Broad spectrum nanomedicine for Meningitis treatment. Brain inflammatory diseases are among the top ten infectious causes of death. The project aims to provide Australian doctors with a superior alternative of treating infections that do not respond to conventional antibiotics. The nanomedicine developed will reduce the burden of hospital and boost Australia economy in the biomedical sector.
Biomaterials with multifaceted tunability and bio-specificity. Polyurethanes, a family of polymers with independently tunable mechanical and biodegradation properties, will be developed as a versatile platform material for biomedical implants. Novel energetic ion treatments that allow the coupling of bioactive agents to surfaces will eliminate adverse reactions and enable integration with surrounding tissue.
Biochemistry of tropoelastin and elastin. Elastin is the main protein responsible for the elasticity of vertebrate tissues. The Weiss Lab makes large quantities of full-length tropoelastin, which is crosslinked to make elastin. We want to examine the biochemistry of tropoelastin, learn how its domains participate in elastin structure and assembly, and explore cellular responses to our synthetic elastin biomaterial. Remarkably little is known of this biochemistry because elastin is a highly cross ....Biochemistry of tropoelastin and elastin. Elastin is the main protein responsible for the elasticity of vertebrate tissues. The Weiss Lab makes large quantities of full-length tropoelastin, which is crosslinked to make elastin. We want to examine the biochemistry of tropoelastin, learn how its domains participate in elastin structure and assembly, and explore cellular responses to our synthetic elastin biomaterial. Remarkably little is known of this biochemistry because elastin is a highly cross-linked and substantially insoluble macroscopic network of tropoelastin multimers. Our availability of tropoelastin and synthetic elastin now makes these studies possible.Read moreRead less
Bioactive Polymers for Wound Healing Applications. VitroGroR is a growth factor complex which enhances cell growth and migration, and hence has great potential for treating wounds. Tissue Therapies, which holds the rights to commercialization of VitroGroR, is seeking to develop methods of delivering VitroGroR in its active form to the wound environment. Two solutions to this problem will be developed in this project; a bioactive bandage containing a novel combination of microspheres and a hydrog ....Bioactive Polymers for Wound Healing Applications. VitroGroR is a growth factor complex which enhances cell growth and migration, and hence has great potential for treating wounds. Tissue Therapies, which holds the rights to commercialization of VitroGroR, is seeking to develop methods of delivering VitroGroR in its active form to the wound environment. Two solutions to this problem will be developed in this project; a bioactive bandage containing a novel combination of microspheres and a hydrogel matrix, and secondly an in-situ polymerisable matrix for treatment of deep wounds. The growth factor complex will be protected from aggressive proteases through encapsulation within microspheres, and the use of MMP-inhibiting comonomers.Read moreRead less
Molecularly engineered cell-instructive hydrogels for enhanced tissue regeneration. The outcomes of this project will be relevant to range of wounds, including burns, bed-sores, and diabetic and venous ulcers. Clearly, innovation in wound healing is urgently required as the treatment of wounds represents a significant challenge at all levels of our society, in terms of cost (physical, emotional and financial) to patients, the economy and to the wider community. Despite this obvious and overwhelm ....Molecularly engineered cell-instructive hydrogels for enhanced tissue regeneration. The outcomes of this project will be relevant to range of wounds, including burns, bed-sores, and diabetic and venous ulcers. Clearly, innovation in wound healing is urgently required as the treatment of wounds represents a significant challenge at all levels of our society, in terms of cost (physical, emotional and financial) to patients, the economy and to the wider community. Despite this obvious and overwhelming need, research in wound healing is relatively under-developed and has yet to adopt modern biotechnology and biomaterials approaches. This project is therefore directed at generating cost-effective frontier wound dressing technologies that accelerate wound repair.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100398
Funder
Australian Research Council
Funding Amount
$410,507.00
Summary
How T cells modulate stem cells and tissue regeneration. The project aims to determine how T cells modulate tissue repair and regeneration in mammals. Most of the mechanisms modulating the healing of tissues are elusive. This research is expected to reveal unknown mechanisms controlling the processes of tissue repair and regeneration, particularly the nexus between the stem cells involved in the tissue healing process and the immune response .
Discovery Early Career Researcher Award - Grant ID: DE140101530
Funder
Australian Research Council
Funding Amount
$372,744.00
Summary
Synchrotron-based modelling of the deformation and fracture mechanism in normal and osteoporotic femurs under multiaxial loading cycles. The femur is a light-weight structure designed to best perform in life. However, the complex tissue architecture, microstructural organisation and its complex loading regimens make it difficult to understand how the femur can deform and fracture. This project studies femoral fractures by modelling the proximal femur with a micrometric level of detail. Synchrotr ....Synchrotron-based modelling of the deformation and fracture mechanism in normal and osteoporotic femurs under multiaxial loading cycles. The femur is a light-weight structure designed to best perform in life. However, the complex tissue architecture, microstructural organisation and its complex loading regimens make it difficult to understand how the femur can deform and fracture. This project studies femoral fractures by modelling the proximal femur with a micrometric level of detail. Synchrotron femur images are taken in loaded and unloaded conditions. Cortical strain and fracture are measured, replicating possible multiaxial loads. Micro finite-element models will be used to study the contribution that the bone tissue architecture, tissue structure and activity types make to the fracture. The resulting knowledge will have future orthopaedic applications.Read moreRead less
Special Research Initiatives - Grant ID: SR0354797
Funder
Australian Research Council
Funding Amount
$20,000.00
Summary
The Australian Tissue Engineering Network. Driven by four key nodes across the country, the Initiative aims to bring together geographically and financially separated groups into a critical mass of cell and tissue engineering research. This new and rapidly-growing field uses a bio-synthetic approach to replace, repair or regenerate damaged tissues and organs. The Initiative will build the framework which will enable the Network to: identify appropriate expertise, manage duplication, enhance co ....The Australian Tissue Engineering Network. Driven by four key nodes across the country, the Initiative aims to bring together geographically and financially separated groups into a critical mass of cell and tissue engineering research. This new and rapidly-growing field uses a bio-synthetic approach to replace, repair or regenerate damaged tissues and organs. The Initiative will build the framework which will enable the Network to: identify appropriate expertise, manage duplication, enhance communication, bring together innovative skill sets, create linkages, generate focussed research programs and foster novel commercial opportunities. Ultimately the Initiative and Network will deliver an improved quality of life, reduced healthcare costs, and increased productivity to Australia.Read moreRead less
Growth of Bioartificial Tissue Containing an Inbuilt Blood Supply. The large and growing demand for replacement tissues and organs has spurred rapid growth in the emerging field of tissue engineering, which aims to form new tissues in the laboratory by combining living cells and synthetic scaffolds. A major challenge lies in the production of thick tissues, which require a blood supply in order to survive. Uniquely, this project aims to grow in the laboratory a vascular system based on natural ....Growth of Bioartificial Tissue Containing an Inbuilt Blood Supply. The large and growing demand for replacement tissues and organs has spurred rapid growth in the emerging field of tissue engineering, which aims to form new tissues in the laboratory by combining living cells and synthetic scaffolds. A major challenge lies in the production of thick tissues, which require a blood supply in order to survive. Uniquely, this project aims to grow in the laboratory a vascular system based on natural structures, which can then be used to support new tissue growth. Australia is well placed to reap the rewards of this work, having a track record in commercialisation of medical technologies, resulting in an improved quality of life for many Australians and substantial direct and indirect economic benefits.Read moreRead less
Magnetic Nanoparticles for Biomedical Applications. This project will develop biocompatible magnetic nanoparticles for future generations of therapeutic and diagnostic applications. Applications include the reduction in overall toxicity of chemo- and radio- therapy by magnetic target drug delivery, enhanced ability to detect and diagnose diseases using magnetic binding/sorting techniques and an enhanced ability to repair detached retinas. The development of these products provides the potential ....Magnetic Nanoparticles for Biomedical Applications. This project will develop biocompatible magnetic nanoparticles for future generations of therapeutic and diagnostic applications. Applications include the reduction in overall toxicity of chemo- and radio- therapy by magnetic target drug delivery, enhanced ability to detect and diagnose diseases using magnetic binding/sorting techniques and an enhanced ability to repair detached retinas. The development of these products provides the potential for the development of new commercial opportunities in biotechnology and biomedical science in which Australia has an excellent track record. The project will also enhance Australia's capabilities in both nanotechnologiocal and biotechnological sciences.Read moreRead less