Application of Silver Coatings to medical Devices for Antimicrobial Properties using Electroless Deposition. Silver compounds, eg. in topical creams, can be used to treat chronic infections. The results are mediocre, and there may be significant side effects. Metallic silver when coated on bandages or medical devices is gaining wider acceptance, but the dissolution rate muct be improved to minimise infection. In this project an electroless silver coating process will be developed, with bath ch ....Application of Silver Coatings to medical Devices for Antimicrobial Properties using Electroless Deposition. Silver compounds, eg. in topical creams, can be used to treat chronic infections. The results are mediocre, and there may be significant side effects. Metallic silver when coated on bandages or medical devices is gaining wider acceptance, but the dissolution rate muct be improved to minimise infection. In this project an electroless silver coating process will be developed, with bath chemistry and coating conditions optimised for an ideal dissolution rate. This project will lead to the development of improved medical devices that will have significant social and economic benefits for Australia.Read moreRead less
Advanced Intramedullary Nailing Systems. The proposed project is aimed at developing advanced orthopaedic implants (intramedullary nails and associated locking screws) commonly used for bone fracture repair. These new generation metallic implants will be developed using a comprehensive research approach centred on physico-chemical and mechanical properties investigations. A new generation of intramedullary nailing systems with superior design and mechanical properties (small diameter and high st ....Advanced Intramedullary Nailing Systems. The proposed project is aimed at developing advanced orthopaedic implants (intramedullary nails and associated locking screws) commonly used for bone fracture repair. These new generation metallic implants will be developed using a comprehensive research approach centred on physico-chemical and mechanical properties investigations. A new generation of intramedullary nailing systems with superior design and mechanical properties (small diameter and high strength) and improved bone fixation is the key expected outcome. The knowledge generated in the project is expected to lead to the growth of the Industry Partner (Austofix). Training of a world class researcher in the multidisciplinary field of biomaterials will be an additional outcome.Read moreRead less
Plasma processes for optimising the performance of surfaces for biomedical applications. Australia faces a number of pressing problems in health care, including an aging population, environmental damage control and national security, which can be addressed, in part, by effectively interface synthetic materials surfaces with biological systems. Examples of technologies relying on such functional interfaces include implantable medical devices and prostheses, enzymatic conversion of chemicals and w ....Plasma processes for optimising the performance of surfaces for biomedical applications. Australia faces a number of pressing problems in health care, including an aging population, environmental damage control and national security, which can be addressed, in part, by effectively interface synthetic materials surfaces with biological systems. Examples of technologies relying on such functional interfaces include implantable medical devices and prostheses, enzymatic conversion of chemicals and waste, as well as diagnostic arrays and biosensors. The new understanding of fundamental surface properties driving these interactions, together with the new surface modification processes developed in this project, will drive new technologies in these important areas.Read moreRead less
Covalent Immobilisation of Growth Factors on Plasma Modified Titanium for Achieving Enhanced Bone Growth and Bonding in Implant Prosthetics. This project is aimed at improving the fixation of titanium implants by combining the surface technologies expertise of University of South Australia and Flinders University with TGR BioSciences's growth factors expertise. Plasma modified and hydroxyapatite-coated implant surfaces will be used for covalent immobilisation of growth factors via tethers with ....Covalent Immobilisation of Growth Factors on Plasma Modified Titanium for Achieving Enhanced Bone Growth and Bonding in Implant Prosthetics. This project is aimed at improving the fixation of titanium implants by combining the surface technologies expertise of University of South Australia and Flinders University with TGR BioSciences's growth factors expertise. Plasma modified and hydroxyapatite-coated implant surfaces will be used for covalent immobilisation of growth factors via tethers with tailored wettability and flexibility. This innovative strategy is expected to yield high retention of growth factor bioactivity and increased bone-implant integration for long-term implant stability. Knowledge, expertise and techniques developed will help TGR BioSciences expanding its research base and business. Training of students in the emerging field of nano-biotechnology will be another major outcome.Read moreRead less
Next generation closed-loop brain-machine interfaces . Our partners Carbon Cybernetics have developed high-density neural recording and stimulation arrays that employ fine carbon fibres as the electrode material. The aim of the project is to exploit the properties of these materials to develop miniature implantable devices that are able to achieve long-term, closed-loop, high-resolution recording and stimulation within the brain. We aim to demonstrate an advanced algorithm for control of neural ....Next generation closed-loop brain-machine interfaces . Our partners Carbon Cybernetics have developed high-density neural recording and stimulation arrays that employ fine carbon fibres as the electrode material. The aim of the project is to exploit the properties of these materials to develop miniature implantable devices that are able to achieve long-term, closed-loop, high-resolution recording and stimulation within the brain. We aim to demonstrate an advanced algorithm for control of neural function. Devices that interface directly with the brain are increasingly important in neuroscience to understand how the brain processes information and creates memories and self awareness and are critically important to the development of technologies that interface electronics with the human body. Read moreRead less