Understanding glycopolymer interactions with the extracellular matrix. This project aims to advance knowledge of the biochemical and biophysical structure of the endothelial glycocalyx, a dynamic cell surface extracellular matrix rich in proteoglycans and glycosaminoglycans. It will be the first to explore how charged glycopolymers interact with this dynamic interface with the goal to develop a model of the glycocalyx lifecycle. This project is expected to enable the transfer of skills, knowledg ....Understanding glycopolymer interactions with the extracellular matrix. This project aims to advance knowledge of the biochemical and biophysical structure of the endothelial glycocalyx, a dynamic cell surface extracellular matrix rich in proteoglycans and glycosaminoglycans. It will be the first to explore how charged glycopolymers interact with this dynamic interface with the goal to develop a model of the glycocalyx lifecycle. This project is expected to enable the transfer of skills, knowledge and ideas as well as advanced research and industrial training for young scientists. Knowledge derived from this project is expected to enable future innovation in molecules with tailored interactions with the glycocalyx with significant benefits for researchers, manufacturers and end users. Read moreRead less
Nanoengineering of Biomaterial Surfaces to Tailor Innate Immune Responses. The overarching aim of this project is to provide a mechanistic understanding of how surface nanotopography affects inflammatory responses. Recently, we showed that surface nanotopography induced conformational changes in adsorbed proteins can activate or deactivate immune cells. These exciting findings are important because they show that it may be possible to engineer the nanotopography of a biomedical device surface in ....Nanoengineering of Biomaterial Surfaces to Tailor Innate Immune Responses. The overarching aim of this project is to provide a mechanistic understanding of how surface nanotopography affects inflammatory responses. Recently, we showed that surface nanotopography induced conformational changes in adsorbed proteins can activate or deactivate immune cells. These exciting findings are important because they show that it may be possible to engineer the nanotopography of a biomedical device surface in a manner which leads to a desired and predictable level of inflammation. The outcomes of the project will create new fundamental knowledge that in the future can instruct the development of the next generation of biomaterials capable of controlling and directing the body’s inflammatory responses.Read moreRead less
Engineering biomaterials that actively promote blood vessel growth. This project aims to improve understanding of the effect of biomaterials on vascular growth & to develop new biomimetic materials using natural polymers silk & gelatin. It expects to generate new knowledge in biomaterials, matrix biology & advanced material processing. Expected outcomes include new knowledge & technological advances in biomaterial-driven vascular growth, porous material manufacture, & proteoglycan-mediated grow ....Engineering biomaterials that actively promote blood vessel growth. This project aims to improve understanding of the effect of biomaterials on vascular growth & to develop new biomimetic materials using natural polymers silk & gelatin. It expects to generate new knowledge in biomaterials, matrix biology & advanced material processing. Expected outcomes include new knowledge & technological advances in biomaterial-driven vascular growth, porous material manufacture, & proteoglycan-mediated growth factor signalling, as well as cross-disciplinary, international collaboration & research training. This should provide significant benefit to Australia’s scholarly output & reputation & long term benefits to biomedical, veterinary, cosmetic, & food industries through new materials & processing technologies. Read moreRead less