HARNESSING THE PHYSIOLOGICAL EFFECTS OF STRONTIUM AND ZINC TO PRODUCE NOVEL BIOMATERIALS FOR ORTHOPAEDIC APPLICATIONS
Funder
National Health and Medical Research Council
Funding Amount
$560,082.00
Summary
Large skeletal defects resulting from congenital defects or disease processes are challenging to regenerate and represent a major financial burden to our health system. Bone graft treatments are widely used but have considerable drawbacks. Available synthetic alternatives lack the physical-biological properties necessary. We have developed new scaffolds with improved mechanical-biological properties for bone regeneration.
Regulating Astrocytosis For Appropriate Defence And Repair Of The Brain After Injury
Funder
National Health and Medical Research Council
Funding Amount
$562,742.00
Summary
An inflammatory process, designed to clean up cell debris and maintain tissue integrity following brain insult, also results in an astrocytic scar that biochemically impedes nerve repair. After 8 weeks astrocytes switch to become supportive, however once a scar is formed repair is permanently inhibited. Here, we will test the ability of biomaterials to optimise the timing of the necessary inflammatory phase, to encourage repair by converting astrocytes to their tropic phase more rapidly.
Novel Biocompatible Nickel-free Shape Memory Alloy Scaffolds For Biomedical Applications
Funder
National Health and Medical Research Council
Funding Amount
$530,789.00
Summary
The current project is aimed at the development of a new class of novel biocompatible nickel-free shape memory alloy (SMA) scaffolds for metallic implant applications. The new scaffolds possess the ability to exert a mechanical force on the surrounding bones, and stimulate new bone tissue ingrowth, due to their shape memory effect, superelasticity and bone-mimicking porous structure. The outcomes from this project will provide innovative implant materials.
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.
Bioengineering Endovascular Prostheses With Proactive Biocompatibility
Funder
National Health and Medical Research Council
Funding Amount
$627,950.00
Summary
Metallic cardiovascular implants, such as stents, used in the treatment of heart disease are not compatible with blood. They cause inflammation at the site of implantation and increase the risk of blood clots forming. We have developed a unique method of binding bioactive protein layers to the surface of metal alloys, and shown a significant improvement in their compatibility. Stents coated using our technology stand to dramatically improve the treatment of cardiovascular disease.
Pre-clinical Validation Of A Novel Implant For Bone Tissue Engineering
Funder
National Health and Medical Research Council
Funding Amount
$435,767.00
Summary
The aim of this grant to was examine a new method for manufacturing implants to improve repair of critical bone defects. It involves new technology for the manufacture of porous scaffolds and testing their delivery in a biological, bone repair setting.
Building Tissue Engineered Flaps For Surgical Reconstruction
Funder
National Health and Medical Research Council
Funding Amount
$548,453.00
Summary
As a result of serious trauma, burns or cancer surgery, large areas of new skin may be required. Of the three major skin layers - epidermal and dermal replacements are available clinically, but the third layer - the underlying fat tissue layer is yet to be developed. This project has devised a novel product to rapidly recreate the skin fat layer and additionally rapidly grow new blood vessels in these layers which will enable excellent skin coverage in all forms of major skin loss.
Bioengineering Synthetic Elastin Conduits For Arterial Revascularisation
Funder
National Health and Medical Research Council
Funding Amount
$624,776.00
Summary
An arterial substitute with both physical and biological properties that mimic those of the human vasculature has long been the holy grail of vascular tissue engineering. We propose synthetic elastin can form the basis of a durable, clinically effective small diameter vascular graft and fill a significant unmet need for a biocompatible vascular substitute.
This project aims to develop a novel class of drugs with the potential to overcome the stability problems previously associated with protein-based drugs. We will develop novel molecules for the treatment of cancer and cardiovascular disease. This project has the potential to lead to major economic and social benefits to Australia via royalty returns from drug sales and reduced costs for health care for patients with these diseases.