Professor DEREK IRVINE's Outputs (2)

Fungal Attachment-Resistant Polymers for the Additive Manufacture of Medical Devices (2024)
Journal Article
Yong, L. X., Sefton, J., Vallières, C., Rance, G. A., Hill, J., Cuzzucoli Crucitti, V., Dundas, A. A., Rose, F. R., Alexander, M. R., Wildman, R., He, Y., Avery, S. V., & Irvine, D. J. (2024). Fungal Attachment-Resistant Polymers for the Additive Manufacture of Medical Devices. ACS Applied Materials and Interfaces, 16(40), 54508–54519. https://doi.org/10.1021/acsami.4c04833

This study reports the development of the first copolymer material that (i) is resistant to fungal attachment and hence biofilm formation, (ii) operates via a nonkilling mechanism, i.e., avoids the use of antifungal actives and the emergence of funga... Read More about Fungal Attachment-Resistant Polymers for the Additive Manufacture of Medical Devices.

Polymer-Coated Urinary Catheter Reduces Biofilm Formation and Biomineralization: A First-in-Man, Prospective Pilot Study (2024)
Journal Article
Kalenderski, K., Dubern, J.-F., Lewis-Lloyd, C., Jeffery, N., Heeb, S., Irvine, D. J., Sloan, T. J., Birch, B., Andrich, D., Humes, D., Alexander, M. R., & Williams, P. (2024). Polymer-Coated Urinary Catheter Reduces Biofilm Formation and Biomineralization: A First-in-Man, Prospective Pilot Study. Journal of Urology Open PLus, 2(1), Article e00005. https://doi.org/10.1097/JU9.0000000000000097

Purpose: Biofilm formation and biomineralization on urinary catheters may cause severe complications including infection and obstruction. Here, we describe an in vitro evaluation and prospective pilot clinical study of a silicone catheter coated with... Read More about Polymer-Coated Urinary Catheter Reduces Biofilm Formation and Biomineralization: A First-in-Man, Prospective Pilot Study.