Discovery Early Career Researcher Award - Grant ID: DE210100291
Funder
Australian Research Council
Funding Amount
$414,000.00
Summary
Conferring life-like functions to protocells. For life to have arisen, simple self-assembled chemicals must have performed key life-like functions. This project aims to generate new knowledge in the fields of soft condensed matter physics and astrobiology by understanding how primitive life could have obtained nutrients and completed “cell” division without proteins. This ambitious goal is expected to not only contribute towards understanding the origins of life, one of the grand challenges in s ....Conferring life-like functions to protocells. For life to have arisen, simple self-assembled chemicals must have performed key life-like functions. This project aims to generate new knowledge in the fields of soft condensed matter physics and astrobiology by understanding how primitive life could have obtained nutrients and completed “cell” division without proteins. This ambitious goal is expected to not only contribute towards understanding the origins of life, one of the grand challenges in science, but also to elucidate principles in membrane biophysics and self-assembly. The fundamental scientific findings will be applied to making responsive capsules that can confer advanced functionalities to soft materials. Several international collaborations are anticipated.Read moreRead less
Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-break ....Bioelectronic logic. This project aims to understand ion-electron interactions relevant to bioelectronics, and create transducing interfaces. Bioelectronics is a frontier field which aims to connect biological systems with modern electronics and so create biomedical devices. Transducing ion and electron signals using a biocompatible functional interface is difficult since ion and electron physics are different. By combining individual transducers, this project intends to demonstrate ground-breaking bioelectronic logic capable of interface-level processing. The stretch goal is to test this new logic with a biological neuronal model. The project could deliver new science and interfacing elements to integrate tissue and circuitry, and demonstrate these in a real biological model.Read moreRead less
Co-oligomer amphiphiles for novel living and fixed nanomaterials. By using the Australian breakthrough Reversible Addition-Fragmentation chain Transfer (RAFT) polymerization technique to make new molecular structures, we will assemble these into nanoparticles and nanostructured materials and surface coatings with novel properties for a broad range of new technologies and applications.
Highly multiplexed rapid-analysis microarrays for early disease diagnosis. Molecular diagnostics are revolutionising the treatment of disease in hospitals by providing rapid and accurate identification of pathogens; saving costs, time and lives. This project will accelerate this revolution by combining new array technology from the University of Sydney with a proven multiplex method from the Sydney based company, AusDiagnostics.
Discovery Early Career Researcher Award - Grant ID: DE180101635
Funder
Australian Research Council
Funding Amount
$343,450.00
Summary
DNA origami functionalised nanoscale surfaces. This project aims to combine the strengths of top-down and bottom-up nanofabrication to build hybrid structures. In traditional top-down nanofabrication, large systems pattern a semiconductor substrate to build up sophisticated devices. In contrast, in the emerging field of bottom-up nanotechnology, clever design of molecular interactions drives the self-assembly of smaller building blocks into more complex structures, with smaller features. This pr ....DNA origami functionalised nanoscale surfaces. This project aims to combine the strengths of top-down and bottom-up nanofabrication to build hybrid structures. In traditional top-down nanofabrication, large systems pattern a semiconductor substrate to build up sophisticated devices. In contrast, in the emerging field of bottom-up nanotechnology, clever design of molecular interactions drives the self-assembly of smaller building blocks into more complex structures, with smaller features. This project aims to bridge the gap between these two technologies to build functional devices. These devices will be applied, for example, to understand biological problems such as why blood clots form on implanted medical devices - their main cause of failure.Read moreRead less
A scalable, synthetic retina: signal processing in droplet systems with DNA. This project aims to design DNA-based nanotechnology for processing optical signals in synthetic biological systems. The intended outcome of this project is to develop a system for signal transduction in artificial bilayers using new DNA nanostructures. The anticipated goal of the project is to deliver: 1) light-based control of membrane protein insertion into artificial bilayers; 2) novel DNA-based pores that can trans ....A scalable, synthetic retina: signal processing in droplet systems with DNA. This project aims to design DNA-based nanotechnology for processing optical signals in synthetic biological systems. The intended outcome of this project is to develop a system for signal transduction in artificial bilayers using new DNA nanostructures. The anticipated goal of the project is to deliver: 1) light-based control of membrane protein insertion into artificial bilayers; 2) novel DNA-based pores that can transduce signals across membranes; 3) signal processing using multi-compartment biological components composed. Together, this technology allows us to use light and external signals to control biochemical pathways in synthetic systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100090
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Surface and Colloid Characterisation Facility. Surface and colloid characterisation facility: Surface science lies at the heart of biointerface and colloid science. This facility will enable particle size, shape, distribution, surface area and charge to be measured as well as the amount of material adsorbed to interfaces, the configuration of that material and the response of the surface to stimuli such as changing pH or salinity. All these parameters influence the properties of these important ....Surface and Colloid Characterisation Facility. Surface and colloid characterisation facility: Surface science lies at the heart of biointerface and colloid science. This facility will enable particle size, shape, distribution, surface area and charge to be measured as well as the amount of material adsorbed to interfaces, the configuration of that material and the response of the surface to stimuli such as changing pH or salinity. All these parameters influence the properties of these important systems. As such this facility will underpin the research of a number of groups across three institutions over the next decade and promote collaboration between scientists with a range of complementary expertise in fields where surface science is important from biology to ionic liquids.Read moreRead less
Rational design of new synthetic antifreeze molecules for cryopreservation. This project aims to synthesise new carbohydrate-based surfactants optimised for use as cryoprotectants, and to accurately measure, model and optimise their performance. The project will use state-of-the-art experimental methods and advanced phase-field modelling techniques to optimise the cryoprotectants so that they reduce osmotic stress in cells and inhibit ice crystal growth during freezing and thawing. The expected ....Rational design of new synthetic antifreeze molecules for cryopreservation. This project aims to synthesise new carbohydrate-based surfactants optimised for use as cryoprotectants, and to accurately measure, model and optimise their performance. The project will use state-of-the-art experimental methods and advanced phase-field modelling techniques to optimise the cryoprotectants so that they reduce osmotic stress in cells and inhibit ice crystal growth during freezing and thawing. The expected outcomes will be novel cryoprotectants that are easy to synthesise, non-toxic and effective, opening up new possibilities for the cryopreservation of cells, organs and possibly even whole organisms. This will have broad impact in critical applications such as long-term blood storage, reproductive technology and stem cell therapy, as well as preservation of endangered species.Read moreRead less
Functional mesostructured materials in ionic liquids. Polymers, surfactants and nanoparticles are the building blocks from which smart soft matter is assembled. This project will replace conventional molecular solvents with ionic liquids, allowing us to precisely control molecular assembly through intermolecular forces and facilitate the production of new functional soft materials.
Molecular scale engineering of solid/ionic liquid interfaces. Ionic liquids have enormous potential as advanced materials due to their unusual properties. This project will develop ways to use ionic liquids as lubricants, in electrochemical devices like capacitors, and in the electro-refining of metals. The technologies developed will decrease Australia's energy consumption and stimulate economic growth.