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The team is looking at more than just flowers for inspiration.

“Inside our joints, there are structures made of cartilage that help cushion heavy impacts and allow us to move with strength and flexibility. These can wear down as we age, leading to pain and even disability.

“We can design hydrogels to support or replace damaged cartilage – giving people back their pain-free movement. Because these gels react to the environment inside the body to transform into their final structure, we can even inject the gels and closely mould them to the bones, ligaments and muscles to provide a better fit than with current surgical options – all without having to pick up a scalpel.”

This could drastically improve the quality of life for the 1.71 billion people globally who suffer from osteoarthitis conditions.

Hydrogels could also be used as a scaffold for the body’s natural healing processes – providing a structure to guide scar tissue growth and speed up recovery from trauma or surgery. The same scaffolds could also be used to support collagen growth and muscle development following reconstructive or cosmetic surgery, helping the body adjust to its new shape faster and with better function.

“We are also investigating using hydrogels to support organoids, which are tissues grown in the lab from a patient’s own cells that could replace the function of a damaged organ.

“By using hydrogels to protect and support these organoids as they become established within the body, and then having the gels dissolve naturally over time, we can begin to explore ways to make transplant procedures more successful and reduce the risk from follow up surgeries to remove stents, stitches or other artificial support structures.”

Associate Professor Müllner’s expertise in nanoscience and polymer development is  world-renowned, and in 2022 caught the attention of Professor Byeong-Su Kim, at Korea’s leading , who proposed a research collaboration to develop hydrogels together.

“I jumped at the opportunity because Yonsei is another leader in polymer development, so this was a great opportunity to learn from their expertise and make use of our combined strengths,” said Associate Professor Müllner.

The University of Sydney has been a strategic partner with Yonsei University for 10 years, funding 25 joint projects supported by the matched funding from both universities. Yonsei University is a global leader in technological innovation with a strong history of successful research collaboration with Sydney.

Professor Byeong-su Kim said: "We greatly appreciate the opportunity to collaborate with Professor Müllner group at the University of Sydney. Their expertise in nanostructured materials complements our strength in the design and synthesis of biocompatible polymer systems. By combining our respective expertise, we believe this partnership will contribute meaningfully to the advancement of next-generation biomedical materials and therapies."

The partnership was supported through a University of Sydney-Yonsei partnership collaboration award in 2022. The award is one of the seed funding programs established by the Office of Global and Research Engagement (OGRE) at the University of Sydney to facilitate and support joint initiatives with partner universities. These programs aim to foster multi-disciplinary, cutting-edge research that generates significant academic and societal impact, and has helped the team secure further grants including the (GSTDF), a highly competitive scheme for international research collaborations.

The Sydney-Yonsei partnership has now expanded to connect academics at QUT and UNSW, and Brisbane-based biomedical company  to further develop the team's findings.

“The hydrogel scaffolds we’re producing will be adjustable to match the different use cases we’ve explored – meaning they can be rigid if needed or bend, flex and compress to match what the body is doing around the hydrogel, all while delivering medications and supporting healing.”

“While we’re still a few years off a commercial product, the materials we create in this project will be designed to be compatible with 3D printing applications – an emerging way of creating new materials to produce structures that are impossible to achieve using current industrial processes. This flexible and scalable method of manufacturing opens up a whole new world of being able to get medical devices to people in need around the world and at unprecedented scale.”