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Climate Change and Health Initiative to Expand Research, Build Resiliency

Posted on by Richard Woychik, Ph.D., National Institute of Environmental Health Sciences

A woman and child in a small boat paddling through flood waters
Credit: Athawit Ketsak/Shutterstock

Climate change is a global process that affects human health in a variety of complex ways. Wildfires, heat waves, hurricanes, floods, and other climate-related weather events can result in illness, injury, and death. Indirect health threats are cause for concern, too. For example, changes in temperature and rainfall can affect the lifecycle of mosquitoes that transmit diseases such as malaria and dengue fever, thereby paving the way for new outbreaks.

Environmental disruptions worsened by climate change can reduce air quality, diminish water resources, and increase exposure to higher temperatures and pathogens. As a result, we see greater health risks in susceptible individuals such as children, the elderly, the poor, and people with underlying conditions, both in America and around the world.

For decades, the National Institute of Environmental Health Sciences and other NIH institutes and centers (ICs) have advanced important research into how climate change affects health. But expanding knowledge in this area and addressing other key challenges will require much more collaboration. The time is now for an all-hands-on-deck scientific effort—across NIH and the wider biomedical research community—that spans many interconnected disciplines and fields of inquiry.

That is why I am excited to join forces with several other IC directors to launch the NIH Climate Change and Health Initiative. By working together, NIH institutes and centers can harness their technologies, innovative research approaches, and talent to advance the science of climate change and health. Through this timely effort, we will promote resilience in vulnerable communities because our research will help them to understand, prepare for, and recover from climate-related health challenges.

Our Strategic Framework outlines why it is important to go beyond studying the health effects of climate change. We must involve impacted communities in solutions-focused research that empowers them, health care practitioners, and health and social services agencies to reduce climate-related health risks. By generating scientific evidence for public health action, we can use a health equity approach to boost climate resiliency among at-risk groups, whether in the U.S. or low- and middle-income countries.

At the heart of the initiative is a push for transdisciplinary, team-based science that boosts training, research capacity, and community engagement. Our immediate goals are to use existing grant programs to strengthen research infrastructure and enhance communication, internally and externally.

Also, with dedicated support from several ICs and the Office of the Director (OD), NIH is funding a research coordinating center and a community engagement program. The coordinating center will help NIH scientists collaborate and manage data. And the community engagement program will empower underserved populations by encouraging two-way dialogue in which both scientists and community members learn from each other. That inclusive approach will improve research and mitigation efforts and reduce health disparities.

In addition, several Notices of Special Interest are now open for applications. The NIH invites scientists to submit research proposals outlining how they plan either to study the health effects of climate change or develop new technologies to mitigate those effects. Also, with OD support, a Climate and Health Scholars Program will launch later this year. Scientists working on important research will share their expertise and methodologies with the NIH community, spurring opportunities for further collaboration.

Going forward, any additional support from the White House, Congress, and the public will allow NIH to further expand the initiative. For example, we urgently need to test novel interventions for reducing heat stress among agricultural workers and to scale up early-warning systems for climate-related weather events. There is also opportunity to use laboratory-based and clinical methodologies to expand knowledge of how climate factors, such as heat and humidity, affect key cellular systems, including mitochondrial function.

To fill those and other research gaps, we must draw on an array of skill sets and fields of inquiry. Therefore, our Strategic Framework outlines the importance of supporting adaptation research, basic and mechanistic studies, behavioral and social sciences research, data integration, disaster research response, dissemination and implementation science, epidemiology and predictive modeling, exposure and risk assessment, and systems science. Tapping into those areas will help us tackle climate-related health challenges and develop effective solutions.

In recent years, in-depth reports and assessments have provided conclusive evidence that climate change is significantly altering our environment and impacting human health. Although the science of climate change and health has progressed, much work remains. We hope that the Climate Change and Health Initiative expands scientific partnerships and capacity throughout NIH and across the global biomedical and environmental health sciences communities. Greater collaboration will spur new knowledge, interventions, and technologies that help humanity manage the health effects of climate change and strengthen health equity.

(Note: The Initiative’s Executive Committee includes the following IC directors: Richard Woychik, National Institute of Environmental Health Sciences [chair]; Diana Bianchi, Eunice Kennedy Shriver National Institute of Child Health and Human Development; Gary Gibbons, National Heart, Lung, and Blood Institute; Roger Glass, Fogarty International Center; Joshua Gordon, National Institute of Mental Health; Eliseo Pérez-Stable, National Institute on Minority Health and Health Disparities; and Shannon Zenk, National Institute of Nursing Research.)

Links:

Environmental Health Topic: Climate Change (National Institute of Environmental Health Sciences /NIH)

NIH Climate Change and Health Initiative (NIH)

NIH Climate Change and Health Initiative Strategic Framework (NIH)

Research Coordinating Center to Support Climate Change and Health Community of Practice (NIH)

Research Opportunity Announcement: Alliance for Community Engagement—Climate Change and Health (National Heart, Lung, and Blood Institute / NIH)

Notice of Special Interest: Climate Change and Health (NIH)

Notice of Special Interest: Innovative Technologies for Research on Climate Change and Human Health Small Business Technology Transfer (R41/R42 Clinical Trial Option) (NIH)

Notice of Special Interest: Innovative Technologies for Research on Climate Change and Human Health, R43/R44 Small Business Innovation Research (R43/R44 Clinical Trial Optional) (NIH)

Note: Dr. Lawrence Tabak, who performs the duties of the NIH Director, has asked the heads of NIH’s Institutes and Centers (ICs) to contribute occasional guest posts to the blog to highlight some of the interesting science that they support and conduct. This is the 14th in the series of NIH IC guest posts that will run until a new permanent NIH director is in place.


Will Warm Weather Slow Spread of Novel Coronavirus?

Posted on by Dr. Francis Collins

Summer gear and a face mask
Credit: Modified from iStock/energyy

With the start of summer coming soon, many are hopeful that the warmer weather will slow the spread of SARS-CoV-2, the novel coronavirus that causes COVID-19. There have been hints from lab experiments that increased temperature and humidity may reduce the viability of SARS-CoV-2. Meanwhile, other coronaviruses that cause less severe diseases, such as the common cold, do spread more slowly among people during the summer.

We’ll obviously have to wait a few months to get the data. But for now, many researchers have their doubts that the COVID-19 pandemic will enter a needed summertime lull. Among them are some experts on infectious disease transmission and climate modeling, who ran a series of sophisticated computer simulations of how the virus will likely spread over the coming months [1]. This research team found that humans’ current lack of immunity to SARS-CoV-2—not the weather—will likely be a primary factor driving the continued, rapid spread of the novel coronavirus this summer and into the fall.

These sobering predictions, published recently in the journal Science, come from studies led by Rachel Baker and Bryan Grenfell at Princeton Environmental Institute, Princeton, NJ. The Grenfell lab has long studied the dynamics of infectious illnesses, including seasonal influenza and respiratory syncytial virus (RSV). Last year, they published one of the first studies to look at how our warming climate might influence those dynamics in the coming years [2].

Those earlier studies focused on well-known human infectious diseases. Less clear is how seasonal variations in the weather might modulate the spread of a new virus that the vast majority of people and their immune systems have yet to encounter.

In the new study, the researchers developed a mathematical model to simulate how seasonal changes in temperature might influence the trajectory of COVID-19 in cities around the world. Of course, because the virus emerged on the scene only recently, we don’t know very much about how it will respond to warming conditions. So, the researchers ran three different scenarios based on what’s known about the role of climate in the spread of other viruses, including two coronaviruses, called OC43 and HKU1, that are known to cause common colds in people.

In all three scenarios, their models showed that climate only would become an important seasonal factor in controlling COVID-19 once a large proportion of people within a given community are immune or resistant to infection. In fact, the team found that, even if one assumes that SARS-CoV-2 is as sensitive to climate as other seasonal viruses, summer heat still would not be enough of a mitigator right now to slow its initial, rapid spread through the human population. That’s also clear from the rapid spread of COVID-19 that’s currently occurring in Brazil, Ecuador, and some other tropical nations.

Over the longer term, as more people develop immunity, the researchers suggest that COVID-19 may likely fall into a seasonal pattern similar to those seen with diseases caused by other coronaviruses. Long before then, NIH is working intensively with partners from all sectors to make sure that safe, effective treatments and vaccines will be available to help prevent the tragic, heavy loss of life that we’re seeing now.

Of course, climate is just one key factor to consider in evaluating the course of this disease. And, there is a glimmer of hope in one of the group’s models. The researchers incorporated the effects of control measures, such as physical distancing, with climate. It appears from this model that such measures, in combination with warm temperatures, actually might combine well to help slow the spread of this devastating virus. It’s a reminder that physical distancing will remain our best weapon into the summer to slow or prevent the spread of COVID-19. So, keep wearing those masks and staying 6 feet or more apart!

References:

[1] Susceptible supply limits the role of climate in the early SARS-CoV-2 pandemic. Baker RE, Yang W, Vecchi GA, Metcalf CJE, Grenfell BT. Science. 2020 May 18. [Online ahead of print.]

[2] Epidemic dynamics of respiratory syncytial virus in current and future climates. Baker RE, Mahmud AS, Wagner CE, Yang W, Pitzer VE, Viboud C, Vecchi GA, Metcalf CJE, Grenfell BT.Nat Commun. 2019 Dec 4;10(1):5512.

Links:

Coronavirus (COVID-19) (NIH)

Bryan Grenfell (Princeton University, Princeton, NJ)

Rachel Baker (Princeton University, Princeton, NJ)


Zika Virus: An Emerging Health Threat

Posted on by Dr. Francis Collins

Credit: Kraemer et al. eLife 2015;4:e08347

For decades, the mosquito-transmitted Zika virus was mainly seen in equatorial regions of Africa and Asia, where it caused a mild, flu-like illness and rash in some people. About 10 years ago, the picture began to expand with the appearance of Zika outbreaks in the Pacific islands. Then, last spring, Zika popped up in South America, where it has so far infected more than 1 million Brazilians and been tentatively linked to a steep increase in the number of babies born with microcephaly, a very serious condition characterized by a small head and brain [1]. And Zika’s disturbing march may not stop there.

In a new study in the journal The Lancet, infectious disease modelers calculate that Zika virus has the potential to spread across warmer and wetter parts of the Western Hemisphere as local mosquitoes pick up the virus from infected travelers and then spread the virus to other people [2]. The study suggests that Zika virus could eventually reach regions of the United States in which 60 percent of our population lives. This highlights the need for NIH and its partners in the public and private sectors to intensify research on Zika virus and to look for new ways to treat the disease and prevent its spread.