Understanding platinum dissolution in biomedical stimulating electrodes. Platinum is the main material used in electrodes for neurostimulators like the cochlear implant. Platinum electrodes can experience dissolution during implantation, which can impact on their function. The mechanisms governing this dissolution process are complex and still not fully understood. This research aims to understand the chemical, electrical and biological factors that impact on platinum dissolution in electrodes. ....Understanding platinum dissolution in biomedical stimulating electrodes. Platinum is the main material used in electrodes for neurostimulators like the cochlear implant. Platinum electrodes can experience dissolution during implantation, which can impact on their function. The mechanisms governing this dissolution process are complex and still not fully understood. This research aims to understand the chemical, electrical and biological factors that impact on platinum dissolution in electrodes. It will also develop new 3D models to simulate conditions in the human body for more rapid testing of electrodes. The new knowledge generated will improve the accuracy of predictions of platinum dissolution, develop new approaches for minimising dissolution, and contribute to reducing need for animal experimentation.Read moreRead less
A thermodynamic pathway to intracellular delivery. Cells transmit information through molecules. By delivering foreign molecules into cells, such as DNA and proteins, it is possible to engineer and reprogram cells just like a computer. This proposal aims to develop a novel microfluidic device for intracellular delivery. The device will work by exposing cells to rapid thermal shock to generate transient disruptions in cell membranes and thereby enable influx of foreign molecules into cells. To un ....A thermodynamic pathway to intracellular delivery. Cells transmit information through molecules. By delivering foreign molecules into cells, such as DNA and proteins, it is possible to engineer and reprogram cells just like a computer. This proposal aims to develop a novel microfluidic device for intracellular delivery. The device will work by exposing cells to rapid thermal shock to generate transient disruptions in cell membranes and thereby enable influx of foreign molecules into cells. To understand how the method can be optimized, the thermodynamic pathway of membrane disruption will be investigated at a single cell level. The methods and insights arising from this project could eventually lead to novel, patentable and lower-cost health technologies.Read moreRead less
Modelling human brain development with stem cells and biomaterials. With limited resources to directly study and advance our understanding of human neural development, this
proposal will establish models of 4 key stages. Employing innovative, interdisciplinary approaches, biomaterials will be fabricated to provide structural and chemical support for human stem cells during: (i) neural induction, (ii) specification into neuronal progenitor subpopulations, (iii) neuronal maturation and integration ....Modelling human brain development with stem cells and biomaterials. With limited resources to directly study and advance our understanding of human neural development, this
proposal will establish models of 4 key stages. Employing innovative, interdisciplinary approaches, biomaterials will be fabricated to provide structural and chemical support for human stem cells during: (i) neural induction, (ii) specification into neuronal progenitor subpopulations, (iii) neuronal maturation and integration into complex neural networks as well as, (iv) the organisation of neurons into larger 3-dimensional brain structures, namely folding of the human cortex. Further, biomaterials developed here have commercialisation potential, targeted at standardizing the culturing of human stem cells to defined neural populations.
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The colour of cellular aging: a deep probe of cellular processes. Understanding why we age and whether aging is preventable are profound research challenges, which must be first tackled at a cellular level. Building on our advances in non-invasive colour monitoring of cell function, this project aims to uncover intimate links between cellular processes and aging in cells that must survive for many decades such as oocytes and neurons. We will explore the tantalising possibility to rejuvenate such ....The colour of cellular aging: a deep probe of cellular processes. Understanding why we age and whether aging is preventable are profound research challenges, which must be first tackled at a cellular level. Building on our advances in non-invasive colour monitoring of cell function, this project aims to uncover intimate links between cellular processes and aging in cells that must survive for many decades such as oocytes and neurons. We will explore the tantalising possibility to rejuvenate such aged cells by interfering with molecular master switches of aging. A unique machine learning approach will be applied for finding the most effective interventions. The results will have broad impact beyond the science of aging, in the areas of female fertility, neurodegeneration and immunity.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100001
Funder
Australian Research Council
Funding Amount
$875,000.00
Summary
A 3-photon imaging system for deep live imaging. This project aims to establish Australia’s first 3-photon microscope system with adaptive optics for deep intravital imaging. This advanced imaging system will enable researchers to investigate the biology of cells and tissue structures in a wide range of organs and engineered tissues, to a degree not possible with existing technology. This project will capitalise on advanced laser, microscope and adaptive optics technologies with the expected out ....A 3-photon imaging system for deep live imaging. This project aims to establish Australia’s first 3-photon microscope system with adaptive optics for deep intravital imaging. This advanced imaging system will enable researchers to investigate the biology of cells and tissue structures in a wide range of organs and engineered tissues, to a degree not possible with existing technology. This project will capitalise on advanced laser, microscope and adaptive optics technologies with the expected outcomes to include the generation of new knowledge of major biological systems, including the immune system and the nervous system. This will provide significant benefits to fundamental interdisciplinary research into immunology, infectious disease, neuroscience, mechanobiology and engineering.Read moreRead less
Synthetic leukocytes: bio-inspired DNA nanorobots powered by flow. Inspired by the way white blood cells roll along blood vessel walls, our goal is to build DNA nanorobots that roll along surfaces in flow. We take a synthetic biology approach to using biomolecules, such as DNA and proteins, to build functional particles and surfaces. To achieve this, we will combine our teams’ technological advances in DNA nanotechnology, plasma-activation for biomolecule immobilisation, and microfluidic devices ....Synthetic leukocytes: bio-inspired DNA nanorobots powered by flow. Inspired by the way white blood cells roll along blood vessel walls, our goal is to build DNA nanorobots that roll along surfaces in flow. We take a synthetic biology approach to using biomolecules, such as DNA and proteins, to build functional particles and surfaces. To achieve this, we will combine our teams’ technological advances in DNA nanotechnology, plasma-activation for biomolecule immobilisation, and microfluidic devices. This project will contribute new methods for synthetic particle motion in flow and provide new insights into biomolecule interactions and motion. Ultimately, this will allow us to harness rolling for the delivery of synthetic nanorobots for detection and remediation in flow systems, such as the body.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
Protein biosensors for detecting smoke exposure of grapes. Bush fires and controlled burns that take place in the vicinity of vineyards can lead to grape contamination with tasteless phenolic glucosides. Their hydrolysis during wine making leads to “smoke taint” – an unpleasant medicinal taste that can render wine undrinkable. We will apply a combination of organic synthesis, protein engineering and directed evolution to develop protein-based biosensors of phenolic glucosides. These biosensors w ....Protein biosensors for detecting smoke exposure of grapes. Bush fires and controlled burns that take place in the vicinity of vineyards can lead to grape contamination with tasteless phenolic glucosides. Their hydrolysis during wine making leads to “smoke taint” – an unpleasant medicinal taste that can render wine undrinkable. We will apply a combination of organic synthesis, protein engineering and directed evolution to develop protein-based biosensors of phenolic glucosides. These biosensors will be used to devise a simple portable colorimetric test that can be performed in the vineyard or the winery. The ability to rapidly determine the level of grape contamination with phenolic glucosides would give Australian wine growers and wine makers a powerful tool to mitigate the effects of bushfires.Read moreRead less
Engineering biomaterials that actively promote blood vessel growth. This project aims to improve understanding of the effect of biomaterials on vascular growth & to develop new biomimetic materials using natural polymers silk & gelatin. It expects to generate new knowledge in biomaterials, matrix biology & advanced material processing. Expected outcomes include new knowledge & technological advances in biomaterial-driven vascular growth, porous material manufacture, & proteoglycan-mediated grow ....Engineering biomaterials that actively promote blood vessel growth. This project aims to improve understanding of the effect of biomaterials on vascular growth & to develop new biomimetic materials using natural polymers silk & gelatin. It expects to generate new knowledge in biomaterials, matrix biology & advanced material processing. Expected outcomes include new knowledge & technological advances in biomaterial-driven vascular growth, porous material manufacture, & proteoglycan-mediated growth factor signalling, as well as cross-disciplinary, international collaboration & research training. This should provide significant benefit to Australia’s scholarly output & reputation & long term benefits to biomedical, veterinary, cosmetic, & food industries through new materials & processing technologies. Read moreRead less