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
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: DE130101550
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Functional polymer encapsulation to enhance biological performance of implantable materials. This project will develop biomaterial films from essential oils using a low-cost 'green' technology. Applied to commercial biomaterials, these films will minimise infections and inflammations commonly associated with implants. These films will also enable clinical use of metallic resorbable implants for tissue engineering and function restoration.
Soft materials containing hierarchy via 3D sacrificial micro-moulding. The project seeks to develop sophisticated new polymeric materials and devices not possible using current manufacturing techniques. Biomaterials based on hydrogels are ideal substrates for synthetic extra-cellular matrices due to their high water content. However, one of the challenges hindering the use of hydrogels is reproducing the transport properties found in natural tissue with hierarchical features such as vascularisat ....Soft materials containing hierarchy via 3D sacrificial micro-moulding. The project seeks to develop sophisticated new polymeric materials and devices not possible using current manufacturing techniques. Biomaterials based on hydrogels are ideal substrates for synthetic extra-cellular matrices due to their high water content. However, one of the challenges hindering the use of hydrogels is reproducing the transport properties found in natural tissue with hierarchical features such as vascularisation. To address this, the project plans to develop a 3D moulding process for generating soft materials containing precise channels decorated with defined molecules. Intended outcomes include a fundamental understanding of the 3D moulding process, and new polymers and advanced tools for bioengineers for future applications such as tissue transplants, cell guides for treating spinal cord injuries, soft robotics and microfluidic devices to study cancer metastasis. Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC180100024
Funder
Australian Research Council
Funding Amount
$4,000,000.00
Summary
ARC Training Centre for Medical Implant Technologies. The ARC Training Centre for Medical Implant Technologies aims to train a new generation of interdisciplinary engineers and to transform the orthopaedic and maxillofacial implant industry in Australia. In collaboration with industry, universities and hospitals, the Centre will build a dynamic training environment for interdisciplinary engineers to develop and evaluate personalised implants and surgeries. It will create new networks, internatio ....ARC Training Centre for Medical Implant Technologies. The ARC Training Centre for Medical Implant Technologies aims to train a new generation of interdisciplinary engineers and to transform the orthopaedic and maxillofacial implant industry in Australia. In collaboration with industry, universities and hospitals, the Centre will build a dynamic training environment for interdisciplinary engineers to develop and evaluate personalised implants and surgeries. It will create new networks, international collaborations and a generation of industry-ready researchers critical for growing Australia’s industry. The advances in materials and savings in time for procedures will reduce costs.
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A Micro-Physiological System to Mimic Human Microbiome-Organ Interactions. This project aims to mimic gut microbiome-organ interactions by developing a microbial-gut coculture chip, which can reversibly interface with other organs-on-chips. This is achieved through the systematic integration of highly customisable biofabrication and microfluidic technologies. This project fills a critical technological gap in the availability of an animal-alternative system to investigate microbiome-host interac ....A Micro-Physiological System to Mimic Human Microbiome-Organ Interactions. This project aims to mimic gut microbiome-organ interactions by developing a microbial-gut coculture chip, which can reversibly interface with other organs-on-chips. This is achieved through the systematic integration of highly customisable biofabrication and microfluidic technologies. This project fills a critical technological gap in the availability of an animal-alternative system to investigate microbiome-host interactions, which will greatly complement existing meta-omics approaches. The deliverables include a proof-of-concept system validated for gut-liver axis as well as the creation of new knowledge and framework to assimilate design thinking and advanced manufacturing to elevate tissue engineering into physiology engineering. Read moreRead less
Controlling the adhesome to regulate cell fate on biomaterials. Mesenchymal stem cell-based tissue engineering practices are hampered worldwide by the lack of appreciation and understanding of the matrix-mediated cues that must be provided during adhesion and spreading to drive cells to definitive tissue end points. This project will address these knowledge deficiencies by combining high throughput array technologies, a set of tailorable self-assembling biomaterials and real-time biosensors to r ....Controlling the adhesome to regulate cell fate on biomaterials. Mesenchymal stem cell-based tissue engineering practices are hampered worldwide by the lack of appreciation and understanding of the matrix-mediated cues that must be provided during adhesion and spreading to drive cells to definitive tissue end points. This project will address these knowledge deficiencies by combining high throughput array technologies, a set of tailorable self-assembling biomaterials and real-time biosensors to rapidly, at high resolution, elucidate how mechanotransductive cues determine the fate choice of mesenchymal stem cells, and furthermore, how to manipulate them with smart biomaterial design to achieve desired outcomes for tissue engineering. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130100986
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
An innovative platform using non-coding ribonucleic acids (RNAs) to control stem cell differentiation outcomes. It is difficult to control the tissue type that stem cells will form when combined with biomaterials, as the outcome is influenced by the 'stiffness' of the surface to which the stem cells attach. This project will determine how non-coding ribonucleic acids (RNAs) control stem cell behaviours and use this information to direct stem cell differentiation outcomes.
Identifying how cortical bone microstructure deteriorates with age. This project aims to define the disruptions responsible for the gradual weakening of the skeleton in ageing by integrating a range of high-resolution imaging, biomechanical, and computational methods. The expected significance of this project includes a full definition and comparison of the cellular and subcellular organisation of bone from young and elderly individuals. Expected outcomes of this international project include th ....Identifying how cortical bone microstructure deteriorates with age. This project aims to define the disruptions responsible for the gradual weakening of the skeleton in ageing by integrating a range of high-resolution imaging, biomechanical, and computational methods. The expected significance of this project includes a full definition and comparison of the cellular and subcellular organisation of bone from young and elderly individuals. Expected outcomes of this international project include the establishment of a new multidisciplinary research team, and the development of a new data-driven theoretical framework for understanding the nature and the causes of age-related bone fragility. Potential long-term benefits include new ways to treat age-related osteoporosis.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100036
Funder
Australian Research Council
Funding Amount
$440,000.00
Summary
National in-situ transmission electron microscope facilities. This project will establish six complementary transmission electron microscope (TEM) facilities at various locations. The establishment of the facilities will be a key step in developing advanced capacity in Australia and will support ground-breaking research in diverse material systems for various high-performing applications, including electronics, optoelectronics, light metals, biomaterials, energy, and environment.