Prof. Swee Hin Teoh | Biomedical Engineering | Innovation Award

Hunan University, Changsha | China

Professor Swee Hin Teoh is an eminent materials and bioengineering scientist recognized for his pioneering contributions to biomaterials and tissue engineering. He earned his BEng (First Class Honours) and Ph.D. in Materials Engineering from Monash University, Australia. With an illustrious academic career spanning over four decades, he has served at Monash University, the National University of Singapore (NUS), and Nanyang Technological University (NTU), holding leadership roles such as Director of the Centre for Biomedical Materials Applications and Technology, Chair of the School of Chemical and Biomedical Engineering, and President’s Chair Professor at NTU. His research focuses on biomaterials, biodegradable scaffolds, and bone tissue engineering, leading to FDA-approved innovations successfully commercialized through Osteopore International. His scholarly excellence is reflected through numerous awards, including the Prestigious Engineering Achievement Award, Gold Asian Innovation Award, and the Distinguished Changjiang Chair Professorship. A Fellow of the Academy of Engineering Singapore and the Institute of Engineers Singapore, Prof. Teoh has also contributed extensively to scientific publications and editorial boards. His career embodies academic excellence, translational innovation, and mentorship in advancing biomedical engineering and regenerative medicine worldwide.

Profile: Orcid

Featured Publications

Quek, J., Vizetto-Duarte, C., Ng, K. W., Teoh, S. H., Choo, Y., & Shields Bahney, C. (2025). Fully defined 3D hybrid system for bone tissue engineering: Integration of MeHA–RGD/PCL–TCP scaffolds with human stem cells via 3D‐printed vacuum‐assisted cell loading device. Journal of Tissue Engineering and Regenerative Medicine.

Le Ferrand, H., Goh, B. T., & Teoh, S. H. (2024). Nacre-like ceramic composites: Properties, functions and fabrication in the context of dental restorations. Acta Biomaterialia.

Herath, T. D. K., Saigo, L., Schaller, B., Larbi, A., Teoh, S. H., Kirkpatrick, C. J., & Goh, B. T. (2021). In vivo efficacy of neutrophil-mediated bone regeneration using a rabbit calvarial defect model. International Journal of Molecular Sciences.

Dee, P., You, H. Y., Teoh, S.-H., & Le Ferrand, H. (2020). Bioinspired approaches to toughen calcium phosphate-based ceramics for bone repair. Journal of the Mechanical Behavior of Biomedical Materials.

Prof. Inho Bae | Biomaterials | Best Researcher Award

Chosun University | South Korea

Dr. Inho Bae is a distinguished Research Professor at Chosun University, renowned for his pioneering work in biomedical materials and cardiovascular stent technology. He earned his advanced degrees in materials science and biomedical engineering, building a strong foundation for his career in medical device innovation. Over the years, Dr. Bae has gained extensive research and academic experience, contributing significantly to the fields of biomaterials, polymer science, and cardiovascular therapeutics. His research focuses on developing advanced stent designs, drug delivery systems, and surface modification techniques to enhance anti-thrombogenicity and endothelialization. He has also led studies on polymer-free and biodegradable coating technologies, aiming to improve stent performance and patient safety through translational applications. His work bridges fundamental science with clinical impact, making meaningful advancements in biomedical engineering and healthcare innovation. Recognized for his achievements, Dr. Bae has received multiple honors including the Excellence in Biomedical Research Award, Patent Commercialization Award, Innovative Researcher Award, and Technology Transfer Achievement Award. His dedication to translational research and interdisciplinary collaboration continues to advance medical technology, shaping the future of cardiovascular treatment and biomaterials science.

Featured Publication

Drug release control and anti-inflammatory effect of biodegradable polymer surface modified by gas phase chemical functional reaction, Biomedical Materials (Bristol).