Friday, October 08, 2021

AIR POLLUTION STUDIES

USC studies show that clean air matters for a healthy brain


Research on air pollution and cognitive decline indicate cleaner air may reduce risk for Alzheimer’s and other dementias

Peer-Reviewed Publication

UNIVERSITY OF SOUTHERN CALIFORNIA

Two USC researchers whose work linked air pollution to a greater risk of Alzheimer’s disease and faster cognitive decline are seeing signs that cleaner air can make a difference in brain health.

Cars and factories produce a fine particulate known as PM2.5 that USC-led studies have linked to memory loss and Alzheimer’s disease. Smaller than the width of a human hair, these tiny particles pose a big problem. Once inhaled, they pass directly from the nose up and into the brain, beyond the blood-brain barrier that normally protects the brain from dust or other invaders.  

In a research letter published today in Alzheimer’s & Dementia: The Journal of the Alzheimer’s Association, the USC researchers described how their labs each independently reported indications of recent decreases in neurotoxicity (damage to the brain or nervous system caused by exposure to toxic substances) of PM2.5 air pollution in humans and mice.

University Professor Caleb Finch and associate professor of gerontology and sociology Jennifer Ailshire, both with the USC Leonard Davis School of Gerontology, focused on PM2.5 pollution. Long-term exposure to PM2.5 has been linked to premature death, particularly in people with chronic heart or lung diseases.

Ailshire’s research, published earlier this year in the Journal of Alzheimer’s Disease, showed a strong association between cognitive deficits and air pollution among people with lower levels of education in 2004.

Based on data from the nationwide Health and Retirement Study, her work showed that, when exposed to PM2.5, adults 65 and older who had fewer than eight years of education faced a greater risk of cognitive impairment. But one decade later, Ailshire found no such association for study participants.

A likely factor was the reduction in PM2.5 over the prior decade, said Ailshire. Air quality data showed the average annual PM2.5 levels in the study participants’ neighborhoods were 25% below 2004 levels.

Notably in 2014, very few of the study participants lived in places with annual average PM2.5 that exceeded U.S. Environmental Protection Agency air quality standards. This further suggested that the improvements with cognitive decline were linked to a drop in exposure to high pollution among older adults.

“Improving air quality around the country has been a tremendous public health and environment policy success story. But there are signs of a reversal in these trends,” Ailshire said. “Pollution levels are creeping up again and there are increasingly more large fires, which generate a significant amount of air pollution in certain parts of the country. This gives me cause for concern about future trends in improving air quality.”

Finch’s research on mice, published earlier this year in the Journal of Alzheimer’s Disease, also found evidence of lower neurotoxicity of air pollution over time.

Finch and his research team have studied pollution levels at the same Los Angeles site and their effect on mouse brains since 2009. After 2017, the mice exposed to a tiny, nanoscale version of PM2.5 appeared healthier. Markedly, they showed sharp declines in several factors of neurotoxicity, including oxidative damage to cells and tissues.

During the years that Finch’s and Ailshire’s studies were taking place, the composition of air pollution in the United States was also changing.

From 2000 to 2020, PM2.5 levels declined nationwide by 41%, according to the EPA. In contrast, urban PM2.5 in Los Angeles declined only slightly from 2009 to 2019. While nationwide ozone levels decreased, Los Angeles County ozone reversed the prior trends by increasing after 2015.

Finch and Ailshire emphasize that their findings cannot evaluate potential benefits of air pollution improvements to the risk of cognitive decline and dementia. Although PM2.5 levels declined nationally from 2009 to 2016, the year-over-year increases that have been observed since 2017 show that improvements in air quality can be reversed, as they were in Los Angeles.

“Our findings underscore the importance of efforts to improve air quality as well as the continued importance of demographic and experimental evaluation of air pollution neurotoxicity,” Finch said.

Finch and Jiu-Chiuan “J.C.” Chen, an associate professor of preventive medicine at the Keck School of Medicine of USC, previously published a study using both human and animal data that showed brain aging processes worsened by air pollution may increase dementia risk. Their research indicated that older women who lived in locations with high levels of PM2.5 suffered memory loss and Alzheimer’s-like brain shrinkage not seen in women living with cleaner air.

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Smoggier skies, lower scores? 

A Brazilian study examines the effects of air pollution on students’ cognitive performance

Peer-Reviewed Publication

UNIVERSITY OF CHICAGO PRESS JOURNALS

A new study published in the Journal of the Association of Environmental and Resource Economists looks at the causal relationship between outdoor air pollution levels on nationwide university entry examination day and students’ cognitive performance in Brazil.

In “The Effects of Air Pollution on Students’ Cognitive Performance: Evidence from Brazilian University Entrance Tests,” authors Juliana Carneiro, Matthew A. Cole, and Eric Strobl use Brazilian data on concentrations of ozone (O3) and particulate matter (PM10) and a data set of students’ scores to examine the impact of air pollution on academic performance in national examinations. The air pollution data focuses on Rio de Janeiro and São Paulo—Brazil’s most industrialized states—using air pollution and weather monitoring station data to build a unique data panel from 2015–17.

The authors constructed individual-level panel data for the two days of exams across three years and applied student fixed effects to address potential endogeneity concerns. “In addition,” they note, “We take advantage of plausibly exogenous spatial and temporal variation in PM10 across municipalities in the states of Rio de Janeiro and São Paulo and utilize an instrumental variable approach based on wind direction.”

The findings suggest that an increase of 10 micrograms per cubic meter (mg/m3) of PM10 on the day of the examination decreases students’ scores by 6.1 points (8% SD). “Even when including a more flexible measure of our treatment that is utilizing a dummy variable to account for the days in which PM10 exceeded the WHO’s acceptable threshold, our findings still point to negative effects of air pollution on cognitive performance during examinations,” they note. Placebo tests, sensitivity checks, and falsifications tests reinforced the main findings: evidence of a link between air pollution and exam performance.

Consistent with previous studies, the authors also find evidence that the effect of air pollution on exam performance appears to affect males more adversely than females. “Our results also suggest that poorer students may be more susceptible to air pollution than wealthier exam takers,” they write, adding, “Our findings provide plausible evidence to suggest that cognitive performance may be hindered by poor air quality, but unequally so.”

Pollution from freight traffic disproportionately impacts communities of color across 52 US cities


Low-income and minority neighborhoods in U.S. exposed to 28% more nitrogen dioxide pollution, study finds

Peer-Reviewed Publication

AMERICAN GEOPHYSICAL UNION

Inequalities in exposure to NO2 pollution 

IMAGE: ACROSS 52 U.S. CITIES, LARGE DISCREPANCIES IN EXPOSURE TO NO2 POLLUTION EXIST BETWEEN LOW-INCOME COMMUNITIES OF COLOR AND HIGH-INCOME WHITE COMMUNITIES. THE INEQUALITY IS DRIVEN PRIMARILY BY PROXIMITY TO ROADWAYS WITH HEAVY DIESEL TRUCK TRAFFIC, SAYS A NEW STUDY IN GEOPHYSICAL RESEARCH LETTERS. view more 

CREDIT: CREDIT: DEMETILLO ET AL. (2021)/GEOPHYSICAL RESEARCH LETTERS

WASHINGTON—In urban areas across the U.S., low-income neighborhoods and communities of color experience an average of 28% more nitrogen dioxide (NO2) pollution than higher-income and majority-white neighborhoods. The disparity is driven primarily by proximity to trucking routes on major roadways, where diesel trucks are emitters of NO2 and other air pollutants.

Nitrogen dioxide is a common air pollutant that can cause a range of health problems, such as chronic respiratory illness and asthma. But it can be difficult to trace.

new study used high-resolution air pollution data measured with satellites to track NOfor nearly two years in major cities across the U.S. The researchers then paired the pollution data with both demographic data and metrics that analyze the degree of racial segregation in a community.

Cities with bigger populations tended to have larger disparities in NOpollution between low-income neighborhoods of color and high-income white neighborhoods, according to the study. Phoenix, Los Angeles and Newark, N.J., have the highest NOinequalities, all with a discrepancy in NO2 exposure of over 40%.

Both commuter traffic and heavy-duty trucks contribute NOand other pollutants, but diesel trucks are the dominant source, contributing on average up to half of a city’s NOdespite being at most 5% of traffic. Because diesel trucks also emit other harmful gases and particulates, changes in NOare also thought to reflect exposure to other pollutants as well.

The findings are detailed in the AGU journal Geophysical Research Letters, which publishes high-impact, short-format reports with immediate implications spanning all Earth and space sciences.

“One of the novel things we looked at was the integration of segregation metrics and air quality. Previously, we had been limited in our ability to address air pollution inequality, but with improvements in satellite resolution we are now able to get spatially and temporally continuous data at finer resolutions within cities,” said Angelique Demetillo, an atmospheric chemist at the University of Virginia and lead author of the study.

Measuring pollutants like NOis difficult to do at a scale that’s useful to local policymakers. While previous studies have shown disparities in air quality, the new findings offer near-daily pollution data at small scales, providing important quantitative information policymakers can use to guide zoning and public health and that can reflect the lived experience of community members.

The new study found a 60% drop in heavy trucking on weekends results in a 40% decrease in air pollution inequality. That can point policymakers to a clear emissions-reducing target.

“In terms of environmental justice, one of the things we have lacked is these observations across an entire city that also have temporal variability that we can use to understand the sources [of pollution],” said Sally Pusede, an atmospheric chemist at the University of Virginia who co-authored the study.

“We have these new data and methodologies that continue to show us what we already know through experience, but in the U.S., it’s [quantitative] data that informs policy,” said Regan Patterson, a transportation and public health expert at the Congressional Black Caucus Foundation.

Bigger city, bigger disparity

Transitioning to electric heavy-duty trucks could be one way of reducing pollution exposure in neighborhoods close to highways. California already has a mandate of doing this by 2045. But, Pusede pointed out, while emissions from diesel trucks are the biggest driver of exposure inequality, other pollution sources contribute to the problem. “Even if we eliminated emissions from trucking, we would still see inequalities present because there are other sources of inequality.”

Discrepancies in exposure to pollution between communities of color and white communities are well-documented. They often stem from zoning practices that result in communities of color forming in less desirable areas or infrastructure like highways being built in close proximity to — or through — a neighborhood.

Patterson said over the long term, transformative changes are needed to truly begin to remove NO2 pollution disparity. “How do you rectify the inequities that have literally been built into the environment, where certain groups are more likely to be adjacent to major roadways?” she asked.

Both Patterson and Pusede referenced a bill in the new infrastructure package aimed at physically reconnecting communities by removing freeways as a necessary step toward equalizing air quality. More immediately, Demetillo hoped her study and studies like it will help put air-quality information into the hands of community members.

“I see this as just the beginning. There are a lot of potential end-user applications, like people in different cities using this information to help them make decisions about how to go about their day. For policymakers, this could be a new way to plan mitigation solutions or to monitor how well those mitigation strategies are playing out,” Demetillo said.

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Notes for Journalists:

This research study is published with open access and is freely available. Download a PDF copy of the paper here. Neither the paper nor this press release is under embargo.

Paper title:

“Space-Based Observational Constraints on NO2 Air Pollution Inequality From Diesel Traffic in Major US Cities”

Authors:

  • Mary Angelique G. Demetillo, Sally E. Pusede (corresponding author), Department of Environmental Sciences, University of Virginia, Charlottesville, VA, USA
  • Colin Harkins, Cooperative Institute for Research in Environmental Sciences, University of Colorado, Boulder, CO, USA, and NOAA Chemical Sciences Laboratory, Boulder, CO, USA
  • Brian C. McDonald, NOAA Chemical Sciences Laboratory, Boulder, CO, USA
  • Philip S. Chodrow, Department of Mathematics, University of California Los Angeles, Los Angeles, CA, USA
  • Kang Sun, Department of Civil, Structural and Environmental Engineering and Research and Education in eNergy, Environment and Water (RENEW) Institute, University at Buffalo, Buffalo, NY, USA

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