Information theoretic approaches to optimise genome wide association studies with application to continuous and discrete traits. This project aims to develop new mathematical methods to find genetic associations from new genome-wide studies of colorectal cancer and breast cancer risk factors. If successful, this will result in improved use of expensive genetic data to better predict and understand diseases, conditions and other characteristics for humans, animals and plants.
Concepts towards the next generation of dye-sensitised solar cells: tandem and plasmonic solar cells. This project aims at exploring the feasibility of novel device concepts to enhance the performance of dye-sensitised solar cells. These concepts include tandem solar cells as well as novel energy relay systems based on the ability of nanoparticles to effectively act as antenna systems that can funnel energy towards a sensitising dye molecule.
Novel fuel-cell structures based on electroactive polymers. This project will tackle some of the challenges currently hindering progression of our society into a post-petroleum era via materials developments that will lead to in-expensive, more efficient fuel cell technologies. Specifically, a new class of organic catalysts and novel ion conducting membranes will be integrated into functional fuel-cells.
Detection of infrared-biomarkers for the diagnosis and treatment of canine neoplasia. This research hopes to discover infrared-biomarkers for canine cancers using synchrotron infrared and laser light. Many dog cancers are similar to human cancers so cancerous tissues and cells from dogs make excellent models for human cancer research. This project will provide new insights and technological approaches to cancer diagnosis and treatment.
Engineering the Microstructure of Electrodes for Advanced Fuel Cells. A polymer solution-based integration technique is proposed to be developed to fabricate polymer electrolyte membrane fuel cells, allowing for effective engineering of the porous networks and interfaces within electrodes and cells. This novel systems materials engineering approach is expected to overcome the drawbacks of the conventional hot pressing method, enabling precise integration of nanostructured electrodes and membrane ....Engineering the Microstructure of Electrodes for Advanced Fuel Cells. A polymer solution-based integration technique is proposed to be developed to fabricate polymer electrolyte membrane fuel cells, allowing for effective engineering of the porous networks and interfaces within electrodes and cells. This novel systems materials engineering approach is expected to overcome the drawbacks of the conventional hot pressing method, enabling precise integration of nanostructured electrodes and membrane into high-performance, flexible fuel cells. The outcomes of this research aim to provide a unique opportunity for Australia to become a world leader in the rapidly-emerging clean energy technology, and critical manufacturing of new energy generation systems for domestic uses and exports, thereby producing important economic benefits.Read moreRead less
Dynamic Microcages for Cells: Advanced Tools to Interrogate Cell Mechanics. This project aims to develop a suite of movable micro/nanostructures with integrated mechanical and biological sensors, which will be interfaced with cells to investigate how those cells respond to their surrounding physical environment. Expected outcomes are new technologies in micro/nanofabrication, sensing, and advanced imaging, and deep understanding of the biological processes that control tissue formation and repai ....Dynamic Microcages for Cells: Advanced Tools to Interrogate Cell Mechanics. This project aims to develop a suite of movable micro/nanostructures with integrated mechanical and biological sensors, which will be interfaced with cells to investigate how those cells respond to their surrounding physical environment. Expected outcomes are new technologies in micro/nanofabrication, sensing, and advanced imaging, and deep understanding of the biological processes that control tissue formation and repair. These outcomes would impact how 3D microsystems are developed and applied, informing the design of advanced in-vitro cell culture systems. Significant benefits are expected in 3D nano-microengineering, and in generating new knowledge underpinning future advances in stem cell and tissue engineering technologies.Read moreRead less
Examining the relationship between error processing, cognitive control and emotion: a cognitive neuroscience approach. The proposed research aims to contribute to current scientific thinking on how the processing of errors influences self-monitoring and cognitive performance. The ability to monitor one's cognitive performance deteriorates with normal ageing, and is particularly affected in a range of clinical conditions, where it is a reliable predictor of a poor prognostic outcome. This project ....Examining the relationship between error processing, cognitive control and emotion: a cognitive neuroscience approach. The proposed research aims to contribute to current scientific thinking on how the processing of errors influences self-monitoring and cognitive performance. The ability to monitor one's cognitive performance deteriorates with normal ageing, and is particularly affected in a range of clinical conditions, where it is a reliable predictor of a poor prognostic outcome. This project aims to clarify understanding of the cognitive and neural processes underlying self-monitoring, as an important first step to improving rehabilitation and management methods for age-related impairments such as Alzheimer's disease, and prominent mental health conditions such as schizophrenia.Read moreRead less
Probing membrane rafts using surface-selective multi-dimensional microscopy. The results of this project will provide fundamental insights into the role played by domains in cell membranes in the regulation of membrane protein function. These insights will create new avenues in the biotechnology industry for development of novel therapeutics aimed at disruption of membrane protein-protein interactions that cause aberant cell signalling in disease states such as cancer.
Photoreversible hydrogels to study stem cell memory and fate. This project will develop materials whose stiffness can be reversibly increased and decreased by the simple application of light, and use these to build knowledge of how stem cell fate is regulated. The influence of mechanical cues on the structure and organisation of the nucleus will be determined. Expected outcomes are new synthetic and light-reversible culture materials, and fundamental insights into how forces change the nucleus t ....Photoreversible hydrogels to study stem cell memory and fate. This project will develop materials whose stiffness can be reversibly increased and decreased by the simple application of light, and use these to build knowledge of how stem cell fate is regulated. The influence of mechanical cues on the structure and organisation of the nucleus will be determined. Expected outcomes are new synthetic and light-reversible culture materials, and fundamental insights into how forces change the nucleus to alter stem cell aging and fate. The findings will provide critical information required for the future development of assays to measure cell potency and instructive biomaterials to drive stem cell expansion and tissue-regeneration and will have impact by underpinning future advances in stem cell technologies.Read moreRead less
A new defect-control approach for mismatched heteroepitaxy semiconductors. This project aims to develop a new defect-control approach for silicon-germanium heteroepitaxial semiconductor systems to provide a route for high-throughput, low-cost, high-efficiency silicon tandem solar cells. Mismatched heteroepitaxy of semiconductors is of considerable interest for fabricating novel devices. However, the use of highly-mismatched heteroepitaxial semiconductors has been limited due to the high densitie ....A new defect-control approach for mismatched heteroepitaxy semiconductors. This project aims to develop a new defect-control approach for silicon-germanium heteroepitaxial semiconductor systems to provide a route for high-throughput, low-cost, high-efficiency silicon tandem solar cells. Mismatched heteroepitaxy of semiconductors is of considerable interest for fabricating novel devices. However, the use of highly-mismatched heteroepitaxial semiconductors has been limited due to the high densities of crystal defects which degrade the performance of both majority and minority carrier devices. This project aims to develop a new defect-control approach for heteroepitaxial semiconductors by continuous wavelength diode laser processing. With heteroepitaxial silicon-germanium as an example, the project will investigate the mechanism underlying defect-cleaning, optimised designs for best performance, and designs for high-efficiency tandem solar cells.Read moreRead less