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Innovative Antimicrobial Treatments For Successful Bone Allografts
Funder
National Health and Medical Research Council
Funding Amount
$473,706.00
Summary
Bone healing sites are commonly infected, and this is associated with adverse clinical and significant socioeconomic outcomes. These studies will determine whether our novel antimicrobials can be used to reduce bone infections by studying the combination of antimicrobials and bone in laboratory and bone fracture studies whilst minimising the potential of developing antibiotic resistance.
Development And Evaluation Of Novel Antibacterial Coatings For The Prevention Of Infection On Biomedical Devices
Funder
National Health and Medical Research Council
Funding Amount
$284,402.00
Summary
This project aims to develop infection-resistant coatings that can be applied to a wide range of biomedical devices used in human health care. Novel antibacterial compounds from Australian plants (genus Eremophila) will be coated as thin layers onto model materials used for biomedical device fabrication, then onto real-life biomedical products and evaluated for ability to deter colonization by biofilm-forming human pathogenic bacteria.
Star Polymers As Novel Antimicrobial And Immunomodulatory Agents
Funder
National Health and Medical Research Council
Funding Amount
$945,908.00
Summary
The rise in antibiotic resistance in bacteria is considered as a major public health threat that is not being met by antibiotic research. This project will modify a novel star polymer that we have shown kills antibiotic resistant bacteria but does not induce resistance. The project will make and characterise new versions of the star polymer to produce antimicrobial materials that target and kill the multi-drug resistant bacteria that are a major cause of bacterial infections and death.
Advanced Nanostructured Biointerfaces for Cell Capture. The expected outcomes of this interdisciplinary project, which apply the most recent advances in nanotechnology and biophysics to cancer research, will enhance Australia's capacity in Frontier Technology and build strength in Nanobiotechnology. They will bring competitive advantages to the Australian biotechnology and biomedical community for further developments and applications in the multi-billion dollar field of biodiagnostics. These in ....Advanced Nanostructured Biointerfaces for Cell Capture. The expected outcomes of this interdisciplinary project, which apply the most recent advances in nanotechnology and biophysics to cancer research, will enhance Australia's capacity in Frontier Technology and build strength in Nanobiotechnology. They will bring competitive advantages to the Australian biotechnology and biomedical community for further developments and applications in the multi-billion dollar field of biodiagnostics. These innovative biodiagnostic strategies will potentially achieve a significant step in the direction of the once elusive goal of early detection and improved understanding of cancer.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
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.
Surface engineering of biomaterials for optimal bone bonding characteristics. The ideal bone-implant material is hydroxyapatite. Chemically similar to bone mineral, hydroxyapatite is capable of inducing bone ongrowth. An ideal surface coating for metal hip implants, plasma spraying has been the preferred commercial hydroxyapatite coating technique. Until recently, it was always presumed that the bioactivity of hydroxyapatite resulted from its surface chemistry. However, a recent study has shown ....Surface engineering of biomaterials for optimal bone bonding characteristics. The ideal bone-implant material is hydroxyapatite. Chemically similar to bone mineral, hydroxyapatite is capable of inducing bone ongrowth. An ideal surface coating for metal hip implants, plasma spraying has been the preferred commercial hydroxyapatite coating technique. Until recently, it was always presumed that the bioactivity of hydroxyapatite resulted from its surface chemistry. However, a recent study has shown that the bioactivity of HAp coatings strongly correlates with surface roughness on the scale of bone cells. This project will explore cell-attachment behaviour for hydroxyapatite coatings prepared by plasma spraying compared with engineered surface morphology/chemistry by microlithography and vapour coating.Read moreRead less
Numerical investigation of signal mechanotransduction of bone cells - application to bone remodeling. The understanding of signal mechanotransduction of bone cells is directly related to mechanical activation of bone remodeling processes, i.e., resorption and formation of bone tissue. Understanding of bone remodeling is essential for the development of new bone implants, the prognosis of osteosporosis, and studies related to changes in microgravity (e.g. space flight) to name a few key applicati ....Numerical investigation of signal mechanotransduction of bone cells - application to bone remodeling. The understanding of signal mechanotransduction of bone cells is directly related to mechanical activation of bone remodeling processes, i.e., resorption and formation of bone tissue. Understanding of bone remodeling is essential for the development of new bone implants, the prognosis of osteosporosis, and studies related to changes in microgravity (e.g. space flight) to name a few key applications. This research proposal closely aligns with one of the major national research priorities, i.e., promoting and maintaining good health (ageing well, ageing productively). The research project is aimed to understand how mechanically induced loading may activate remodeling of bone.
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Bio-MEMS eye sensor for continuous monitoring of intraocular pressure. Glaucoma is a leading cause of preventable blindness, particularly prevalent in the 60+ population, caused by elevated intraocular pressure (IOP). Current treatment to monitor and prevent glaucoma-related blindness is by lowering IOP with eye-drops, laser therapy or surgery. This project directly benefits our aging population by ensuring independence and quality of life, whilst reducing long-term medical and social costs. By ....Bio-MEMS eye sensor for continuous monitoring of intraocular pressure. Glaucoma is a leading cause of preventable blindness, particularly prevalent in the 60+ population, caused by elevated intraocular pressure (IOP). Current treatment to monitor and prevent glaucoma-related blindness is by lowering IOP with eye-drops, laser therapy or surgery. This project directly benefits our aging population by ensuring independence and quality of life, whilst reducing long-term medical and social costs. By incorporating nanotechnology with ophthalmology we will provide an economic solution to long-term, reliable, home-monitoring of IOP. An implantable IOP sensor, will identify patients requiring more invasive treatment compared with those with less aggressive disease, leading to better health resource utilisation.Read moreRead less
Tissue distraction: A novel approach to enhance tissue growth for soft tissue engineering purposes. This project will provide new tissues for the expanding field of regenerative medicine to treat numerous tissue defects and
1.Benefit the health & economic well being of Australian society by rapidly supplying organs and tissues.
2.Benefit the academic community by a multidisciplinary approach, involving several academic Institutions in the fields of surgery, tissue engineering, physiology, morph ....Tissue distraction: A novel approach to enhance tissue growth for soft tissue engineering purposes. This project will provide new tissues for the expanding field of regenerative medicine to treat numerous tissue defects and
1.Benefit the health & economic well being of Australian society by rapidly supplying organs and tissues.
2.Benefit the academic community by a multidisciplinary approach, involving several academic Institutions in the fields of surgery, tissue engineering, physiology, morphology, polymer chemistry & biomolecular engineering that will produce basic scientific data with a practical application. Post-graduate students and staff will train & gain significant knowledge in this area.
3. Benefit industry through new product development and IP. This project advances a platform technology with multiple applications.Read moreRead less