A new stretchy patch applied directly to the skin wicks up sweat to measure the stress hormone cortisol.
Cortisol rises and falls naturally throughout the day and can spike in response to stress, but current methods for measuring it require waiting several days for results from a lab.
By the time a person learns the results—which may pinpoint the best treatment for certain medical conditions—it’s likely different from the current level of cortisol.
“We are particularly interested in sweat sensing, because it offers noninvasive and continuous monitoring of various biomarkers for a range of physiological conditions,” says lead author Onur Parlak, a postdoctoral scholar in the lab of Alberto Salleo, associate professor of materials science and engineering at Stanford University. “This offers a novel approach for the early detection of various diseases and evaluation of sports performance.”
As reported in Science Advances, clinical tests that measure cortisol provide an objective gauge of emotional or physical stress in research subjects and can help doctors tell if a patient’s adrenal or pituitary gland is working properly. If the prototype version of the wearable device becomes a reality, it could allow people with an imbalance to monitor their own levels at home.
A fast-working test like this could also reveal the emotional state of young—even non-verbal—children, who might not otherwise be able to communicate that they feel stress.
Parlak came to work with Salleo, intending to develop wearable technologies. While discussing Parlak’s work at a conference, someone suggested to Salleo that it would be great if a sensor could measure cortisol. Cortisol presents a special challenge to biosensors like the one Parlak was developing because these sensors detect a molecule’s positive or negative charge—and cortisol has no charge.
To overcome the challenge, Parlak built a stretchy, rectangular sensor around a membrane that specifically binds only to cortisol. Stuck to the skin, it sucks in sweat passively through holes in the bottom of the patch. The sweat pools in a reservoir, which is topped by the cortisol-sensitive membrane.
Enough to glisten
Charged ions like sodium or potassium, also found in sweat, pass through the membrane unless they are blocked by cortisol. It’s those backed up charged ions the sensor detects, not the cortisol itself. On top of all this is a waterproof layer that protects the patch from contamination.
“I always get excited about a device, but the sweat collection system that Onur devised is really clever,” Salleo says. “Without any active microfluidics, he’s able to collect enough sweat to do the measurements.”
All a user needs to see cortisol levels is to sweat (enough to glisten), apply the patch, and connect it to a device for analysis, which gives results in seconds. In the future, the researchers hope the sensor could be part of a fully integrated system.
Parlak first showed that the device measured up to the gold standard clinical test in the lab, then gave it a real world test. He strapped on his running shoes and recruited two volunteers, who all ran for 20 minutes with the patches on their arms. In both the lab and real world tests, the results were similar to the gold standard.
So far, the sensor appears to work as designed. But the researchers want to make it more reliable and accurate, and also make sure it is reusable. The prototype seems to work multiple times so long as it is not saturated with sweat. In the future, they may try the cortisol sensor on saliva, which would avoid patients needing to sweat.
The researchers, hoping to take advantage of their generalizable design, are also figuring out what biomarker they may want to study next. Eventually, the goal would be to have a device that measures several biomarkers at once, which would give a clearer and more individualized picture of what is going on in a person’s body.
Additional researchers from Stanford and from École Nationale Supérieure des Mines in France are coauthors of the paper. The Wallenberg Foundation at Stanford, the France-Stanford Center for Interdisciplinary Studies, and a Stanford Graduate Fellowship funded the work.
Source: Stanford University