How does climate change affect disease?

Just as snowbirds flock to warmer climes when winter settles in, wild creatures seek out weather that suits them. But a changing climate is moving that comfort zone for many animals, including disease-carrying mosquitoes that kill about 1 million people a year.

Stanford biologist Erin Mordecai and her colleagues have made startling forecasts of how climate change will alter where mosquito species are most comfortable and how quickly they spread disease, shifting the burden of disease around the world. A major takeaway: wealthy, developed countries such as the United States are not immune.

“It’s coming for you,” Mordecai said. “If the climate is becoming more optimal for transmission, it’s going to become harder and harder to do mosquito control.”

Mosquitoes and other biting insects transmit many of the most important, devastating and neglected human infectious diseases, including malaria, dengue fever, chikungunya and West Nile virus. Economic development and cooler temperatures have largely kept mosquito-borne diseases out of wealthier Northern Hemisphere countries, but climate change promises to tip the scales in the other direction.

“As the planet warms, we need to be able to predict what populations will be at risk for infectious diseases because prevention is always superior to reaction,” said Desiree LaBeaud, an associate professor of pediatrics in the Stanford Medical School who collaborates on research with Mordecai.

Mordecai’s research has found that warmer temperatures increase transmission of vector-borne disease up to an optimum temperature or “turn-over point,” above which transmission slows. Just as they carry different diseases, different mosquitoes are adapted to a range of temperatures. For example, malaria is most likely to spread at 25 degrees Celsius (78 degrees Fahrenheit) while the risk of zika is highest at 29 degrees Celsius (84 degrees Fahrenheit).

“If you’re thinking about impacts of climate change, this tells you a few degrees of warming has a really different impact depending on where you start relative to the optimum,” Mordecai said.

The good news: higher global temperatures will decrease the chance of most vector-borne disease spreading in places that are currently relatively warm. The bad news: warming will increase the chance that all diseases spread in places that are currently relatively cold.

Meanwhile, many influential global health initiatives focus on cell and molecular biology rather than disease transmission. “I think they’re missing a big area,” Mordecai said. “If you have an ecological change that results in 96 million dengue cases a year, you should target that causal relationship even as you try to find a dengue vaccine and get it to as many people as possible.”

It’s crucial to understand and predict the rise and spread of diseases and to factor related health costs into public policy, according to Mordecai. “Otherwise, we’re not going to be able to get a handle on this. We’re going to be constantly playing whack-a-mole with whatever the new emerging disease is.”

Mordecai is also a fellow at the Center for Innovation in Global Health. LaBeaud is also a member of the Maternal & Child Health Research Institute. Mordecai and LaBeaud are members of Bio-X and affiliates of the Stanford Woods Institute for the Environment.

Media Contacts

Rob Jordan
Stanford Woods Institute for the Environment
(650) 721-1881, rjordan@stanford.edu