Bad air
In addition to pollen, the ambient air in many places is increasingly becoming saturated with bioallergenic proteins such as bacteria, viruses, animal dander, insects, molds, and plant species, Ms. Balakrishnan and colleagues noted, adding that “atmospheric levels of carbon dioxide have also been found to increase pollen productivity. These changes result in greater over-the-counter medication use, emergency department visits, and outpatient visits for respiratory illnesses.”
The rash of violent storms that has washed over much of the United States in recent months is also likely to increase the incidence of so-called “thunderstorm asthma,” caused when large quantities of respirable particulate matter are released before or during a thunderstorm.
Air pollution from the burning of carbon-based fuels and from wildfires sparked by hotter and drier conditions increase airborne particulate matter that can seriously exacerbate asthma, COPD, and other obstructive airway conditions.
In addition, as previously reported by Medscape, exposure to particulate matter has been implicated as a possible cause of non–small cell lung cancer in persons who have never smoked.
Critical care challenges
Among the myriad other effects of climate change postulated in evidence enumerated by Ms. Balakrishnan and colleagues are chest infections and pleural diseases, such as aspergillosis infections that occur after catastrophic flooding; increased incidence of Mycobacterium avium complex infections and hypersensitivity pneumonitis; increased demands on critical care specialists from natural disasters; pollution-induced cardiac arrest; and heat prostration and heat stroke from increasingly prevalent heat waves.
The reviewers also examined evidence suggesting links between climate change and pulmonary hypertension, interstitial lung disease, sleep disorders, and occupational pulmonary disorders.
Power to the patients
“Pulmonologists should counsel patients on ways to minimize outdoor and indoor pollution, using tight-fitting respirators and home air-purifying systems without encroaching on patients’ beliefs and choices,” the authors advise.
“Empowering patients with resources to monitor air quality daily, in inclement weather, and during disasters would help minimize exposure and thus improve overall health. The pulmonologist can play an important role in emphasizing the impact of climate change on pulmonary disorders during patient care encounters,” they write.
Ms. Balakrishan adds that another important mitigation measure that can be taken today is education.
“In medical school we don’t really learn about the impact of climate change – at least in my generation of physicians, climate change or global warming weren’t part of the medical curriculum – but now I think that there’s a lot of advocacy work being done by medical students who actually want more education on climate change and its effects on pulmonary diseases,” she said.
The study by Ms. Balakrishnan and colleagues was unfunded. Ms. Balakrishnan reports no relevant financial relationships. Co-author Mary-Beth Scholand, MD, has received personal fees from serving on advisory boards and speakers bureaus for Genentech, Boehringer Ingelheim, Veracyte, and United Therapeutics. Co-author Sean Callahan, MD, has received personal fees for serving on advisory boards for Gilead and Boehringer Ingelheim. Dr. Fineman reports no relevant financial relationships.
A version of this article originally appeared on Medscape.com.