In bioelectronics breakthrough, scientists create soft, flexible semiconductors
semiconductor

In bioelectronics breakthrough, scientists create soft, flexible semiconductors

‘Let’s change our perspective’

The typical way of making a hydrogel is to take a material, dissolve it in water, and add gelation chemicals to puff the new liquid into a gel form. Some materials simply dissolve in water, others require researchers to tinker and chemically modify the process, but the core mechanism is the same: No water, no hydrogel.

Semiconductors, however, don’t normally dissolve in water. Rather than find new, time-consuming means of trying to force the process, the UChicago PME team re-examined the question.

“We started to think, ‘Okay, let’s change our perspective,’ and we came up with a solvent exchange process,” Dai said.

Instead of dissolving the semiconductors in water, they dissolved them in an organic solvent that is mixable with water. They then prepared a gel from the dissolved semiconductors and hydrogel precursors.

An important benefit of such a solvent-exchange-based method is its broad applicability to different types of polymer semiconductors with different functions.

‘One plus one is greater than two’

The hydrogel semiconductor, which the team has patented and is commercializing through UChicago’s Polsky Center for Entrepreneurship and Innovation, is not merging a semiconductor with a hydrogel. It’s one material that is both semiconductor and hydrogel at the same time.

“It’s just one piece that has both semiconducting properties and hydrogel design, meaning that this whole piece is just like any other hydrogel,” Wang said.


Unlike any other hydrogel, however, the new material actually improved biological functions in two areas, creating better results than either hydrogel or semiconductor could accomplish on their own.

First, having a very soft material bond directly with tissue reduces the immune responses and inflammation typically triggered when a medical device is implanted.

Second, because hydrogels are so porous, the new material enables elevated biosensing response and stronger photo-modulation effects. With biomolecules being able to diffuse into the film to have interactions, the interaction sites for biomarkers-under-detection are significantly increased, which gives rise to higher sensitivity.

Besides sensing, the responses to light for therapeutic functions at tissue surfaces also get increased from the more efficient transport of molecules. This benefits functions such as light-operated pacemakers or wound dressing that can be more efficiently heated with a flick of light to help speed healing.

“It’s a ‘one plus one is greater than two’ kind of combination,” Wang joked.

Citation: “Soft hydrogel semiconductors with augmented biointeractive functions,” Dai et al., Science, October 24, 2024. DOI: 10.1126/science.adp9314

Funding: US National Institutes of Health, US Office of Naval Research, University of Chicago start-up fund

—Adapted from an article first published by Pritzker Molecular Engineering.

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