Structure and metabolism of bioactive carbohydrates from brown algae. Brown algae produce a diversity of species-specific carbohydrates in their cell walls that exhibit a variety of biological activities that can be exploited for the development of functional food and biopharmaceutical formulations. However, the metabolic pathways responsible for the biosynthesis of these carbohydrates are poorly characterised. This multidisciplinary project aims to understand the molecular events that control t ....Structure and metabolism of bioactive carbohydrates from brown algae. Brown algae produce a diversity of species-specific carbohydrates in their cell walls that exhibit a variety of biological activities that can be exploited for the development of functional food and biopharmaceutical formulations. However, the metabolic pathways responsible for the biosynthesis of these carbohydrates are poorly characterised. This multidisciplinary project aims to understand the molecular events that control the structure and metabolism of bioactive carbohydrates in the prominent Australian brown alga Ecklonia radiata, with particular focus on alginates and fucoidans. This knowledge will be used to produce in yeast bioactive oligosaccharides that are of high commercial interest to the biopharmaceutical industry.Read moreRead less
Characterization of bioadhesives from marine diatom slimes and their interactions with different substrata; developing environmentally friendly, foul-release coatings. This project represents a collaborative effort between Melbourne University, the Department of Defense and Akzo Nobel to develop new, environmentally friendly strategies to modify and/or prevent marine slime adhesion in anti-foul coatings or paint. Fouling by diatom slimes occurs at great expense to industry and the Australian N ....Characterization of bioadhesives from marine diatom slimes and their interactions with different substrata; developing environmentally friendly, foul-release coatings. This project represents a collaborative effort between Melbourne University, the Department of Defense and Akzo Nobel to develop new, environmentally friendly strategies to modify and/or prevent marine slime adhesion in anti-foul coatings or paint. Fouling by diatom slimes occurs at great expense to industry and the Australian Navy, adding up to 60% annually to the cost of propulsive fuel consumption in shipping. We will characterize the chemical and physical properties of the slime adhesives in order to understand how organisms control adhesion, and use these principles to develop new technology, anti-foul paints.Read moreRead less