Advancing the visualisation and quantification of nephrons with MRI. . This project aims to characterise key components of nephrons, the glomeruli and tubules, using magnetic resonance imaging without contrast agents, in combination with Deep Learning and super-resolution techniques. Nephrons, the basic functional unit of the kidney, are critical to the maintenance of the body’s homeostasis. Their number and architecture are critical determinants of kidney function. The expected outcomes are inn ....Advancing the visualisation and quantification of nephrons with MRI. . This project aims to characterise key components of nephrons, the glomeruli and tubules, using magnetic resonance imaging without contrast agents, in combination with Deep Learning and super-resolution techniques. Nephrons, the basic functional unit of the kidney, are critical to the maintenance of the body’s homeostasis. Their number and architecture are critical determinants of kidney function. The expected outcomes are innovative semi-automated nephron visualisation and quantitation tools that enable efficient renal phenotyping. Techniques tailored to widely accessible preclinical research scanners are expected to accelerate research into genetic and environmental factors affecting kidney microstructure in embryonic and post-natal life.Read moreRead less
Impact of Biological Coatings on Nanoparticle–Immune Cell Interactions. Nanomaterials exposed to biological environments such as blood or lymph fluids rapidly adsorb a layer of biomolecules on their surface, forming a biomolecular corona, and profoundly altering their properties. This project aims to resolve the influence of biomolecular coronas on nanoparticle–immune cell interactions by combining particle engineering, immunology, proteomics and bioinformatic analysis. The project expected outc ....Impact of Biological Coatings on Nanoparticle–Immune Cell Interactions. Nanomaterials exposed to biological environments such as blood or lymph fluids rapidly adsorb a layer of biomolecules on their surface, forming a biomolecular corona, and profoundly altering their properties. This project aims to resolve the influence of biomolecular coronas on nanoparticle–immune cell interactions by combining particle engineering, immunology, proteomics and bioinformatic analysis. The project expected outcomes are to generate new knowledge in nanomaterial–immune cell behaviour and design principles for nanoparticles with prospective applications in the agricultural, veterinary and biomedical sectors.Read moreRead less
Random network models with applications in biology. Complex biological systems consist of a large number of interacting agents or components, and so can be studied using mathematical random network models. We aim to gain deeper insights into the laws emerging as the random networks evolve in time. This can help us to deal with dangerous disease epidemics and better understand the human brain.
Smart materials from semi-soft particles. This project will combine precision polymer chemistry to material science to develop structured nanoparticles for applications in photonics and shape memory materials.
Understanding bacteriophage deactivation and stabilisation in formulations. Bacteriophages (phages) are viruses that kill pathogenic bacteria without causing harms to the eco-balance. They can provide a safe and highly effective antimicrobial measure for biocontrol when formulated properly. This project aims to develop a mechanistic understanding of the physicochemical factors responsible for stabilising and deactivating phages in a wide range of formulations. It will create new knowledge on ke ....Understanding bacteriophage deactivation and stabilisation in formulations. Bacteriophages (phages) are viruses that kill pathogenic bacteria without causing harms to the eco-balance. They can provide a safe and highly effective antimicrobial measure for biocontrol when formulated properly. This project aims to develop a mechanistic understanding of the physicochemical factors responsible for stabilising and deactivating phages in a wide range of formulations. It will create new knowledge on key relationships between phage chemistry, phage-excipient interactions and phage stability. The research outcomes would significantly benefit Australia by enabling commercial development in the high value-adding area of environmentally friendly antimicrobial products.Read moreRead less
Diamane: A New Frontier in Materials Science. Single-layer diamond (‘diamane’) is a new frontier of material research although its preparation is still in infancy with many structures predicted possible but have not been made experimentally. Built on a new chemical route for 'graphite to diamane' transformation, this project will address a research gap towards synthesising new diamane(-like) nanostructures and developing an in-depth understanding of the chemically induced phase transformation an ....Diamane: A New Frontier in Materials Science. Single-layer diamond (‘diamane’) is a new frontier of material research although its preparation is still in infancy with many structures predicted possible but have not been made experimentally. Built on a new chemical route for 'graphite to diamane' transformation, this project will address a research gap towards synthesising new diamane(-like) nanostructures and developing an in-depth understanding of the chemically induced phase transformation and structure-property correlations, which will have far-reaching impact on scientific fields beyond carbon research. Preliminary data points to both feasibility and impact for discovering new materials and technologies, which will bring foreseeable scholarly, economic, and social benefits.Read moreRead less
Pushing the Boundaries of Multi-modal Biospectroscopic Microscopies. In order to understand the fundamentals of life processes, diseases, and their treatments, it is essential to probe fundamental changes in molecular processes in cells, tissues and whole organisms. Much of our understanding of these processes has involved the introduction of chemical probes for biospectroscopy, but these have inherent problems because the probe can often change the biochemistry that is being probed. This projec ....Pushing the Boundaries of Multi-modal Biospectroscopic Microscopies. In order to understand the fundamentals of life processes, diseases, and their treatments, it is essential to probe fundamental changes in molecular processes in cells, tissues and whole organisms. Much of our understanding of these processes has involved the introduction of chemical probes for biospectroscopy, but these have inherent problems because the probe can often change the biochemistry that is being probed. This project will push the boundaries of a variety of micro and nano "probe-free" microscopies to provide fundamental insights into these life processes, which could ultimately lead to improvements in the diagnosis, prevention and treatment of diseases.Read moreRead less
Spin manipulation in oxide magnetic semiconductors towards spintronics applications. The project is to develop high quality diluted magnetic semiconductors (DMS) with magnetic element dopant for practical spintronics applications. The properties for the qualified DMS include intrinsic ferromagnetism, effective spin manipulation, high spin polarisation and long distance of spin transport, which have not been well addressed so far. This project will investigate these issues using advance tools, in ....Spin manipulation in oxide magnetic semiconductors towards spintronics applications. The project is to develop high quality diluted magnetic semiconductors (DMS) with magnetic element dopant for practical spintronics applications. The properties for the qualified DMS include intrinsic ferromagnetism, effective spin manipulation, high spin polarisation and long distance of spin transport, which have not been well addressed so far. This project will investigate these issues using advance tools, including muon spin relaxation and neutron reflectometry. This project expects to establish criteria for evaluating DMS, understanding spin dynamics and mechanisms of spin manipulation and achieve qualified DMSs.Read moreRead less
Skeletal endocrine signalling in the regulation of glucose metabolism. This project seeks to explore a highly novel and interesting recent development in bone biology: the fact that the skeleton is a central regulator of glucose metabolism. Currently, the mechanisms involved in this process remain unclear. mTORC1 has been identified as a signalling pathway in bone cells that modulates glucose metabolism. This project plans to selectively delete mTORC1 in the bone cells of mice to examine how ske ....Skeletal endocrine signalling in the regulation of glucose metabolism. This project seeks to explore a highly novel and interesting recent development in bone biology: the fact that the skeleton is a central regulator of glucose metabolism. Currently, the mechanisms involved in this process remain unclear. mTORC1 has been identified as a signalling pathway in bone cells that modulates glucose metabolism. This project plans to selectively delete mTORC1 in the bone cells of mice to examine how skeletal mTORC1 signalling regulates glucose metabolism, and identify novel pathways and circulating factors involved in this process. These studies may provide greater understanding of the basic biology of glucose metabolism, and may have applications in animal husbandry and the future management of diabetes.Read moreRead less
The role of copper in the early ubiquitination pathway. This project aims to explore the role of copper in ageing and protein turnover. The removal of damaged or excess proteins is achieved by ubiquitin-tagging in all kingdoms of life. It has recently been observed that one of the earliest steps of this process appears to be driven by copper. This project aims to elaborate the precise biochemical mechanisms by which copper regulates this important tagging and protein turnover system. It proposes ....The role of copper in the early ubiquitination pathway. This project aims to explore the role of copper in ageing and protein turnover. The removal of damaged or excess proteins is achieved by ubiquitin-tagging in all kingdoms of life. It has recently been observed that one of the earliest steps of this process appears to be driven by copper. This project aims to elaborate the precise biochemical mechanisms by which copper regulates this important tagging and protein turnover system. It proposes to characterise the structure and function of a newly identified copper-dependent form of cell enzyme which could be involved in amplifying ubiquitin-tagged protein breakdown. Copper is essential for life in all domains. Identifying copper as a major regulator in protein clearance is important in understanding this fundamental biological machinery.Read moreRead less