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The Systems Biochemistry of Adaptation in Cellular Protein Networks. A living cell must process and interpret a host of diverse signals using a complex network of interacting proteins inside the cell. The detailed molecular mechanisms by which cells exhibit adaptation to these signals remains a fundamental question in biology. This project aims to develop a novel mathematical framework for analysing the capacity of intracellular protein interactions to contribute to cellular adaptation, along ....The Systems Biochemistry of Adaptation in Cellular Protein Networks. A living cell must process and interpret a host of diverse signals using a complex network of interacting proteins inside the cell. The detailed molecular mechanisms by which cells exhibit adaptation to these signals remains a fundamental question in biology. This project aims to develop a novel mathematical framework for analysing the capacity of intracellular protein interactions to contribute to cellular adaptation, along with a novel methodology for validating mathematical models against experimental data. These innovations offer a completely fresh approach to identifying and modulating the adaptive capacities of living cells, which may contribute to overcoming the problem of drug resistance in future therapeutic development.
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Decoding miRNA regulated genetic circuits. This project will aim to develop a much better understanding of how the process of making proteins from genes is regulated, and will develop scientific software capable of predicting how a cell will respond to changes in this regulation. The results will have widespread use, including assistance in deciding the best treatments for genetic diseases.
Encoding Interactions and Printability into Hairy Colloidal Biomaterials. Printing mixtures of live cells and biomaterials (or 'BioInks') to make bespoke engineered tissues has the potential to enable personalised platforms for therapeutic discovery and organ replacement. Using a novel high throughput approach to materials synthesis, BioInk design and process optimisation, this project aims to discover new biomaterials and printing nozzles to help realise this potential. It will produce new insi ....Encoding Interactions and Printability into Hairy Colloidal Biomaterials. Printing mixtures of live cells and biomaterials (or 'BioInks') to make bespoke engineered tissues has the potential to enable personalised platforms for therapeutic discovery and organ replacement. Using a novel high throughput approach to materials synthesis, BioInk design and process optimisation, this project aims to discover new biomaterials and printing nozzles to help realise this potential. It will produce new insights in colloid science, cell-laden biomaterials design, and BioInk processing. Structure-property-function guides for colloid-based BioInks and quality-assured bioprinting as outcomes represent significant benefits for researchers and industries alike engaged in biofabrication, cell therapy and biotherapeutics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200100119
Funder
Australian Research Council
Funding Amount
$424,607.00
Summary
Manipulation of non-wetting droplets for cell culture. We have recently discovered an innovative and interdisciplinary approach for manipulating non-wetting droplets called “liquid marbles” as a platform for three-dimensional cell culture. This project aims to elucidate the fundamental physics underpinning the electrostatic handling concept of this platform technology. The project is expected to deliver an inexpensive but sophisticated cell culture platform that is well-suited for high-throughpu ....Manipulation of non-wetting droplets for cell culture. We have recently discovered an innovative and interdisciplinary approach for manipulating non-wetting droplets called “liquid marbles” as a platform for three-dimensional cell culture. This project aims to elucidate the fundamental physics underpinning the electrostatic handling concept of this platform technology. The project is expected to deliver an inexpensive but sophisticated cell culture platform that is well-suited for high-throughput drug screening and preparing cells for implantation therapy. Significant benefits for end users in pharmaceutical industry, life sciences research and hospitals are expected from the project and the application of the developed technology.Read moreRead less
Establishing Design Principles Of Polymers For Intracellular Delivery . Engineered polymers have played a central role in the field of bionanotechnology by enabling targeted nanoscale cell interactions. Progress in the field of intracellular delivery is currently affected by a major bottleneck due to the absence of effective polymers that is applicable across the range of bimolecular cargoes. In essence depending on the type of cargo: DNA, RNA or protien, the polymer needs programmability. The l ....Establishing Design Principles Of Polymers For Intracellular Delivery . Engineered polymers have played a central role in the field of bionanotechnology by enabling targeted nanoscale cell interactions. Progress in the field of intracellular delivery is currently affected by a major bottleneck due to the absence of effective polymers that is applicable across the range of bimolecular cargoes. In essence depending on the type of cargo: DNA, RNA or protien, the polymer needs programmability. The limited tunability of traditional polymers agents makes them unsuitable for this particular application. The multidisciplinary project addresses this significant problem by engineering novel sequences of defined polymer based nanoscale agents to achieve efficient delivery in cells.Read moreRead less
Unpacking the immune system with applied mathematics. This project aims to model immune interactions across cells and structures spanning scales of nanometres to millimetres. It expects to develop innovative mathematical insights, improve our understanding of immunology, and consolidate collaborations with top American and European laboratories and groups. Expected outcomes include cutting-edge techniques for multiscale biological modelling and improved prediction and analysis of immune dynami ....Unpacking the immune system with applied mathematics. This project aims to model immune interactions across cells and structures spanning scales of nanometres to millimetres. It expects to develop innovative mathematical insights, improve our understanding of immunology, and consolidate collaborations with top American and European laboratories and groups. Expected outcomes include cutting-edge techniques for multiscale biological modelling and improved prediction and analysis of immune dynamics. The project should provide benefits to industries where highly organised behaviours are important, for example those interested in robot swarming, optimal transportation, and epidemic management. It should also benefit Australian students and researchers with novel overseas training opportunities.Read moreRead less
Promoting new reaction pathways with nonequilibrium flow. This project aims to develop a fundamental molecular level understanding of flow-induced physical and chemical reactions in liquids. Nonequilibrium molecular dynamics simulations will be used to gain insight into the mechanisms that promote reactions under shear, and how these are related to molecular structure and fluid composition. New relationships for determination of rate constants of reactions in nonequilibrium systems will also be ....Promoting new reaction pathways with nonequilibrium flow. This project aims to develop a fundamental molecular level understanding of flow-induced physical and chemical reactions in liquids. Nonequilibrium molecular dynamics simulations will be used to gain insight into the mechanisms that promote reactions under shear, and how these are related to molecular structure and fluid composition. New relationships for determination of rate constants of reactions in nonequilibrium systems will also be developed and tested. It is expected that this knowledge will enhance the capacity to control and promote reactions. This is significant for advancement of many technologies, from development of new synthetic pathways and products, to design of lubricants that can withstand extreme strain rates.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100128
Funder
Australian Research Council
Funding Amount
$450,000.00
Summary
Engineering microenvironments to regulate osteocyte 3D networks in vitro. Most knowledge of bone is based on only a fraction of cells found in bone because the majority of cells in our bones (called osteocyte cell networks) cannot easily be grown or studied outside the body. This results in the inability to understand how the bone organ functions. Using bioinspired engineering, this project will use advanced biomaterials to biofabricate, for the first time, osteocyte cell networks in vitro. By u ....Engineering microenvironments to regulate osteocyte 3D networks in vitro. Most knowledge of bone is based on only a fraction of cells found in bone because the majority of cells in our bones (called osteocyte cell networks) cannot easily be grown or studied outside the body. This results in the inability to understand how the bone organ functions. Using bioinspired engineering, this project will use advanced biomaterials to biofabricate, for the first time, osteocyte cell networks in vitro. By unravelling how they are formed and controlled by manipulating their microenvironment, we will discover how different types of bones are formed. The benefits will be a valuable tool for the bone research community, allowing unresolved questions to be addressed in the future, such as how bone forms, repairs, and remodels.Read moreRead less
Bioengineering self-assembly of innovative core-shell nanomaterials . This project aims to generate new knowledge in nanoscale bioengineering. It expects to develop a disruptive platform technology for design and manufacture of advanced nanomaterials to provide solutions for unmet needs in industry. It will explore an innovative bioengineering concept that merges biopolymer synthesis with virus-like particle self-assembly to produce innovative tunable core-shell nanomaterials. Expected outcomes ....Bioengineering self-assembly of innovative core-shell nanomaterials . This project aims to generate new knowledge in nanoscale bioengineering. It expects to develop a disruptive platform technology for design and manufacture of advanced nanomaterials to provide solutions for unmet needs in industry. It will explore an innovative bioengineering concept that merges biopolymer synthesis with virus-like particle self-assembly to produce innovative tunable core-shell nanomaterials. Expected outcomes are the development of advanced techniques for design and manufacture of innovate nanomaterials with enhanced stability and performance. This innovative platform technology for precision engineering of high-performance nanomaterials should provide significant benefits for biotechnological and agricultural industries.Read moreRead less
Stretchable Organic Transistors for Wearable Electronics and Robotics. The project aims to address the challenges of fabricating stretchable organic transistors for applications in wearable electronics and robotics through the development of new semiconducting polymers with stretchability and integrating them into novel, stretchable organic transistor configurations. The project will take a molecular engineering approach to the complex needs of this challenge by combining appropriate chemical f ....Stretchable Organic Transistors for Wearable Electronics and Robotics. The project aims to address the challenges of fabricating stretchable organic transistors for applications in wearable electronics and robotics through the development of new semiconducting polymers with stretchability and integrating them into novel, stretchable organic transistor configurations. The project will take a molecular engineering approach to the complex needs of this challenge by combining appropriate chemical functionality which provides high charge carrier mobility with judiciously placed flexible spacers and side chains to provide mechanical dexterity. These novel polymers will be integrated into transistor structures and their fabricated arrays deposited on stretchable substrates will be used for a real world applications.Read moreRead less