Engineered Polymer Scaffolds for Controlled Proliferation and Differentiation of Stem Cells. This project aims to develop a new methodology to sculpt 3D polymer scaffolds coated with cell adhesion and growth factors to control environmental cues, for the first time rapidly generating large quantities of undifferentiated stem cells. This project aims to exponentially increase cell generation in order to finally be able to unlock the potential of stem cells for application in regenerative medicine ....Engineered Polymer Scaffolds for Controlled Proliferation and Differentiation of Stem Cells. This project aims to develop a new methodology to sculpt 3D polymer scaffolds coated with cell adhesion and growth factors to control environmental cues, for the first time rapidly generating large quantities of undifferentiated stem cells. This project aims to exponentially increase cell generation in order to finally be able to unlock the potential of stem cells for application in regenerative medicine. The resulting cell repositories could make a significant contribution to human health outcomes.Read moreRead less
Bioengineered bioscaffolds for Achilles tendinopathy treatment. The purpose of the project is to improve outcomes following the surgical treatment of Achilles tendinopathy. The expected outcome is the development in animals of new ways to design tissue engineered bioscaffolds for the surgical repair of Achilles tendinopathy.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100012
Funder
Australian Research Council
Funding Amount
$890,000.00
Summary
Dual Column-Focused Ion Beam/Scanning Electron Microscope facility for Queensland. Dual column focused ion beam/scanning electron microscope facility: This facility will precisely cut specimens and surfaces that can be imaged in a variety of ways, including crystallographic and elemental space, of particular use for physical scientists, as well as biological specimens. This instrument will provide information at resolutions between optical and transmission electron microscopy, images that will ....Dual Column-Focused Ion Beam/Scanning Electron Microscope facility for Queensland. Dual column focused ion beam/scanning electron microscope facility: This facility will precisely cut specimens and surfaces that can be imaged in a variety of ways, including crystallographic and elemental space, of particular use for physical scientists, as well as biological specimens. This instrument will provide information at resolutions between optical and transmission electron microscopy, images that will effectively provide the biologist with the ability to develop the complete correlative picture of organelles and cells. The instrument will also provide a much needed resource for researchers across disciplines such as physics, chemistry, biology, geology and engineering.Read moreRead less
Biodegradable magnesium alloy scaffolds for bone tissue engineering. This project aims to develop a class of porous, biocompatible, biofunctional and biodegradable magnesium alloy scaffolds with designed pore architecture and mechanical properties mimicking those of natural bone for tissue engineering applications. These magnesium alloy scaffolds will be biocompatible, able to bear loads, and will be gradually replaced by natural bone. The outcomes are expected to benefit the ageing population a ....Biodegradable magnesium alloy scaffolds for bone tissue engineering. This project aims to develop a class of porous, biocompatible, biofunctional and biodegradable magnesium alloy scaffolds with designed pore architecture and mechanical properties mimicking those of natural bone for tissue engineering applications. These magnesium alloy scaffolds will be biocompatible, able to bear loads, and will be gradually replaced by natural bone. The outcomes are expected to benefit the ageing population and people with bone abnormalities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160101308
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
An in vitro model of biomaterial-induced thrombosis. This project intends to use bioengineering strategies to develop new methods to understand material interactions with proteins and cells. The project plans to develop microfluidic channels to contain test materials and immobilise a key enzyme associated with thrombosis by plasma immersion ion implantation. This knowledge may increase our understanding of material-biomolecule interactions and have implications for manipulating biological foulin ....An in vitro model of biomaterial-induced thrombosis. This project intends to use bioengineering strategies to develop new methods to understand material interactions with proteins and cells. The project plans to develop microfluidic channels to contain test materials and immobilise a key enzyme associated with thrombosis by plasma immersion ion implantation. This knowledge may increase our understanding of material-biomolecule interactions and have implications for manipulating biological fouling across multiple fields.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100115
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
High-temperature probes for investigating phase transitions and reaction kinetics in thin films, nanostructured materials and biomaterials. This infrastructure for high temperature surface analysis and in-situ diagnostics as a function of temperature and gas environments will enhance Australia's capabilities in creating new materials for devices that will meet needs in medical, communications, environmental and security applications. The facility will enable researchers to understand and exploi ....High-temperature probes for investigating phase transitions and reaction kinetics in thin films, nanostructured materials and biomaterials. This infrastructure for high temperature surface analysis and in-situ diagnostics as a function of temperature and gas environments will enhance Australia's capabilities in creating new materials for devices that will meet needs in medical, communications, environmental and security applications. The facility will enable researchers to understand and exploit interfacial phenomena and to tailor processing-microstructure-composition correlations, so as to design new materials with the best performance possible. Probes with unique capabilities will measure surface morphology, optical properties, elemental composition and crystallographic phase.The facility will be the first in Australia to offer a comprehensive study of structure and properties at high temperature.Read moreRead less
Highly ordered and tunable extracellular DNA micro- and nanopatterns for investigating the attachment mechanisms of pseudomonas aeruginosa to surfaces. Preventing infectious bacteria from colonising artificial surfaces is a major scientific challenge. New engineered surfaces will be designed to better understand how the important pathogen Pseudomonas aeruginosa sticks to surfaces, facilitating new ways of reducing infections acquired from the surface of, for example, medical devices.
Ultra-low fouling active surfaces. This project aims to develop chemistries and fabrication approaches through innovative materials evaluation to develop ultra-low fouling active electrode surfaces. Development of ultra-low fouling surfaces will have significant impact in a range of applications where system or device failure is attributed to fouling. The growing field of bionics, where implantable electronic devices interface directly with the nervous system, is one such device. The expected ou ....Ultra-low fouling active surfaces. This project aims to develop chemistries and fabrication approaches through innovative materials evaluation to develop ultra-low fouling active electrode surfaces. Development of ultra-low fouling surfaces will have significant impact in a range of applications where system or device failure is attributed to fouling. The growing field of bionics, where implantable electronic devices interface directly with the nervous system, is one such device. The expected outcomes will be an understanding of the material requirements that lead to the elimination of protein and cell accumulation at surfaces that degrades the performance and lifetime of these implants. The findings will benefit any application where fouling is a problem.Read moreRead less
Engineering Functional Antimicrobial Polypeptide Surfaces. Antimicrobial coatings are vital in preventing bacterial contamination but a versatile solution does not exist. Structurally nanoengineered antimicrobial peptide polymers (SNAPPs) were recently developed to fight multidrug-resistant bacteria. To expand their application into antimicrobial coatings across a range of surfaces, a simple and universal coating strategy is needed. By developing phenolic-functionalised SNAPPs, this project aims ....Engineering Functional Antimicrobial Polypeptide Surfaces. Antimicrobial coatings are vital in preventing bacterial contamination but a versatile solution does not exist. Structurally nanoengineered antimicrobial peptide polymers (SNAPPs) were recently developed to fight multidrug-resistant bacteria. To expand their application into antimicrobial coatings across a range of surfaces, a simple and universal coating strategy is needed. By developing phenolic-functionalised SNAPPs, this project aims to exploit the adhesive nature of metal–phenolic materials to rapidly coat diverse surfaces, including stainless steel and textiles. The expected outcome is the generation of antimicrobial polypeptide surfaces, which will have benefits in food safety, medical implant technology and advanced textiles.Read moreRead less