Modifying and Improving Porous Sol-Gel Materials for Water Purification. XeroCoat is commercialising nanotechnology research out of UQ's Physics department. XeroCoat has received much local and international interest in its signature product 'XeroCoat'. The company is rapidly expanding and has established new research facilities with production facilities to be set-up. This will result in high technology, employment growth for Australia. Links with Flinders could see expansion into SA. The c ....Modifying and Improving Porous Sol-Gel Materials for Water Purification. XeroCoat is commercialising nanotechnology research out of UQ's Physics department. XeroCoat has received much local and international interest in its signature product 'XeroCoat'. The company is rapidly expanding and has established new research facilities with production facilities to be set-up. This will result in high technology, employment growth for Australia. Links with Flinders could see expansion into SA. The company operates in 'Sol-Gel' nanotechnology, which has huge global, academic and commercial interest. However in Australia this technology has only been serviced by Flinders, ANSTO and ANSTO's spin-out company Ceramisphere. The project will help to build a new Australian high tech industry in sol-gel nanotechnology.Read moreRead less
Revealing molecular detail of DNA triplexes to underpin antigene technology. Variations from the classic DNA double helix structure are proposed to play key roles in a range of cellular processes, particularly gene regulation. However, the biological function and therapeutic potential of these unusual DNA structures are poorly explored, since the fundamental molecular details which govern their formation and interactions with cellular machinery are not well described. This project aims to develo ....Revealing molecular detail of DNA triplexes to underpin antigene technology. Variations from the classic DNA double helix structure are proposed to play key roles in a range of cellular processes, particularly gene regulation. However, the biological function and therapeutic potential of these unusual DNA structures are poorly explored, since the fundamental molecular details which govern their formation and interactions with cellular machinery are not well described. This project aims to develop innovative methods to investigate, and importantly modulate, DNA and RNA triple helix assembly, specificity and molecular interactions. Resulting insights will underpin novel approaches to gene regulation, principally in the context of designing new antibacterial agents to address the antibacterial resistance problem.Read moreRead less
Mass spectrometry to reveal the role of lipids in protein misfolding. This project aims to develop an integrated mass spectrometry-based approach to determine structures and dynamics of membrane associated proteins, and discover how lipids cause protein misfolding implicated in neurodegeneration. Lipid membranes may influence protein (mis)folding, aggregation and related toxicity. However, the complex and dynamic nature of the lipid-protein interactions involved means traditional methods cannot ....Mass spectrometry to reveal the role of lipids in protein misfolding. This project aims to develop an integrated mass spectrometry-based approach to determine structures and dynamics of membrane associated proteins, and discover how lipids cause protein misfolding implicated in neurodegeneration. Lipid membranes may influence protein (mis)folding, aggregation and related toxicity. However, the complex and dynamic nature of the lipid-protein interactions involved means traditional methods cannot easily characterise them, and they are poorly understood at a molecular level. The project expects to develop tools to bridge a critical gap in structural biology, while understanding lipid-protein interactions could lead to new therapies. This will ultimately provide benefits such as reduced health costs and better health outcomes.Read moreRead less