Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561229
Funder
Australian Research Council
Funding Amount
$518,427.00
Summary
Establishment of a Multiphoton Microscope Imaging Platform for Live Cell and Tissue, and Optical Imaging. This proposal seeks to establish a multidisciplinary multiphoton imaging laboratory, expanding the imaging capabilities of a Core Regional Imaging Facility. This Facility supports researchers across all Monash campuses and hospital-based research Schools, as well as outside research groups in the Victorian region. Furthermore, this equipment will support significant fiber optic research at V ....Establishment of a Multiphoton Microscope Imaging Platform for Live Cell and Tissue, and Optical Imaging. This proposal seeks to establish a multidisciplinary multiphoton imaging laboratory, expanding the imaging capabilities of a Core Regional Imaging Facility. This Facility supports researchers across all Monash campuses and hospital-based research Schools, as well as outside research groups in the Victorian region. Furthermore, this equipment will support significant fiber optic research at Victoria University for the development of communication and endoscopic technology. The instrument design will allow multiple use of the lightsource and choice of specific imaging devices (microscopes) to ensure that applications in biocellular imaging, intravital microscopy and fiber optic design and imaging are individually optimised.Read moreRead less
In situ Raman spectroscopic studies of iron and calcium biomaterials in marine chiton teeth. The future of biomaterial science in Australia depends upon the discovery and refinement of new materials. This project characterizes the biomaterials in the feeding apparatus of Australian marine chitons (Mollusca: Polyplacophora). Like many biological structures, chiton teeth are sophisticated composite materials that have been refined by evolution over millions of years. Initially composed of the poly ....In situ Raman spectroscopic studies of iron and calcium biomaterials in marine chiton teeth. The future of biomaterial science in Australia depends upon the discovery and refinement of new materials. This project characterizes the biomaterials in the feeding apparatus of Australian marine chitons (Mollusca: Polyplacophora). Like many biological structures, chiton teeth are sophisticated composite materials that have been refined by evolution over millions of years. Initially composed of the polysaccharide chitin, these extremely hard teeth are mineralized with calcium and iron compounds and used to excavate the rocks on which they live, as they graze for food. Understanding the mechanism of biomineralization is vital for devising synthetic routes to composite materials for industrial purposes.Read moreRead less
Characterisation Of Eurl, A Novel Gene Implicated In The Etiology Of Abnormal Brain Development And Intellectual Disability
Funder
National Health and Medical Research Council
Funding Amount
$597,541.00
Summary
Intellectual disability affects around one per cent of Australians, and can arise from genetic abnormalities during fetal life, such as through abnormal regulation of gene expression. We have identified a novel gene, known as eurl, which controls brain assembly as well as the ability of neurons to form functional connections within the brain. We will investigate how this novel gene controls brain development, and characterise eurl as a potential therapeutic target for learning and memory.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668435
Funder
Australian Research Council
Funding Amount
$1,300,000.00
Summary
Biomedical Engineering Sensing and Imaging Facility. The sensing and imaging facility will be the only national facility for leading engineering and medical researchers to undertake multidiscipline research into live and model biological systems. The facility will capture and combine existing strengths in these fields in Melbourne. This will provide new insights into the physiology of human, animal and plant systems and the development of preventive and curative strategies for disease.
Magnetic Nanoparticles for Biomedical Applications. This project will develop biocompatible magnetic nanoparticles for future generations of therapeutic and diagnostic applications. Applications include the reduction in overall toxicity of chemo- and radio- therapy by magnetic target drug delivery, enhanced ability to detect and diagnose diseases using magnetic binding/sorting techniques and an enhanced ability to repair detached retinas. The development of these products provides the potential ....Magnetic Nanoparticles for Biomedical Applications. This project will develop biocompatible magnetic nanoparticles for future generations of therapeutic and diagnostic applications. Applications include the reduction in overall toxicity of chemo- and radio- therapy by magnetic target drug delivery, enhanced ability to detect and diagnose diseases using magnetic binding/sorting techniques and an enhanced ability to repair detached retinas. The development of these products provides the potential for the development of new commercial opportunities in biotechnology and biomedical science in which Australia has an excellent track record. The project will also enhance Australia's capabilities in both nanotechnologiocal and biotechnological sciences.Read moreRead less
In vivo mechano-microscopy: a discovery platform for cell mechanics. This project aims to develop a platform for quantitative 3-D imaging of cell elasticity in tissue which may make possible new discoveries in cell mechanics. Mechanical properties, in concert with chemical properties, act to determine the function and behaviour of cells, and play a vital role in diseases such as cancer. Measurement of the mechanical properties of the cell in its native tissue environment, currently not possible, ....In vivo mechano-microscopy: a discovery platform for cell mechanics. This project aims to develop a platform for quantitative 3-D imaging of cell elasticity in tissue which may make possible new discoveries in cell mechanics. Mechanical properties, in concert with chemical properties, act to determine the function and behaviour of cells, and play a vital role in diseases such as cancer. Measurement of the mechanical properties of the cell in its native tissue environment, currently not possible, could accelerate the understanding of cell mechanics. This project plans to develop in vivo mechano-microscopy by combining innovations in optical microscopy, micro-mechanical loading, and computational methods. It then plans to demonstrate its capability by producing the first 3-D elasticity maps of skeletal muscle cells in living animals.Read moreRead less
Regulation Of Neural Progenitor Cell Self-renewal By The RNA-binding Protein ZFP36L1 During Development And Disease
Funder
National Health and Medical Research Council
Funding Amount
$345,401.00
Summary
The timely differentiation of neural stem cells is critical during development, and the unrestrained proliferation of neural stem cells in the adult can lead to deadly brain cancers such as glioma. At present our understanding of the key molecules that regulate neural stem cell behaviour during these processes remains limited. In this proposal we will investigate the molecular determinants underpinning neural stem cell biology, both within the developing brain, and within glioma.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100122
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
Returning WA Rapid Acquisition Fluorescent Microscopy to the cutting edge. The equipment proposal aims to establish West Australia's only super-rapid-speed, high throughput confocal microscopy facility. The technology will provide researchers in biotechnology, medicine, environmental biology and agriculture with contemporary state-of-art opportunities to analyse living cells and/or large-area tissue specimens in three-dimensions with the highest possible speed and high-resolution. West Australia ....Returning WA Rapid Acquisition Fluorescent Microscopy to the cutting edge. The equipment proposal aims to establish West Australia's only super-rapid-speed, high throughput confocal microscopy facility. The technology will provide researchers in biotechnology, medicine, environmental biology and agriculture with contemporary state-of-art opportunities to analyse living cells and/or large-area tissue specimens in three-dimensions with the highest possible speed and high-resolution. West Australia hosts 1 twelve-year old historic rapid-acquisition confocal microscope that is heavily subscribed, no longer manufactured and prone to regular, prolonged, costly breakdowns. Accessing high-speed confocal systems in other states is not a viable option putting WA-based researchers at a significant disadvantage.Read moreRead less
The Role Of The Zinc Finger Transcriptional Repressor Znf238 During Nerve Cell Maturation
Funder
National Health and Medical Research Council
Funding Amount
$394,264.00
Summary
Proper foetal brain assembly is critical for brain function, but the underlying genetic mechanisms remain poorly defined. In this study, I will investigate a family of proteins that “turn on” neural gene expression in combination with another protein that “turns off” their expression during nerve cell development. Understanding this novel on/off mechanism for controlling gene expression in newborn nerve cells will further our understanding of how the brain is assembled.
Roads to the Future: Infrastructure and the New Development in Africa. This project aims to conduct a comparative analysis of new road schemes in East Africa and the Western Indian Ocean (a region which sits at the intersection of several major global transport and development corridors), in order to understand their economic, socio-political, cultural and public health effects. As global road-building accelerates at an unprecedented rate, especially in the developing world, there is an urgent n ....Roads to the Future: Infrastructure and the New Development in Africa. This project aims to conduct a comparative analysis of new road schemes in East Africa and the Western Indian Ocean (a region which sits at the intersection of several major global transport and development corridors), in order to understand their economic, socio-political, cultural and public health effects. As global road-building accelerates at an unprecedented rate, especially in the developing world, there is an urgent need for new models for understanding roads' potential economic benefits, as well as their risks, including their environmental risks. This project is benefitting citizens, NGOs, donors and governments, by generating new knowledge about how we have in the past, do at present, and should in the future, engage with roads.Read moreRead less