Original Link: https://www.motherjones.com/environment/2020/07/how-trees-can-help-us-fight-a-pandemic/
As the world grapples with the devastation of the coronavirus, one thing is clear: The United States simply wasn’t prepared. Despite repeated warnings from infectious disease experts over the years, we lacked essential beds, equipment, and medication; public health advice was confusing, and our leadership offered no clear direction while sidelining credible health professionals and institutions. Infectious disease experts agree that it’s only a matter of time before the next pandemic hits, and that could be even deadlier. How do we fix what COVID-19 has shown was broken? In this Mother Jones series, we’re asking experts from a wide range of disciplines one question: What are the most important steps we can take to make sure we’re better prepared next time?
Christina Hemphill Fuller is an environmental exposure scientist and epidemiologist focused on the intersection of air pollution, public health, and racial justice. Her expertise has taken on even greater relevance as the Centers for Disease Control and Prevention has confirmed that Black and Latino communities have experienced some of the worst effects of COVID-19, being three times as likely to become infected as white people, and nearly twice as likely to die. The Georgia State University professor says it’s not a coincidence that these communities also face more pollution in their daily lives, which makes them more vulnerable to a range of health problems, including lung damage. Fuller’s area of specialty is in a type of air pollution called ultrafine particles, which can lodge deep in the lungs and could make people more likely to experience severe effects of COVID-19.
On the health effects of air pollution: Air pollution has been known for a long time to be associated with different diseases and conditions linked to respiratory disease, but it’s also linked to heart attack, heart disease, and lung cancer, in addition to pregnancy outcomes like preterm birth and babies being born early and babies being born smaller.
People who live in places where air pollution is low are more resilient when they’re exposed to the virus, and they’re less likely to have severe COVID-19.
It’s definitely known that air pollution, particularly particulate matter, is associated with poor health outcomes. Air pollution many times concerns PM2.5—particulate matter as less than 2.5 microns in diameter—and also ozone. And both of those are regulated by the Clean Air Act.
On why Black people are disproportionately affected: There are many studies that have documented that communities with more Blacks or Hispanics have higher air pollution, and that’s because industries are placed there on purpose. The first study to talk about that was Toxic Waste and Race, way back in 1987, and updated in 2007. This study looked at hazardous waste facilities all around the country and found that the most important predictor was race, and the second was income.
There are some differences between urban communities and rural communities. One that’s really important that I study a lot is traffic. Definitely in urban communities a lot of air pollution that we’re concerned about comes from traffic. So being close to a highway or major roads that has lots of cars and trucks on it, you’re going to have high air pollution exposure. A lot of the times those run through communities of color, leading to high air pollution exposures in those neighborhoods.
In addition to that, we have our energy production, so natural gas and coal-fired power plants are also disproportionately in communities of color and low-income communities. There are other types of industries, like a car body shop and dry cleaners, that are smaller producers, but they do produce air pollution and those are also disproportionately in color or low-income communities.
In rural areas, traffic may be less of an issue, but you have other types of industry and power generation still disproportionately in communities of color.
On the challenges of pinning down the impact of air pollution in a pandemic: If you were to do a search for air pollution and heart disease, or air pollution and respiratory disease, you will find thousands and thousands of studies. But if you look at whether air pollution makes you susceptible, and that’s what the field of public health calls “effect modification,” you’re going to find maybe tens, twenties of those.
Let’s pick PM2.5, because PM2.5 is widely studied. We’ll do a study and record what the PM2.5 levels are, and then you’ll look at how many people die from a heart attack, how many people get a particular respiratory disease, or how many people get lung cancer due to that exposure. We can really say that exposure to particulate matter is related to development of asthma, because there’s just so much data. The research that I’ve been doing is people who are under high stress. So if you are under high stress and you’re exposed to air pollution, you have an even higher risk of heart disease. That’s putting two effects together. For COVID-19 there are a couple of studies that have come out—one is the Harvard study by Dr. Francesca Dominici of Harvard: If you have high exposure to air pollution, is that going to increase your risk of contracting COVID 19 and having worse outcomes? What we’re concerned about is susceptibility: When your lungs already damaged by having chronic exposure to particulate matter, then you’re going to be more susceptible to other diseases versus if you were just exposed to that disease, and your lungs weren’t already damaged. People who are living in areas where the air pollution is high already had damage and they actually are having worse health outcomes versus people who live in places where air pollution is low, who are more resilient when they’re exposed to the virus and they’re less likely to have severe COVID-19.
On the problem of ultrafine particles: Air pollution is such a mix of chemicals, and we only monitor for a few, and then we regulate for even fewer. Particulate matter are either solid or liquid droplets suspended in air and we regulate for those that are smaller than 2.5 microns, and smaller than than 10 microns. The EPA monitors for PM2.5 and PM10.
The Clean Air Act is wonderful and has led to many positive changes, but the EPA still may not tell you what’s outside of your house. But a particular one that I study is called ultrafine particles, and those are less than 100 nanometers in diameter. There is no regulation around that. Over recent years, the studies have shown that ultrafine particles are really, really important for public health. And you have to measure for them specifically.
If you put a PM2.5 monitor next to a busy highway, you’re not going to detect the really small particles. You’d have to monitor those specifically and those are re