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Shaking sensor continuously monitors inflammation

Implantable device works like a tree branch to grab and fling proteins
December 5, 2024 | By Amanda Morris
inflammation sensor
Postdoctoral fellow Hossein Zargartalebi, the study's first author, holds the first-of-its-kind sensor, which monitors fluctuating proteins within the body in real time.

Northwestern University scientists have designed a new implantable device that can monitor fluctuating levels of proteins within the body in real time.

Inspired by fruit shaking off the branches of a tree, the device comprises strands of DNA that stick to proteins, shake them off and then grab more proteins. This creative strategy enables the device to sample various proteins over time to measure changes in inflammatory markers.

In proof-of-concept experiments, the sensors accurately and sensitively measured protein biomarkers of inflammation in diabetic rats. The work lays the foundation for the real-time management and prevention of acute and chronic conditions through the tracking of critical proteins, such as cytokines in inflammation, protein biomarkers in heart failure and many others.

The study will be published on Friday (Dec. 6) in the journal Science.

“The device’s design is analogous to a continuous glucose monitor that sits on your arm and measures levels right beneath your skin,” said Northwestern’s Shana O. Kelley, who led the study. “You can see that your glucose levels are increasing in real time. But then maybe you take your insulin, and your glucose goes back down. You need to be able to measure trends in the wrong direction and trends in the right direction. It’s the same with proteins in inflammation. We need to track fluctuations in order to get a full picture of what’s happening in the body. This is a completely new capability — to be able to watch inflammation in real time. There are a huge number of applications that we are now beginning to explore.”

Kelley is the Neena B. Schwartz Professor of Chemistry and Biomedical Engineering at Northwestern, where she has appointments in the Weinberg College of Arts and Sciences, McCormick School of Engineering and Feinberg School of Medicine. She also is president of the Chan Zuckerberg Biohub Chicago, one of the four institutes in the Chan Zuckerberg Biohub Network.

Quaking with inspiration

While numerous sensors exist to continuously detect small molecules, such as glucose or electrolytes, sensors for proteins — which are larger and more complex than small molecules — are more challenging to design. To detect proteins in biological fluids, scientists typically use DNA receptors that bind to proteins and pull them out of biofluids.

The problem with these receptions is they work too well. Even with passive regeneration, these Velcro-like attachments are so strong that they hold onto proteins for more than 20 hours, making it impossible to measure real-time fluctuations in the blood. After trying several solutions to “reset” the sensors, Hossein Zargartalebi, the study’s first author, received inspiration from an unexpected place: nature.

“I thought about how shaking an apple tree, whether by hand or with a gust of wind, makes ripe apples detach and fall,” said Zargartalebi, a postdoctoral fellow in Kelley’s laboratory. “This simple observation sparked an idea. What if we could ‘shake’ the DNA receptors on our sensors to release the captured proteins in a similar way? I applied an alternating potential electrode, which caused the DNA strands to oscillate, and it worked. The proteins detached and the sensor was reset.”

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The nanoscale sensors look like rows of bulbous pendulums, each comprising a double-stranded cord of DNA. One end of the DNA strand is attached to an electrode, and the other end is attached to another bit of DNA that binds to a desired protein. When the researchers apply an alternating electric field, the pendulum-like sensors swing back and forth — flinging off proteins within a mere minute and catching others.

“Hossein was thinking very creatively and came up with a non-obvious idea,” Kelley said. “He went into the lab, tried it once and it worked. Then, he did it again, and it worked. It’s such a simple and elegant solution.”

“I was exhilarated, knowing that this natural insight had led to a major breakthrough,” Zargartalebi said. “Now, just as trees repeatedly grow and release their fruit, our DNA sensors can ‘release’ their proteins after each measurement cycle, enabling continuous, real-time monitoring inside the body. This experience reminded me that, just as Newton’s encounter with the apple hinted at gravity, nature still holds powerful lessons for those who pay close attention.”

Getting under the skin

After watching the device work in the lab, the team next wanted to see if the sensors worked in living animals. The researchers built an implantable microdevice with the electrode and sensors inside a thin microneedle, the width of just three human hairs. Resembling a continuous glucose monitor, the device sits on the skin outside the body while the microneedle pricks the skin to sample fluids.

The researchers designed sensors to bind to two protein cytokines, which are key markers of inflammation. Then they attached the device into the skin of rats with diabetes. Because diabetes and inflammation are tightly linked, many complications associated with diabetes are caused by inflammation.

The sensors successfully measured concentration changes of both proteins within fluid. When the rats fasted or received insulin, the sensors tracked cytokine levels as they drifted down. Conversely, when researchers injected the rats with a substance that agitates the immune system, the inflammatory cytokine levels rapidly shot up.

The sensors were so sensitive, in fact, that each time a rat received a shot of insulin, the device detected a small spike in inflammation where the needle pierced the skin. Measurements from the sensors also matched gold-standard laboratory methods to detect proteins in bodily fluids — validating the device’s success.

The ‘ultimate preventative measure’

Although the new device works well for measuring inflammation, Kelley envisions using it to track many other protein markers. She specifically cites heart failure, which is associated with a protein called B-type natriuretic peptide (BNP). Clinicians measure BNP to diagnose and monitor heart failure, but, currently, there is no way to continuously track this marker in real time.

“If you have heart failure, you might go to the doctor every three months,” Kelley said. “But, as with most illnesses, symptoms occur between doctor’s visits. If a patient isn’t feeling well, it’s not immediately obvious that it’s due to heart failure. With a continuous monitor, when the patient doesn’t feel well, the doctor could pull up their data and check their BNP levels. Then, medications could be fine-tuned before symptoms worsen. We hope one day this technology will benefit many people, along the lines of what has happened with the positive impact of continuous glucose monitoring today. It could be the ultimate preventative measure.”

Kelley is co-leader of the Cancer and Physical Sciences Program in the Robert H. Lurie Comprehensive Cancer Center of Northwestern University as well as a member of the International Institute of Nanotechnology and Chemistry of Life Processes Institute.

The study, “Active-reset protein sensors enable continuous in vivo monitoring of inflammation,” was supported by the National Institutes of Health, Canadian Institutes of Health Research, Ontario Genomics, National Institutes of Health Heart Failure, Chan Zuckerberg Biohub Chicago and the Natural Sciences and Engineering Research of Canada.

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