image title

Study: Hot cars can hit deadly temperatures in as little as one hour

New study: In the sun, car interiors can reach deadly temps in about an hour.
May 24, 2018

New research from ASU and UC San Diego measured air and surface temperatures of cars parked in sun and shade

A lot can happen at 160 degrees Fahrenheit: Eggs fry, salmonella bacteria dies, and human skin will suffer third-degree burns. If a car is parked in the sun on a hot summer day, its dashboard can hit about 160 degrees in about an hour. One hour is also about how long it can take for a young child trapped in a car to suffer heat injury or even die from hyperthermia.

Researchers from Arizona State University and the University of California at San Diego School of Medicine have completed a study to compare how different types of cars warm up on hot days when exposed to different amounts of shade and sunlight for different periods of time. The research team also took into account how these differences would affect the body temperature of a hypothetical 2-year-old child left in a vehicle on a hot day. Their study was published today in the journal Temperature.

“Our study not only quantifies temperature differences inside vehicles parked in the shade and the sun, but it also makes clear that even parking a vehicle in the shade can be lethal to a small child,” said Nancy Selover, a climatologist and research professor in ASU’s School of Geographical Sciences and Urban Planning.

From January through May 2018, six children died after being left in hot cars in the United States. That number will go up. Annually in the U.S., an average of 37 children left in hot cars die from complications of hyperthermia — when the body warms to above 104 degrees and cannot cool down. More than 50 percent of cases of a child dying in a hot car involve a parent or caregiver who forgot the child in the car. 

The findings

Researchers used six vehicles for the study: Two identical silver midsize sedans, two identical silver economy cars and two identical silver minivans. During three hot summer days with temperatures in the 100s in Tempe, Arizona, researchers moved the cars from sunlight to shade for different periods of time throughout the day. Researchers measured interior air temperature and surface temperatures throughout different parts of the day.

“These tests replicated what might happen during a shopping trip,” Selover said. “We wanted to know what the interior of each vehicle would be like after one hour, about the amount of time it would take to get groceries. I knew the temperatures would be hot, but I was surprised by the surface temperatures.”

For vehicles parked in the sun during the simulated shopping trip, the average cabin temperature hit 116 degrees in one hour. Dashboards averaged 157 degrees, steering wheels 127 degrees, and seats 123 degrees in one hour.

For vehicles parked in the shade, interior temperatures were closer to 100 degrees after one hour. Dashboards averaged 118 degrees, steering wheels 107 degrees and seats 105 degrees after one hour.

The different types of vehicles tested warmed up at different rates, with the economy car warming faster than the midsize sedan and minivan.

“We’ve all gone back to our cars on hot days and have been barely able to touch the steering wheel,” Selover said. “But imagine what that would be like to a child trapped in a car seat. And once you introduce a person into these hot cars, they are exhaling humidity into the air. When there is more humidity in the air, a person can’t cool down by sweating because sweat won’t evaporate as quickly.”

hot car graphic

Graphic by Safwat Saleem/ASU

Hyperthermia

A person’s age, weight, existing health problems and other factors, including clothing, will affect how and when heat becomes deadly. Scientists can’t predict exactly when a child will suffer a heatstroke, but most cases involve a child’s core body temperature rising above 104 degrees for an extended period.

In the study, the researchers used data to model a hypothetical 2-year-old boy’s body temperature. The team found that a child trapped in a car in the study’s conditions could reach that temperature in about an hour if a car is parked in the sun, and just under two hours if the car is parked in the shade.

“We hope these findings can be leveraged for the awareness and prevention of pediatric vehicular heatstroke and the creation and adoption of in-vehicle technology to alert parents of forgotten children,” said Jennifer Vanos, lead study author and assistant professor of climate and human health at UC San Diego.

Hyperthermia and heatstroke effects happen along a continuum, Vanos said. Internal injuries can begin at temperatures below 104 degrees, and some heatstroke survivors live with brain and organ damage.

Why memories fail

Forgetting a child in the car can happen to anyone, said Gene Brewer, an ASU associate professor of psychology. Brewer, who was not involved in the heat study, researches memory processes and has testified as an expert witness in a court case involving a parent whose child died in a hot car.

“Often these stories involve a distracted parent,” he said. “Memory failures are remarkably powerful, and they happen to everyone. There is no difference between gender, class, personality, race or other traits. Functionally, there isn’t much of a difference between forgetting your keys and forgetting your child in the car.”

Most people spend a lot of time on routine behaviors, doing the same activities over and over without thinking about them. For example, driving the same route to work, taking the children to day care on Tuesdays and Thursdays, or leaving car keys in the same spot every day. When new information comes into those routines, such as a parent’s day care drop-off day suddenly changing or an emergency phone call from a boss on the way to work, that’s when memory failures can occur.

“These cognitive failures have nothing to do with the child,” Brewer said. “The cognitive failure happens because someone’s mind has gone to a new place, and their routine has been disrupted. They are suddenly thinking about new things, and that leads to forgetfulness. Nobody in this world has an infallible memory.”

Ariane Middel, an assistant professor in Temple University’s Department of Geography and Urban Studies, and Michelle N. Poletti, a civil engineering student at Florida International University, also worked on the study as part of the National Science Foundation Central Arizona-Phoenix Long-Term Ecological Research Program through ASU.

Leslie Minton

Media Relations Manager , Media Relations and Strategic Communications

480-727-4294

 
image title

Tempe, ASU to work together on wastewater monitoring to improve public health

May 24, 2018

Biodesign engineer Rolf Halden's lab to identify concentrations of opioids, other substances in samples from sewage lines

The Tempe City Council announced Thursday that it will provide $35,000 from the Tempe Innovation Fund to embark on an anonymized monitoring system with Arizona State University scientists that will reveal the presence of opioids, cocaine, alcohol, marijuana and other health-threatening substances in the city’s wastewater. According to Tempe officials, the immediate goal of this new partnership is to achieve an end to opioid-related deaths and overdoses. The university will provide matching funds of $35,000.

ASU Biodesign Institute environmental engineer Rolf Halden and his lab will analyze sewage samples from the city, providing nearly real-time results that can help Tempe better serve its populace.

“Pairing the data from this wastewater program with the opioid map [a dashboard that documents public safety calls where use of opioids is likely] will help us pinpoint where to send the necessary resources to help people overcome addiction,” Tempe City Councilman Joel Navarro said. “This research could help save lives.”

Navarro is a firefighter who has seen the effects of opioid abuse firsthand. He is also chair of the Regional Opioid Action Plan Committee, a group of government representatives, nonprofit agencies, churches and health-care experts.

"With their vote, the city of Tempe has become the de facto thought leader in public health among cities across the United States,” said HaldenHalden is also director of ASU's Biodesign Center for Environmental Health Engineering , a professor in the Ira A. Fulton Schools of Engineering who will lead the effort.

Halden’s technology is being used in more than 300 cities across the world, but the Tempe project will be the first civic-university public health partnership — one in which the researchers and city officials will work together to extract data, review results and work collaboratively to refine the process, and identify and implement effective solutions.

LISTEN: Thought Huddle podcast — ‘We monitor what goes down the drain’

Because samples are taken from sewage lines carrying waste of thousands of people, the samples cannot be linked to any one individual. The anonymity of the process and detected drug types and quantities deliver results that are far more reliable than personal surveys or other methods.

“This is about the health of an entire city,” said Adam Gushgari, postdoctoral research associate in Halden’s Biodesign Center for Environmental Health Engineering. “As public health researchers and professional engineers, we study populations, not individuals. When we draw a sample of city wastewater, it always represents an anonymous composite from typically thousands to even hundreds of thousands of residents, with no way of linking obtained data to any one particular person.”

ASU PhD candidate Varun P. Kelkar examines a water sampling station
ASU PhD candidate Varun P. Kelkar retrieves a sample at the wastewater sampling point near a Packard parking structure on the Tempe campus Tuesday. Photo by Adam Gushgari/ASU

Halden’s Human Health Observatory is the largest archive of wastewater samples worldwide and has been used in the past to change U.S. policy. Halden’s team previously used wastewater and human cohort studies to bring to light the detrimental effects of harmful antimicrobials, such as triclosan and triclocarban. Following his call for national and international legal action, the Food and Drug Administration banned the use of these chemicals in personal-care products last September.

No additional sample collection is necessary for the Tempe project, as city public works staff already follow a regular schedule for compliance monitoring. With his lab on ASU’s Tempe campus, Halden’s team will receive the samples and provide results in near real time. Halden’s process uses tandem mass spectrometry, which can isolate and identify concentrations of specific opioids, including morphine, codeine, oxycodone, heroin and fentanyl. Measured concentrations of opioids are then converted to pounds per day per population to estimate the amount of drugs used in an area, the number of drug abusers and even the number of overdoses.

WATCH: Arizona PBS Catalyst — 'The dirty little secret of soaps'

With the addition of this project, Tempe could emerge as a role model for other cities across Arizona and the U.S. In addition to the new project, in February of this year, the city launched an Opioid Abuse Dashboard, which documents public safety calls where use of opioids is likely.

The wastewater data will be weighed alongside the Arizona Youth Survey’s report, which asks people age 18 and younger whether they use tobacco, alcohol, marijuana or other drugs.

For the 2017–18 fiscal year budget, the city of Tempe established a one-time, non-recurring Innovation Fund of $500,000, designed to encourage and promote new and creative ideas that significantly improve the community and position Tempe as an innovator. 

Top photo: ASU PhD candidate Erin M. Driver examines a wastewater sampling point on the Tempe campus Tuesday. Photo by Adam Gushgari/ASU