Latest news with #JonathanBarnes
Scientific American
2 days ago
- Science
- Scientific American
Nature-Inspired Gel Explains Why This Duck Is Stuck
On the shores of a beach in northern Japan, waves pummel a rubber duck stubbornly stuck to a rock. Thanks to a new supersticky hydrogel lining its base, the toy won't budge. Hydrogels are soft, jellylike materials used in many fields. In medicine, they can dress wounds and deliver drugs. In agriculture, they can help soil hold more water. But making substances sticky is tough—and underwater, it's even tougher. The glues typically don't hold well under a wet and salty surf. Nature, however, has a solution. Creatures such as barnacles and mussels naturally produce proteins that let them stick to wet surfaces. Inspired by these adhesive abilities, researchers combed through catalogs of these animals' protein structures to mimic their stickiest features. Then, the scientists incorporated these protein structures into the hydrogels and tested them. After running several experiments, the team fed the results to a machine-learning system so that it could design a hydrogel with even stronger glue. The system came up with three superadhesive designs, composed of different protein structures, which the researchers described this week in Nature. On supporting science journalism If you're enjoying this article, consider supporting our award-winning journalism by subscribing. By purchasing a subscription you are helping to ensure the future of impactful stories about the discoveries and ideas shaping our world today. Jonathan Barnes, a polymer scientist at Washington University in St. Louis, who was not involved in the study, was impressed by the sheer strength of the enhanced hydrogels. In one experiment, the researchers used one of the gels to glue together pairs of plates made of one of three different materials—ceramic, glass and titanium—in a tank of saline. Each glued pair had a kilogram-mass load suspended below it. The gel held on for more than a year. 'To last for a year is incredible,' Barnes says. All three of the artificial-intelligence-designed hydrogels showed similar strength in artificial seawater. But one outperformed the others when tested in deionized water, which is devoid of charge and not found in nature. The differences in strength show that some adhesive materials may be more equipped for specific environments than others. 'We are now working to tune this difference and test them in different conditions,' says study co-author Jian Ping Gong, a polymer scientist at Hokkaido University in Japan. 'We also want to improve and [find] other formulations that can work on metal, for example.' After synthesizing the ultrasticky gels, the scientists took two of them into the field to test their real-world capabilities. The researchers used one gel to seal a hole at the base of a three-meter-long pipe that was filled with tap water to simulate a high-pressure water leak. And they used the other to affix a rubber duck onto a rock to see how well the technology fared in seawater. One day these gels could help researchers develop artificial skin or repair underwater and offshore structures. '[The study] points to tougher, faster and more reliable wet adhesives—for medical sealing, marine infrastructure and emergency repairs,' says Ximin He, a materials scientist who studies biologically inspired materials at the University of California, Los Angeles, and was not involved in the paper. 'The data‑driven playbook they use could shorten the path from idea to material across many applications that affect daily life.'
BBC News
16-05-2025
- Health
- BBC News
Hereford eye care centre opens in supermarket car park
An eye care centre has opened in a supermarket car park, offering treatment in as little as four said the facility, alongside the ASDA on Belmont Road in Hereford, "will support an estimated 21,000 residents in Herefordshire who are currently living with common eye-related conditions".The company, which is an independent provider of NHS ophthalmology services, said it would also offer patients a transport service to get to said setting up a care centre in portable buildings avoided "the high cost and inflexibility of permanent hospital builds". The total size of the facility is 3,200 sq ft (297.2 sq m), which is equivalent to around six swimming Barnes, who will run the centre, said: "With over a quarter of Herefordshire residents aged over 65, accessible eye care is crucial."He said the aim was to give patients access to "essential treatments close to home, minimising disruption and maximising convenience". Follow BBC Hereford & Worcester on BBC Sounds, Facebook, X and Instagram.
