Visualising molecular level detail in single cells and intact tissues. The goal of this project is to deliver a new toolkit for imaging cells at an unprecedented resolution and level of chemical detail. We will expand the capabilities of two existing, but complementary, methods: optical fluorescence microscopy with responsive probes and X-ray fluorescence imaging. Expected outcomes include improved techniques and benchmarks for visualising bacterial and mammalian cells; development of new molecu ....Visualising molecular level detail in single cells and intact tissues. The goal of this project is to deliver a new toolkit for imaging cells at an unprecedented resolution and level of chemical detail. We will expand the capabilities of two existing, but complementary, methods: optical fluorescence microscopy with responsive probes and X-ray fluorescence imaging. Expected outcomes include improved techniques and benchmarks for visualising bacterial and mammalian cells; development of new molecules for elucidating cellular chemistry; better utilisation of valuable synchrotron resources; and greater understanding of the strengths and limitations of current microscopy workflows. Results should benefit the biotechnology sector, and may lead to improved medical, diagnostic, and bioremediation capacity.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100181
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
Strengthening merit-based access and support at the new National Computing Infrastructure petascale supercomputing facility. World-leading high-performance computing is fundamental to Australia's international research success. This facility will provide access to the new National Computational Infrastructure facility by world-leading researchers from six research universities, and sustain ground-breaking work in an increasingly competitive environment.
Intelligent nanoparticles: Interactive tools to decode brain activity. This project aims to use nanoparticles and integrated nanoparticle devices to unravel causal relationships between molecular events and high-level brain activity. These devices, capable of real-time sensing and adaptive responses, could expose previously unmeasurable cellular events and establish their physiological effects. This is expected to reveal the complex dynamics in the living brain and advance neuroscience and analy ....Intelligent nanoparticles: Interactive tools to decode brain activity. This project aims to use nanoparticles and integrated nanoparticle devices to unravel causal relationships between molecular events and high-level brain activity. These devices, capable of real-time sensing and adaptive responses, could expose previously unmeasurable cellular events and establish their physiological effects. This is expected to reveal the complex dynamics in the living brain and advance neuroscience and analytical chemistry.Read moreRead less
Iron, ferroptosis and the biology of ageing. This project aims to determine how and when regulation of iron is lost. Failing iron metabolism during life may dictate the rate of ageing by driving a newly discovered cell death program. Combining biology, chemistry and physics, this collaborative project aims to transform the understanding of the fundamental mechanisms of biological ageing. Anticipated outcomes include new assays for measuring iron in biology and identification of potential pathway ....Iron, ferroptosis and the biology of ageing. This project aims to determine how and when regulation of iron is lost. Failing iron metabolism during life may dictate the rate of ageing by driving a newly discovered cell death program. Combining biology, chemistry and physics, this collaborative project aims to transform the understanding of the fundamental mechanisms of biological ageing. Anticipated outcomes include new assays for measuring iron in biology and identification of potential pathways that regulate death signaling and lifespan. Outcomes will benefit life sciences and biotechnology industries.Read moreRead less
Metalloproteomics: A new piece of the systems biology puzzle. Systems biology uses advanced analytical technology to study the complex chemistry of the living cell. Many cellular functions are the result of chemical reactions involving metalloproteins, which are notoriously difficult to study due to the weak bonds between metal and protein that is not normally amenable to traditional proteomic approaches. In partnership with the leading analytical manufacturer Agilent Technologies, this project ....Metalloproteomics: A new piece of the systems biology puzzle. Systems biology uses advanced analytical technology to study the complex chemistry of the living cell. Many cellular functions are the result of chemical reactions involving metalloproteins, which are notoriously difficult to study due to the weak bonds between metal and protein that is not normally amenable to traditional proteomic approaches. In partnership with the leading analytical manufacturer Agilent Technologies, this project aims to adapt and apply advanced mass spectrometry to the study of metalloproteins, developing new methods for studying hundreds of molecules in single experiments. Using the C. elegans model organism the project aims to showcase the importance of metals in biology and develop new solutions for the $2.9 billion proteomics industry.Read moreRead less
Examination of unique tear lipids and their role in the tear film's structure and function. The tear film lipid layer covers the eye, stabilises the tears and prevents their evaporation. Yet its structure, function and composition are yet to be fully elucidated. The aim of this project is to fully characterise the unique lipids in this layer, the long-chain omega-hydroxy fatty acids (not found elsewhere in the body), and to determine their role in its structure and function. The project is signi ....Examination of unique tear lipids and their role in the tear film's structure and function. The tear film lipid layer covers the eye, stabilises the tears and prevents their evaporation. Yet its structure, function and composition are yet to be fully elucidated. The aim of this project is to fully characterise the unique lipids in this layer, the long-chain omega-hydroxy fatty acids (not found elsewhere in the body), and to determine their role in its structure and function. The project is significant because the unique combination of skills including synthetic chemistry, mass spectrometry, lipidomics, biochemistry, biophysics which aim to result in a major shift in the understanding of this layer.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100129
Funder
Australian Research Council
Funding Amount
$249,000.00
Summary
Microflow ultra high pressure liquid chromatography - high resolution mass spectrometry for chemical exposure monitoring. Microflow ultra high pressure liquid chromatography – high resolution mass spectrometry for chemical exposure monitoring: Identifying new chemicals of interest in environmental or biological samples is the first critical step toward understanding their impact to human and environment. A state-of-the-art microflow ultra high performance liquid chromatography high resolution ma ....Microflow ultra high pressure liquid chromatography - high resolution mass spectrometry for chemical exposure monitoring. Microflow ultra high pressure liquid chromatography – high resolution mass spectrometry for chemical exposure monitoring: Identifying new chemicals of interest in environmental or biological samples is the first critical step toward understanding their impact to human and environment. A state-of-the-art microflow ultra high performance liquid chromatography high resolution mass spectrometer is fundamental to extend our research capabilities to new environmental contaminants and environmental exposure biomarkers, as well as consumption biomarkers of new illicit drugs and their metabolites. This instrument will fill an important gap in our capacity to link health/ecological risk to unknown chemicals and will allow interdisciplinary researchers to advance work in environmental toxicology, chemistry and forensics.Read moreRead less
Energy Transfer Across Organic-Inorganic Interfaces. This project seeks to advance our basic understanding of the energy transfer processes which are crucial to the operation of organic optoelectronic devices. Controlling energy transfer is central to the operation of electronic devices. As devices become smaller and more complex, the transfer of energy across interfaces between different materials begins to dominate their operation and characteristics. This project plans to use a range of compl ....Energy Transfer Across Organic-Inorganic Interfaces. This project seeks to advance our basic understanding of the energy transfer processes which are crucial to the operation of organic optoelectronic devices. Controlling energy transfer is central to the operation of electronic devices. As devices become smaller and more complex, the transfer of energy across interfaces between different materials begins to dominate their operation and characteristics. This project plans to use a range of complementary experimental approaches to study energy generation, transfer and diffusion across the nanoscale interface between organic and inorganic materials. Knowledge gained would provide a roadmap for bottom-up improvements to the efficiency of energy transfer across hybrid organic–inorganic interfaces, with a range of applications in optoelectronic devices, including photovoltaics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100736
Funder
Australian Research Council
Funding Amount
$362,446.00
Summary
High performing multifunctional silicon nanomaterials for bio-applications. This project aims to develop high-performance, multifunctional silicon nanomaterials, and to understand their physicochemical properties for bio-imaging. A range of high-quality multifunctional silicon-based bio-probes with novel fluorescent and magnetic properties will be developed for enhancing bio-imaging. The outcomes of the project will further strengthen Australia’s leading position in the targeted areas of Advance ....High performing multifunctional silicon nanomaterials for bio-applications. This project aims to develop high-performance, multifunctional silicon nanomaterials, and to understand their physicochemical properties for bio-imaging. A range of high-quality multifunctional silicon-based bio-probes with novel fluorescent and magnetic properties will be developed for enhancing bio-imaging. The outcomes of the project will further strengthen Australia’s leading position in the targeted areas of Advanced Materials and Nanotechnology.Read moreRead less
Nanoengineering Smart and Precise Antimicrobial Polymers. Designing the next generation of antimicrobial polymers. This proposal aims to combat the critical global issue of antibiotic resistance via fundamental and innovative chemistry design solutions. The proposed new design will enable the polymers to activate intelligently and precisely in the presence of specific stimuli such as bacterial enzymes for the first time, thereby endowing the polymers with both antimicrobial and biocompatible pro ....Nanoengineering Smart and Precise Antimicrobial Polymers. Designing the next generation of antimicrobial polymers. This proposal aims to combat the critical global issue of antibiotic resistance via fundamental and innovative chemistry design solutions. The proposed new design will enable the polymers to activate intelligently and precisely in the presence of specific stimuli such as bacterial enzymes for the first time, thereby endowing the polymers with both antimicrobial and biocompatible properties. Both properties are crucially needed for successful translation into practical applications. This proposal will lead to new and effective avenues in fighting multidrug-resistant bacteria and will significantly benefit Australia's healthcare and agriculture sectors.Read moreRead less