Squishy-yet-strong hydrogels are invaluable for making medical devices, tissue engineering scaffolds, and sensors. Being mostly water, though, they freeze and become useless in subzero temperatures. But now, researchers have made a freezable hydrogel that boasts high strength, moldability, adhesiveness, and self-healing powers. The new hydrogel stays stretchy down to –80°C and is stronger than most […]
Squishy-yet-strong hydrogels are invaluable for making medical devices, tissue engineering scaffolds, and sensors. Being mostly water, though, they freeze and become useless in subzero temperatures. But now, researchers have made a freezable hydrogel that boasts high strength, moldability, adhesiveness, and self-healing powers.
The new hydrogel stays stretchy down to –80°C and is stronger than most other synthetic and natural polymer-based gels, says Junjie Li, a chemical engineer at Tianjin University. Its combination of mechanical properties should open up applications in flexible energy-storage devices, soft electronics, and wearable devices designed for subzero conditions. The hydrogels could also be used to protect cells, tissues, and organs stored at cryogenic temperatures from cold damage.
Credit: ACS Appl. Mater. Interfaces The hydrogel heals itself when heated and pressed together.
Hydrogels are three-dimensional networks of cross-linked polymer chains dispersed in water. When frozen, hydrogels lose their elasticity and become brittle. To make a freeze-tolerant hydrogel, Li, Fanglian Yao of Tianjin University, and their colleagues replaced part of the water in their gelatin-based hydrogel with glycerol. The simple one-step synthesis involves soaking a gelatin hydrogel precursor in a water-glycerol solution containing sodium citrate for 3 h.
“Glycerol forms hydrogen bonds with water molecules, which can effectively prevent freezing of water at subzero temperatures,” Yao says. The strength of the gel comes from hydrogen bonds between the gelatin chains and glycerol and from ionic interactions between the ammonium groups in gelatin and the citrate ions. The gelatin chains also easily intertwine and untwine, making the gel moldable and healable.
To show off the hydrogel’s properties, the researchers formed it into various shapes and stretched it to at least five times its original length at room temperature. It remained transparent and the researchers could still stretch and twist it after freezing to –80°C for three days, whereas a traditional hydrogel shrunk and became brittle and opaque under the same treatment.
When the researchers pressed two pieces of their hydrogel together and heated it for a half hour, the pieces fused into one that retained about half of the material’s original strength. And when warmed and pressed against metal, glass, and plastic, the gel stuck fast, without any glue.
Others have added salt to hydrogels to make them freeze tolerant. But those previous hydrogels have not been strong or have required sophisticated manufacturing techniques, Li says.
The gel’s outstanding properties and easy production method should make it important for practical applications, says Mingjie Liu, a chemist at Beihang University. The only downside he sees is that the results might not work with other hydrogel chemistries. “The mechanical strength enhancement based on the introducing of citrate might not work for all hydrogels or polymers,” he says.
This article is reproduced with permission from C&EN (© American Chemical Society). The article was first published on June 26, 2019.