Tag Archives: Yixun Cheng

Turning marine waste into medical applications

Leave a reply

This 2025 Research Story on the Natural Sciences and Engineering Research Council of Canada website describes work from McGill University to turn marine waste into a bioadhesive, Note: A link has been removed,

An interdisciplinary team of researchers at McGill University has developed an ultra-strong, environmentally friendly medical glue, or bioadhesive, made from marine waste. The discovery has promising applications for wound care, surgeries, drug delivery, wearable devices and medical implants.

“A glue that can close wounds or make something strongly adhere to the skin is critical for many medical interventions,” says Audrey Moores, a chemistry professor at McGill.

A July 31, 2025 McGill University news release, which originated the research story, has more detail to offer, Note: Links have been removed,

“Many existing bioadhesive products are based on toxic compounds, while overall, there is a need to explore new materials that demonstrate both high adhesion and strong fatigue resistance, or the ability to hold even if pulled apart repeatedly,” Moores said.  
 
Moore [sic] and main co-author Jianyu Li, Associate Professor, Department of Mechanical Engineering and Canada Research Chair in Tissue Repair and Regeneration reported their findings in “Nanowhisker glues for fatigue-resistant bioadhesion and interfacial functionalization,” published in Nature Communications.  

Naturally sourced nanowhiskers give the glue its strength 

The new bioadhesive is composed of chitosan, a chemically modified form of chitin, the natural building block found in the exoskeletons of shellfish and certain fungi. 

The researchers modified the chitosan to have a nanowhisker shape – a feature that proved to be essential to the bioadhesive’s effectiveness – using a mechanochemical process pioneered by co-authors Moores and Edmond Lam in previous studies.   

 “We chemically manipulate this material to turn it into nanochitosan, which has a range of different properties we can finetune. Using this nanomaterial, we can make nanoglue,” Moores said. 

Ultrasound turns whiskers into interlocking structures 

To apply the nanoglue, researchers use a unique ultrasound technology developed by the Li group to penetrate the skin.  When exposed to sound waves, the nanowhiskers not only adhere firmly to skin but also interlock into a rigid, resilient scaffolding that drastically enhances the glue’s strength and durability. 

“Imagine you have a Band-Aid on your hand. It’s difficult to get it to stay, because your hand moves a lot,” Moores explained.  

“To get it to stick, you need the skin to be permeable to the glue. We used microneedles or ultrasound for that. 

 “We were surprised to see that ultrasound was critical to making a strong glue. While our initial strategy was to get the nanoglue to stick to the skin, we also discovered ultrasounds helped build a complex, interconnected network of our nanostructures. These nanowhisker glues are simply better than the current glues out there.”  

They say the nanostructure has promising applications beyond health care, in many engineering contexts. 

Allergy-safe, and potentially vegan 

The bioadhesive is also fully biocompatible, even for people with seafood allergies. 

“People who are allergic to shellfish are not allergic to chitin, but the proteins. We can remove these in the manufacturing process and avoid allergic reactions.  
 
“We could also theoretically make a vegan version from fungi,” Moores added. 

This research was funded by the Natural Sciences and Engineering Research Council of Canada, the National Research Council Ocean program, the Canada Foundation for Innovation and the National Institutes of Health of the United States, the Canada Research Chairs Program, the Fonds de Recherche du Québec Nature et Technologies (FRQNT) – Centre for Green Chemistry and Catalysis and McGill University.

For those who like to listen to their science news, the Canadian Broadcasting Corporation (CBC) has an 8 mins. 8 secs. radio segment where researcher Audrey Moores is interviewed by Angelica Montgomery. on Quebec AM.

Here’s a link to and a citation for the paper,

Nanowhisker glues for fatigue-resistant bioadhesion and interfacial functionalization by Shuaibing Jiang, Tony Jin, Tianqin Ning, Zhen Yang, Zhenwei Ma, Ran Huo, Yixun Cheng, Davis Kurdyla, Edmond Lam, Rong Long, Audrey Moores & Jianyu Li. Nature Communications volume 16, Article number: 6826 (2025) DOI: https://doi.org/10.1038/s41467-025-62019-y Published: 24 July 2025

This paper is open access.

Safer, greener way to make hydrogels? Try ultrasound

Leave a reply

A May 9, 2025 news item on ScienceDaily announces research from McGill University (Montréal, Québec) and Polytechnique Montréal,

Researchers at McGill University, in collaboration with Polytechnique Montréal, pioneered a new way to create hydrogels using ultrasound, eliminating the need for toxic chemical initiators. This breakthrough offers a faster, cleaner and more sustainable approach to hydrogel fabrication, and produces hydrogels that are stronger, more flexible and highly resistant to freezing and dehydration. The new method also promises to facilitate advances in tissue engineering, bioadhesives and 3D bioprinting

Hydrogels are gels composed of polymers that can absorb and retain large amounts of water. They are widely used in wound dressings, drug delivery, tissue engineering, soft robotics, soft contact lenses and more.

A May 8, 2025 McGill University news release (also on EurekAlert but published on May 9, 2025), which originated the news item, provides more details about the work,

Gel formation within minutes

Traditional hydrogel manufacturing relies on chemical initiators, some of which can be harmful, particularly in medical applications. Initiators are the chemicals used to trigger chemical chain reactions. The McGill research team, led by Mechanical Engineering Professor Jianyu Li, has developed an alternative method using ultrasound. When applied to a liquid precursor, sound waves create microscopic bubbles that collapse with immense energy, triggering gel formation within minutes. 

“The problem we aimed to solve was the reliance on toxic chemical initiators,” said Li. “Our method eliminates these substances, making the process safer for the body and better for the environment.” 

This ultrasound-driven technique is dubbed “sonogel.”

“Typical hydrogel synthesis can take hours or even overnight under UV light,” said Li. “With ultrasound, it happens in just five minutes.” 

Revolutionizing biomedical applications

One of the most exciting possibilities for this technology is in non-invasive medical treatments. Because ultrasound waves can penetrate deep into tissues, this method could enable in-body hydrogel formation without surgery.  

“Imagine injecting a liquid precursor and using ultrasound to solidify it precisely where needed,” said Li. “This could be a game-changer for treating tissue damage and regenerative medicine. Further refinement, we can unlock new possibilities for safer, greener material production.” 

The technique also opens the door to ultrasound-based 3D bioprinting. Instead of relying on light or heat, researchers could use sound waves to precisely “print” hydrogel structures.  

“By leveraging high-intensity focused ultrasound, we can shape and build hydrogels with remarkable precision,” said Jean Provost, one of co-authors of the study and assistant professor of engineering physics at Polytechnique Montréal.  

Here’s a link to and a citation for the paper,

Ultrasound Cavitation Enables Rapid, Initiator-Free Fabrication of Tough Anti-Freezing Hydrogels by Yixun Cheng, Stephen Lee, Yihang Xiao, Shou Ohmura, Louis-Jacques Bourdages, Justin Puma, Zixin He, Zhen Yang, Jeremy Brown, Jean Provost, Jianyu Li. Advanced Science Volume 12, Issue 22 June 12, 2025 2416844 DOI: https://doi.org/10.1002/advs.202416844 First published online: 17 April 2025

This paper is open access.