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Sunday, 25 October 2020
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Raw materials & technologies, Technologies

Electric impulse releases adhesive force: Novel smart underwater adhesive

Monday, 28 September 2020

With a small zap of electricity, biomedical engineers at Michigan Technological University take an underwater smart glue prototype from sticky to not in seven seconds.

Scientists have developed a smart underwater smart glue. Image source: Pexels - Pixabay (symbol image).

Scientists have developed a smart underwater smart glue. Image source: Pexels - Pixabay (symbol image).

Turning adhesion on and off is what makes a glue smart. It’s one thing to do this in the open air and quite another under water. Inspired by nature, catechols are synthetic compounds that mimic the wet-but-still-sticky proteins secreted by mussels and offer promise for smart adhesives that work in water. The technology could help with underwater glue, wound dressings, prosthetic attachments or even making car parts and in other manufacturing.

Bruce Lee, associate professor of biomedical engineering at Michigan Tech, is a part of the Office of Naval Research’s (ONR) Young Investigator Program (YIP) and showed how to use pH to make smart underwater adhesives. Along with doctoral researcher Saleh Akram Bhuiyan, Lee developed a new method using an electrical current to turn off the adhesion of a catechol-containing material.

The team’s findings detailed the stickiest part of the process — creating a repeatable contact mechanics test that can measure adhesion before and after a jolt of electricity.  
"A lot of people have been using catechol to mimic mussels and their adhesive proteins, but applying electricity to deactivate it is new,” Lee said. "It’s more convenient than using pH like what we were using before and it should be easier to integrate with electronic devices, which means detaching could be automated and could be as simple as pushing a button.”

Catechols for Smart Glue

Bhuiyan developed a setup that uses a titanium sphere and a platinum wire electrode to apply electrical stimulation to the adhesive that is in contact with the sphere in the presence of salty water. This method makes it easy to control the voltage applied through the wire, glue and sphere as well as how salty the water is around them. The amount of time the current runs is also important. With more time, voltage and salt, the more the catechol adhesives gets oxidized and the less adhesive it becomes. With strong enough voltage, the glue detaches in only seven seconds.

"The novelty is application of the electricity and the short amount of time it takes to detach,” Bhuiyan said. "What I find most unusual about the experiment is the colour change. It starts white and when I apply the electricity and the material is deactivated, it oxidizes and turns a red colour — and we really like to see that red colour.”

The next step in the research will be taking that red and trying to turn it back into white. The hallmark of a smart glue is not only deactivating adhesion, but turning it back on. Lee and doctoral graduate Ameya Narkar were able to accomplish this feat by playing with pH, which earned them the Bhakta Rath Research Award, and Bhuiyan hopes to apply the lessons from that research to using electrical current.

From painless bandages to underwater glue, from automotive gear to prosthetic limbs, catechol-containing adhesives are versatile and promising materials.

The study has been published in Journal of the American Chemical Society, 2020, 142, 10.

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