Topology Optimisation for Three-dimensional Periodic Nanophotonic Structures. Three-dimensional dielectric and/or metallic nanophotonic structures are of critical importance to a wide variety of applications ranging from sensing and biomedicine to imaging and information technology. This project aims to establish effective and efficient topology optimisation algorithms for the designs of nanophotonic structures with specific functional properties. The expected outcome will be a new methodology a ....Topology Optimisation for Three-dimensional Periodic Nanophotonic Structures. Three-dimensional dielectric and/or metallic nanophotonic structures are of critical importance to a wide variety of applications ranging from sensing and biomedicine to imaging and information technology. This project aims to establish effective and efficient topology optimisation algorithms for the designs of nanophotonic structures with specific functional properties. The expected outcome will be a new methodology and an advanced design tool for scientists and engineers to create novel nanophotonic structures to improve capabilities in devices such as waveguides, sensors, optical computer chips, superlenses and so on.Read moreRead less
Complement evasion strategies of malaria parasites. Pathogens have evolved to protect themselves from deleterious effects of host immune attack. Malaria is one of the most widespread parasitic diseases, yet evasion strategies employed by these parasites are unknown. This project will aim to understand how malaria parasites exploit the innate immune system for successful human infection.
Explaining the differences in affinity and of carbohydrate binding of the glycogen-sensing enzyme, AMP-protein activated kinase (AMPK). This project will provide fundamental molecular knowledge of how a complex enzyme, AMPK is controlled by the major sugar molecule, glycogen. Our research will increase our understanding of its role in metabolic diseases such as Type 2 diabetes and obesity.
Understanding the role of methionine oxidation in amyloid formation. Amyloid deposition is associated with many debilitating systemic and neurological diseases, including Alzheimer's disease. This project aims to understand the effect of protein oxidation on the process of amyloid fibril formation. This knowledge will assist in the discovery of the triggers of these disorders and may identify methods of combating them.
Structural and functional characterisation of compounds that inhibit the malarial aminopeptidases. Malaria is the world's most prevalent parasitic disease. Due to the rapid spread of drug resistant parasites there is a need to develop new antimalarial drugs. In this proposal we will characterise new targets and novel methods of inhibition that will form the basis of a new mechanism for antimalarial drugs.
Determination of lung morphology from X-ray phase contrast radiographs. Current methods of imaging the lung rely heavily on low contrast images obtained with chest radiography or computed tomography. This research will develop new X-ray phase contrast imaging techniques capable of providing a tenfold contrast increase over conventional chest radiography at a fraction of the X-ray dose of computed tomography. Methods of extracting quantitative information on lung morphology and pathology from pha ....Determination of lung morphology from X-ray phase contrast radiographs. Current methods of imaging the lung rely heavily on low contrast images obtained with chest radiography or computed tomography. This research will develop new X-ray phase contrast imaging techniques capable of providing a tenfold contrast increase over conventional chest radiography at a fraction of the X-ray dose of computed tomography. Methods of extracting quantitative information on lung morphology and pathology from phase contrast chest radiographs will be developed during this research. Eventual outcomes are likely to lead to improved methods of detecting lung disease and injury for both biomedical and clinical studies.Read moreRead less
"Painting" the 3D proteome: folding, conformation and interactions. The project aims to develop a "residue painting approach", employing novel chemical biology reagents and advanced quantitative proteomics, to monitor changes in protein folding, conformations and interactions in cells, in response to stimuli. Proteins direct almost all functions required to sustain life. The project expects to map the dynamic 3D-structures of thousands of proteins that inform the networks they are in, and of the ...."Painting" the 3D proteome: folding, conformation and interactions. The project aims to develop a "residue painting approach", employing novel chemical biology reagents and advanced quantitative proteomics, to monitor changes in protein folding, conformations and interactions in cells, in response to stimuli. Proteins direct almost all functions required to sustain life. The project expects to map the dynamic 3D-structures of thousands of proteins that inform the networks they are in, and of the conformations they adopt. Expected outcomes include the development of novel biotechnology tools for protein structure and function analysis, the illumination of important cell biology pathways underpinning molecular responses to stimuli and stress, and the training of our next generation of scientists.Read moreRead less
The function and misfunction of serum apolipoproteins: lipid binding and protein misfolding. The interaction between proteins and lipids is a fundamental aspect of cellular processes in all organisms. Lipid binding proteins must be structurally dynamic to perform their function, which predisposes them to misfolding and aggregation. This project aims to assess the structural mechanisms of lipid binding by apolipoproteins, and how these proteins balance this function with their propensity to misfo ....The function and misfunction of serum apolipoproteins: lipid binding and protein misfolding. The interaction between proteins and lipids is a fundamental aspect of cellular processes in all organisms. Lipid binding proteins must be structurally dynamic to perform their function, which predisposes them to misfolding and aggregation. This project aims to assess the structural mechanisms of lipid binding by apolipoproteins, and how these proteins balance this function with their propensity to misfold. It will focus on apolipoprotein (apo)A-I as a model serum apolipoprotein that binds lipids and mediates lipid transport in circulation. This project also aims to provide an important new understanding of protein-lipid interactions, the structural mechanisms of apolipoproteins, and the process of misfolding in a diverse range of proteins.Read moreRead less
Engineering new tools to aid structure determination of membrane proteins. This project aims to address the inherent instability of G protein-coupled receptors (GPCRs), which are cell-surface proteins that are a major drug targets. The instability of GPCRs has resulted in a lack of atomic-level structural information that has hindered structure-based drug discovery efforts. This project expects to develop tools to improve GPCR stability and streamline the structure determination process. Project ....Engineering new tools to aid structure determination of membrane proteins. This project aims to address the inherent instability of G protein-coupled receptors (GPCRs), which are cell-surface proteins that are a major drug targets. The instability of GPCRs has resulted in a lack of atomic-level structural information that has hindered structure-based drug discovery efforts. This project expects to develop tools to improve GPCR stability and streamline the structure determination process. Project outcomes are intended to lead to significant advances in membrane protein structure determination and will have a substantial impact on future research in the pharmaceutical industry.Read moreRead less
High-Fidelity Modelling for Robotic-Assisted Minimally Invasive Needle Insertion. This project will develop robotic-assisted needle insertion and greatly improve minimally invasive surgery. It will also enhance the establishment of intellectual property for Australian medicine and produce important benefits to the healthcare sector. The proposed symbiotic integration of the systems will advance modelling technologies, and further create new capabilities for a wide range of science and engineerin ....High-Fidelity Modelling for Robotic-Assisted Minimally Invasive Needle Insertion. This project will develop robotic-assisted needle insertion and greatly improve minimally invasive surgery. It will also enhance the establishment of intellectual property for Australian medicine and produce important benefits to the healthcare sector. The proposed symbiotic integration of the systems will advance modelling technologies, and further create new capabilities for a wide range of science and engineering applications. The established methodologies and systems will also provide great potential benefits in many other areas, including microbiology, life sciences and bio/nano-technology. The project's outcomes will further consolidate Australia's position in innovative technologies and international research and development.Read moreRead less