Understanding glycopolymer interactions with the extracellular matrix. This project aims to advance knowledge of the biochemical and biophysical structure of the endothelial glycocalyx, a dynamic cell surface extracellular matrix rich in proteoglycans and glycosaminoglycans. It will be the first to explore how charged glycopolymers interact with this dynamic interface with the goal to develop a model of the glycocalyx lifecycle. This project is expected to enable the transfer of skills, knowledg ....Understanding glycopolymer interactions with the extracellular matrix. This project aims to advance knowledge of the biochemical and biophysical structure of the endothelial glycocalyx, a dynamic cell surface extracellular matrix rich in proteoglycans and glycosaminoglycans. It will be the first to explore how charged glycopolymers interact with this dynamic interface with the goal to develop a model of the glycocalyx lifecycle. This project is expected to enable the transfer of skills, knowledge and ideas as well as advanced research and industrial training for young scientists. Knowledge derived from this project is expected to enable future innovation in molecules with tailored interactions with the glycocalyx with significant benefits for researchers, manufacturers and end users. Read moreRead less
Biomolecular surface interactions with smart biomaterials. Current materials used for medical implants are often recognised by the body as foreign materials causing implant rejection or encapsulation. Research into the interactions between biological molecules and chemically and topographically modified materials will aid in the development of new materials and devices that optimise the body's response to the implanted material. The new materials and surfaces developed from this research will pr ....Biomolecular surface interactions with smart biomaterials. Current materials used for medical implants are often recognised by the body as foreign materials causing implant rejection or encapsulation. Research into the interactions between biological molecules and chemically and topographically modified materials will aid in the development of new materials and devices that optimise the body's response to the implanted material. The new materials and surfaces developed from this research will provide longer lasting implants and reduce the need for repeated operations. This will improve the quality of life for implant recipients and reduce health care costs.Read moreRead less
Injectable scaffolds for treatments of neurological disorders. Cell replacement therapies offer potentially effective treatments for a host of neurological disorders but a major obstacle confronting their development is to ensure appropriate connections are formed within the brain. This proposal aims to utilize injectable biodegradable polymers, to demonstrate the feasibility of assisting neural cells and stem cells to bridge glial scars or significant distances in the brain and repair damaged n ....Injectable scaffolds for treatments of neurological disorders. Cell replacement therapies offer potentially effective treatments for a host of neurological disorders but a major obstacle confronting their development is to ensure appropriate connections are formed within the brain. This proposal aims to utilize injectable biodegradable polymers, to demonstrate the feasibility of assisting neural cells and stem cells to bridge glial scars or significant distances in the brain and repair damaged neural pathways. This proposal will focus on naturally occurring polysaccharides, which will act as "scaffolds" for the growing neurones. The role the scaffolds play in regulating neurite extension will be investigated in vitro and in vivo.Read moreRead less
Manipulating nano-fibres to control nerve regeneration. Diseases of the brain and mind are the most common diseases in the western world; being even more prevalent than cardiac or malignant disease. With Australia's aging demographic, diseases of the brain and mind will continue to impact on our productivity in the workplace, our quality of life, and the ability of the medicare and private health care systems to keep up with the ever-increasing demand for older Australians.
The research prop ....Manipulating nano-fibres to control nerve regeneration. Diseases of the brain and mind are the most common diseases in the western world; being even more prevalent than cardiac or malignant disease. With Australia's aging demographic, diseases of the brain and mind will continue to impact on our productivity in the workplace, our quality of life, and the ability of the medicare and private health care systems to keep up with the ever-increasing demand for older Australians.
The research proposed here will enable us to find solutions to this serious problem by building on Australia's strong track record in nanotechnology and biotechnology research, and help towards new and effective treatments.
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Targeted growth factor delivery using natural polysaccharide materials for bone regeneration. This proposal addresses the core issue of nano-biomaterials capable of encouraging bone growth and providing better and more complete healing of bone fractures. Australia will benefit firstly through improved health outcomes by providing material-based solutions to address slow or non-healing fractures, which are increasingly prevalent in the aging population in Australia. This will have a further benef ....Targeted growth factor delivery using natural polysaccharide materials for bone regeneration. This proposal addresses the core issue of nano-biomaterials capable of encouraging bone growth and providing better and more complete healing of bone fractures. Australia will benefit firstly through improved health outcomes by providing material-based solutions to address slow or non-healing fractures, which are increasingly prevalent in the aging population in Australia. This will have a further benefit to the Australian economy improving the quality of life enabling people to work longer and reducing the need for further surgical intervention. This proposal will also have benefits to Australia through training future researchers in this field which will in turn provide economic growth through the development of Australian industries.Read moreRead less
Engineering Articular Cartilage with Zonal Structure and Function. This project addresses the National Research Priority of Promoting and Maintaining Good Health and specifically the Priority Goal of Ageing well, ageing productively. Osteoarthritis, the most common cartilage-related disease, affects nearly 1.4 million Australians, resulting in 2 in 1000 Australians undergoing total joint replacement, annually. The incidence and impact of cartilage damage on the Australian health and economy is e ....Engineering Articular Cartilage with Zonal Structure and Function. This project addresses the National Research Priority of Promoting and Maintaining Good Health and specifically the Priority Goal of Ageing well, ageing productively. Osteoarthritis, the most common cartilage-related disease, affects nearly 1.4 million Australians, resulting in 2 in 1000 Australians undergoing total joint replacement, annually. The incidence and impact of cartilage damage on the Australian health and economy is expected to increase with the ageing population. This work leads to the development of a novel cartilage engineering technology platform that addresses Frontier Technologies and will thus provide the foundation for translation of this technology to the international marketplace. Read moreRead less
Design and characterisation of a polysaccharide-based biomaterial for tissue adhesion. This proposal aims to design a new bio-adhesive material and study the mechanisms of action for tissue adhesion. Current suture technology is inadequate for anything but simple repairs and the alternative offered by surgical glues available today is at most augmentation of suturing. Combination of a strong adhesive biomaterial with factors for accelerating wound healing will generate a novel material technolo ....Design and characterisation of a polysaccharide-based biomaterial for tissue adhesion. This proposal aims to design a new bio-adhesive material and study the mechanisms of action for tissue adhesion. Current suture technology is inadequate for anything but simple repairs and the alternative offered by surgical glues available today is at most augmentation of suturing. Combination of a strong adhesive biomaterial with factors for accelerating wound healing will generate a novel material technology that, by uniting wound closure with sealing, addresses an unmet need in surgery.
The primary outcomes of these investigations will be:
1. advancement of knowledge in theories of tissue-biomaterial adhesion mechanisms
2. knowledge of effects of visible light from laser diodes on cells and isolated tissue
3. a biocompatible, visible light activated adhesive film for tissue repair based on chitosan polysaccharides
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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
Interfacial interactions with hydrogel biomaterials. The interactions between cells of the body and the surfaces of medical implants are controlled largely by the molecules that are adsorbed on the surface. The aim of this project is to evaluate the effect of modifying hydrogel biomaterials on the interactions of the molecules with the hydrogel. This, in turn, allows us to determine the factors affecting the control of the cell's response. The significance of this work is in the improved ability ....Interfacial interactions with hydrogel biomaterials. The interactions between cells of the body and the surfaces of medical implants are controlled largely by the molecules that are adsorbed on the surface. The aim of this project is to evaluate the effect of modifying hydrogel biomaterials on the interactions of the molecules with the hydrogel. This, in turn, allows us to determine the factors affecting the control of the cell's response. The significance of this work is in the improved ability to control cellular responses to implants. Such improved response will result in better health outcomes for patients, and outcomes in the form of papers and intellectual property.
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Characterization and optimisation of Myomatrix: A novel extracellular matrix hydrogel from muscle. This project would have several sources of benefit for the community. Foremost we will have produced a product that will have a strong commercial application in several fields including basic science and bioengineering. If its full potential were achieved, the development of this innovative new hydrogel would strengthen Australia's standing in the biotechnology field and also enrich specific applic ....Characterization and optimisation of Myomatrix: A novel extracellular matrix hydrogel from muscle. This project would have several sources of benefit for the community. Foremost we will have produced a product that will have a strong commercial application in several fields including basic science and bioengineering. If its full potential were achieved, the development of this innovative new hydrogel would strengthen Australia's standing in the biotechnology field and also enrich specific applications. The knowledge gained from the characterization of this product could also be of benefit to several areas including chemical engineering, tissue engineering, tissue repair, polymer chemistry and food manufacture. The expertise generated and the possibility of collaboration, both academic and with industry would also benefit the community. Read moreRead less