiovascular emergency visits in New York City, although little is known about the mechanisms behind those impacts.

Using advanced physicochemical analysis of the particulate matter, researchers discovered large amounts of high molecular weight polycyclic aromatic hydrocarbons (PAHs), which are cancer-causing organic compounds, at the peak of the incident on June 7.

“We found very large concentrations of ultrafine and fine particulate matter during the peak of this wildfire, surpassing almost 10 times the national air quality standards and any previous record in more than five decades of air quality monitoring in the U.S. Northeast,” said Cedeño Laurent.

Senior author Philip Demokritou, Henry Rutgers Chair and professor in nanoscience and environmental engineering at the Rutgers School of Public Health and director of the Nanoscience and Advanced Materials Center (NAMC), said, “Such small particles have the ability to penetrate deep in the lung and can cause adverse health effects, as recently reported in the New York City area by epidemiological studies.”

Findings showed that the estimated potential inhalation dose of particulate matter (PM10) over a 72-hour exposure period was found to be more than 9 micrograms of particles deposited in the lungs.

“Our findings on extremely high concentrations of ultrafine particles and their significant PAH content are proving to be invaluable in guiding several ongoing mechanistic studies at NAMC,” Cedeño Laurent said.

He added that these studies are investigating effects on various organs including lungs by Reynold Panettieri and Joseph Jude at Rutgers Robert Wood Johnson Medical School; heart by National Heart, Lung, and Blood Institute’s cardiovascular program; brain by David Leong at National University of Singapore; reproductive system by Shuo Xiao and Andrew Gow at Rutgers Ernest Mario School of Pharmacy.

“Findings will advance our understanding of physical and chemical characteristics of wildfire smoke and its impact on human health,” Cedeño Laurent said.

Researchers emphasized further investigation into physical and chemical processes differentiating wildfire-related air pollution from non-wildfire pollution.

“Results from our study can be used by public health assessors to evaluate risk and develop strategies to help our communities,” Demokritou said, “especially those in areas already compromised by air pollution to adapt to increasing wildfire phenomena.”

Additionally, Cedeño Laurent and Demokritou noted their results offer novel insights into evolving composition of particulate matter. Their analysis on optical properties will feature in a companion study led by Georgios Kelesidis examining effects on Earth’s temperature influencing climate change in densely populated cities.

Rutgers’ co-authors include Georgios Kelesidis; post-doctoral fellows Hooman Parhizkar; Leonardo Calderon; doctoral candidate Lila Bazina.