Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100125
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Advanced fluorescence imaging facility: from super high resolution to whole animal imaging. The establishment of this advanced fluorescence imaging facility will provide cutting-edge infrastructure to examine cells, pathogens and interactions between engineered drug delivery systems in both cells and whole animals. The facility will foster the development of new nanomedicines.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100100
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
Cytometer by Time of Flight (CyTOF): A New Paradigm in Cytometry. Cytometer by Time of Flight (CyTOF) - a new paradigm in cytometry: The acquisition of a Cytometer by Time of Flight will allow multiparametric characterisation of biological systems and quantitative analysis of nano-bio interactions at the single cell level. The convergence of nanotechnology with biomedicine offers unprecedented opportunities for biological applications, including targeted therapeutics. One of the major challenges ....Cytometer by Time of Flight (CyTOF): A New Paradigm in Cytometry. Cytometer by Time of Flight (CyTOF) - a new paradigm in cytometry: The acquisition of a Cytometer by Time of Flight will allow multiparametric characterisation of biological systems and quantitative analysis of nano-bio interactions at the single cell level. The convergence of nanotechnology with biomedicine offers unprecedented opportunities for biological applications, including targeted therapeutics. One of the major challenges lies in understanding the complex interactions between nanoengineered materials and biological systems.Read moreRead less
Microfluidic technology to help understand physical damage to brain cells. Understanding the organisation, structure and mechanisms of the human brain and nervous system remains one of the biggest challenges of science. This project aims to develop a new cell culture platform to form defined molecular networks of brain cells and to monitor changes throughout the network in response to a small localised injury within the network. This innovative platform will be used to help understand changes wi ....Microfluidic technology to help understand physical damage to brain cells. Understanding the organisation, structure and mechanisms of the human brain and nervous system remains one of the biggest challenges of science. This project aims to develop a new cell culture platform to form defined molecular networks of brain cells and to monitor changes throughout the network in response to a small localised injury within the network. This innovative platform will be used to help understand changes within cells in response to physical damage to networks of brain cells. This is one of the major causes of death and disability in developed nations, and is identified as a risk factor for a range of neurodegenerative diseases including Alzheimer's, Parkinson's and motor neuron disease.Read moreRead less
Metal Virulence and Therapeutic Factors in Pathogen Bioinorganic Chemistry. The aim is to gain insights into the bioinorganic chemistry that occurs when immune system cells encounter pathogens and the soles of virulence factors and immune system enhancing roles of metal ions. Pathogenic bacteria and fungi accumulate chromium (Cr) in their membranes/outer capsules, which we discovered is likely to be a previously unknown, but important, virulence factor. Hyperaccummulation of nickel (Ni) is also ....Metal Virulence and Therapeutic Factors in Pathogen Bioinorganic Chemistry. The aim is to gain insights into the bioinorganic chemistry that occurs when immune system cells encounter pathogens and the soles of virulence factors and immune system enhancing roles of metal ions. Pathogenic bacteria and fungi accumulate chromium (Cr) in their membranes/outer capsules, which we discovered is likely to be a previously unknown, but important, virulence factor. Hyperaccummulation of nickel (Ni) is also involved in virulence, whereas vanadium (V) enhances the immune system response to these pathogens. Fundamental insights into these roles of Cr, Ni and V will be investigated using advanced spectroscopic, imaging and biochemical techniques. These insights will provide new knowledge on the innate immune system.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100163
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Live Cell Super Resolution Imaging Facility. The recent convergence of nanoscience and biology heralds a new era for the development of new biotechnologies. Advances in this field are critically dependent on being able to explore and understand the interactions of nanomaterials with cells in their live, dynamic state. This proposal aims to establish a Live Cell Super Resolution Imaging Facility, which will enable dynamic nanomaterial–cell interactions to be interrogated. This facility will under ....Live Cell Super Resolution Imaging Facility. The recent convergence of nanoscience and biology heralds a new era for the development of new biotechnologies. Advances in this field are critically dependent on being able to explore and understand the interactions of nanomaterials with cells in their live, dynamic state. This proposal aims to establish a Live Cell Super Resolution Imaging Facility, which will enable dynamic nanomaterial–cell interactions to be interrogated. This facility will underpin leading research programs at The University of Melbourne, Monash University, RMIT, the Peter MacCallum Cancer Centre and the Bionics Institute, promoting synergies across the physical and biological sciences for generating new knowledge and advancing bio-nanoscience and technology.Read moreRead less
Bioprogramming the behaviour of nanoparticles in live cells by nanoscopy . The project aims to develop safer materials that are sustainably sourced from sweet corn, and investigate using advanced imaging technologies, how these materials are processed in biological systems, including human and plant cells. This project expects to generate new knowledge in the optimal design of materials that can be used safely and effectively in biological applications in medicine and in agriculture. Expected ou ....Bioprogramming the behaviour of nanoparticles in live cells by nanoscopy . The project aims to develop safer materials that are sustainably sourced from sweet corn, and investigate using advanced imaging technologies, how these materials are processed in biological systems, including human and plant cells. This project expects to generate new knowledge in the optimal design of materials that can be used safely and effectively in biological applications in medicine and in agriculture. Expected outcomes of this multidisciplinary project include a library of highly biocompatible nanomaterials and expanded knowledge on imaging technologies and structure-function relationship of nanomaterials in biological cells. This should provide significant benefits, such as improved crop yields and safer transfection agents.Read moreRead less
Synthetic extracellular matrices for control of cellular reprogramming. This project aims to design materials that control the cellular environment for the fast, efficient, and reproducible production of reprogrammed cells in embryo-like architectures. Regenerative medicine has entered a new era, where reprogramming a patient’s cells is now possible for studying and treating disease. The expected outcomes of this project include mechanistic details of cell reprogramming, design rules for 3D prin ....Synthetic extracellular matrices for control of cellular reprogramming. This project aims to design materials that control the cellular environment for the fast, efficient, and reproducible production of reprogrammed cells in embryo-like architectures. Regenerative medicine has entered a new era, where reprogramming a patient’s cells is now possible for studying and treating disease. The expected outcomes of this project include mechanistic details of cell reprogramming, design rules for 3D printing of living cells and commercially viable reprogramming materials. The project expects to contribute fundamental knowledge in materials and biomedical sciences, while providing tools that will benefit commercial ventures in cell and tissue manufacturing.Read moreRead less
Molecular basis of nucleotide signalling by TIR domain containing proteins. Nicotinamide adenine dinucleotide (NAD+) dependent signalling pathways play important roles in neurodegenerative diseases and bacterial defence systems, and are therefore potential targets for the development of new therapeutics and biotechnology tools. This project aims to increase our understanding of the biology of a novel class of enzymes involved in NAD+ signalling across the domains of life. The project is expected ....Molecular basis of nucleotide signalling by TIR domain containing proteins. Nicotinamide adenine dinucleotide (NAD+) dependent signalling pathways play important roles in neurodegenerative diseases and bacterial defence systems, and are therefore potential targets for the development of new therapeutics and biotechnology tools. This project aims to increase our understanding of the biology of a novel class of enzymes involved in NAD+ signalling across the domains of life. The project is expected to unravel general principles of nucleotide-based signalling, and the expected outcomes will include new molecular mechanisms relevant to cell-death and pathogen defence in mammalian and bacterial systems, which should provide significant benefit for a range of applications in human biology and biotechnology.Read moreRead less
Light on a nanoscale: channelling energy through space and time to control neuronal activity. Quantum-mechanical effects of energy transfer and resonance will be harnessed to yield ultrabright nanoscale light sources. Research will unveil the intricate interplay between energy harvesting, transferring and emitting centres designed so that the flow of energy exhibits a directed character. This focussed intense energy will produce abundant visible photons from infrared light. Genetically engineere ....Light on a nanoscale: channelling energy through space and time to control neuronal activity. Quantum-mechanical effects of energy transfer and resonance will be harnessed to yield ultrabright nanoscale light sources. Research will unveil the intricate interplay between energy harvesting, transferring and emitting centres designed so that the flow of energy exhibits a directed character. This focussed intense energy will produce abundant visible photons from infrared light. Genetically engineered cells able to be stimulated optically by using an optogenetics method will be illuminated by our nanoscale light causing modulation of cell activity. This new capability will enable remote control of neuronal activity in specific circuits within the nervous system without the limitation of surgically inserted optical fibres.Read moreRead less
Breaching membrane barriers. This project will endeavour to develop novel molecular transporters to deliver macromolecules inside cells or microorganisms. Cell membranes are barriers to macromolecules. The ability to cross these barriers and deliver biological macromolecules into cells represents a major achievement with endless opportunities to modulate pathways and to introduce biomarkers, therapeutics and research tools. The project’s novel platform technology would be based on stable cyclic ....Breaching membrane barriers. This project will endeavour to develop novel molecular transporters to deliver macromolecules inside cells or microorganisms. Cell membranes are barriers to macromolecules. The ability to cross these barriers and deliver biological macromolecules into cells represents a major achievement with endless opportunities to modulate pathways and to introduce biomarkers, therapeutics and research tools. The project’s novel platform technology would be based on stable cyclic peptides to deliver genes, proteins, probes or biomarkers into distinct cell types that can monitor or modulate specific pathways and be translated into new knowledge and specific industrial applications.Read moreRead less