Researchers have been trying to develop a practical way to use microneedles — tiny needles less than 1 mm in length — for routine at-home medical monitoring. Microneedles are so short that they stay within the skin and do not make contact with any neurons, meaning that they cause no pain. Rather than extracting blood, they draw up fluid in the skin that contains most of the important biomarkers that blood tests look for. Several types of microneedles exist but until now, making a practical device that quickly analyzes the fluid has proved elusive.

Researchers have developed a way to combine porous microneedles with paper-based sensors to create low-cost, disposable patches for diagnosing conditions such as pre-diabetes. To make the patch, the researchers first made the microneedles by pouring a melted mixture of a biodegradable polymer and salt into the cone-shaped cavities of a micromold while applying heat. Then they flipped the mold and needles upside down and placed them on top of a piece of paper, this time applying high pressure from above. The high pressure forced the mixture into the pores of the paper, securing the attachment and allowing fluid drawn through the needles to pass effortlessly into the paper.

After removal from the mold, the needles were cooled in a solution that sucked out all the salt, leaving behind thousands of holes, or pores, that the fluid flows through on its way to the paper. The salt concentration was a key factor; the team tested several concentrations of salt to determine how porous the microneedles should be. To finish the patch, they used double-sided tape to attach a paper glucose sensor onto the paper base of the needle array.

The team tested the patch on an agarose gel in which glucose had been dissolved. Fluid from the gel flowed from the gel into the porous microneedles and from there into the paper and the sensor layer. The glucose concentration was accurately recorded as color changes in the paper.

The patches are disposable, biodegradable, and using them does not require any medical expertise or training. They are also biocompatible, meaning that there is no problem if any remain in the skin when the patch is removed. The sensor can vary depending on the biomarker to be monitored.

For more information, contact Professor Beomjoon Kim at This email address is being protected from spambots. You need JavaScript enabled to view it..


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This article first appeared in the January, 2021 issue of Tech Briefs Magazine.

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