Play Live Radio
Next Up:
0:00 0:00
Available On Air Stations
Tell us how you use the radio, along with social media, smartphones, tablets, streaming and the web to stay connected to entertainment, news and updates from MTPR and other sources. Whether you use all these things or none, your response is helpful.

Air pollution could be making antibiotic resistance worse


Antibiotic-resistant infections are on the rise across the world. So-called superbugs caused more than a million deaths in 2019, and that number could reach 10 million people a year by 2050. A new study points to one surprising potential culprit for the spread of antibiotic resistance - air pollution. NPR's Gabriel Spitzer has been looking into the research, and he joins us now. Welcome.


RASCOE: So first, let's talk about antibiotic resistance and how it spreads. Can you give us a refresher on exactly what it is?

SPITZER: Sure. So when someone takes an antibiotic, the meds kill off most of the bacteria - the vulnerable bacteria - but, sometimes, a few hardier microbes survive the antibiotic attack. And those resistant bacteria are then free to thrive and spread and cause infections that resist our best drugs. So that could look like MRSA - those really stubborn staph infections that we hear about - or souped-up versions of TB or gonorrhea. And the thing is, antibiotics aren't only used for, you know, strep throat or an ear infection or whatever. They're also used on a gigantic scale in farming and aquaculture.

RASCOE: So what is it that's ending up in the air?

SPITZER: Well, it's not that antibiotics are leaking into the air and exposing people. It's the germs. So all those activities like agriculture and sewage treatment, even the handling of hospital waste - they leave behind a lot of resistant bacteria and deposit it in the soil in the waterways. And then there's also all this free-floating genetic material from the bacteria that's mixed in with those deposits, including some that carry the genes for resistance to antimicrobials, and those can actually spread resistance all on their own. So ultimately, that material doesn't just stay in the soil or the water. The wind can kick up particles and aerosols, and the microbes catch a ride. And once they're in the air, they can be inhaled by people.

RASCOE: So these bacteria are basically hitchhiking on the particles of air pollution, and then that's spreading infections?

SPITZER: Well, yeah, it's still a little unclear whether the airborne bacteria and genes are actually making people sick with antibiotic-resistant infections. But this new study basically looked at the correlation between the two and found that all over the world, higher levels of particulate air pollution seem to correspond with higher levels of antimicrobial-resistant infections. And the research team, who are mostly based at a university in China, tried to control for a bunch of other factors that might affect the resistance - things like socioeconomic status and how much people spend on health care - and the link was still there.

But that's not to say, Ayesha, that the levels are the same everywhere. The study finds that much of Africa and South Asia seem to bear the highest burden from both the pollution and the drug-resistant infections. Now, those tend to be lower-income countries, as well as the places where the data is the least complete.

RASCOE: So how much of a problem is this? Like, how much of this big, global health problem is because of air pollution, specifically?

SPITZER: The study doesn't prove that pollution is causing the infections, but they found that the portion of resistance that's associated with particulate pollution - it adds up to a big chunk of the increase in antibiotic resistance over the past couple of decades - like, 12%. And that translates to about 480,000 premature deaths over that period.

RASCOE: Wow. I mean, and that's on top of all the other well-known really nasty health effects from particulate air pollution, you know, like lung disease.

SPITZER: Yeah, that's right. And the authors point out that this could mean that reducing air pollution is another lever to control antibiotic resistance. So if you bring down the pollution, you might get this extra benefit of reducing the spread of superbugs.

RASCOE: That's Gabriel Spitzer of NPR's Science Desk. Thank you so much, Gabriel.

SPITZER: You're welcome.

RASCOE: And you can learn more about this topic and see an illustration of the flying bacteria on our Goats and Soda blog at, right?

SPITZER: That's exactly right. Transcript provided by NPR, Copyright NPR.

NPR transcripts are created on a rush deadline by an NPR contractor. This text may not be in its final form and may be updated or revised in the future. Accuracy and availability may vary. The authoritative record of NPR’s programming is the audio record.

Ayesha Rascoe
Ayesha Rascoe is a White House correspondent for NPR. She is currently covering her third presidential administration. Rascoe's White House coverage has included a number of high profile foreign trips, including President Trump's 2019 summit with North Korean leader Kim Jong Un in Hanoi, Vietnam, and President Obama's final NATO summit in Warsaw, Poland in 2016. As a part of the White House team, she's also a regular on the NPR Politics Podcast.
Gabriel Spitzer
Gabriel Spitzer (he/him) is Senior Editor of Short Wave, NPR's daily science podcast. He comes to NPR following years of experience at Member stations – most recently at KNKX in Seattle, where he covered science and health and then co-founded and hosted the weekly show Sound Effect. That show told character-driven stories of the region's people. When the Pacific Northwest became the first place in the U.S. hit by COVID-19, the show switched gears and relaunched as Transmission, one of the country's first podcasts about the pandemic.
Become a sustaining member for as low as $5/month
Make an annual or one-time donation to support MTPR
Pay an existing pledge or update your payment information