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.
Biocompatible Synthetic Conduits To Treat Vascular Disease
Funder
National Health and Medical Research Council
Funding Amount
$421,818.00
Summary
Clinically available synthetic conduits used in vascular repair and bypass are fundamentally incompatible with the vasculature. 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 all polymeric materials and have shown a significant improvement in their compatibility. Grafts coated using our technology stand to dramatically improve the treatment of vascular diseas ....Clinically available synthetic conduits used in vascular repair and bypass are fundamentally incompatible with the vasculature. 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 all polymeric materials and have shown a significant improvement in their compatibility. Grafts coated using our technology stand to dramatically improve the treatment of vascular disease.Read moreRead less
Development of a Prothrombogenic Bone Graft Substitute. The clinical demand for bone is massive and to counter this bone can be either harvested from the patient or bone substitutes are used. The success or failure of a bone substitute is determined the instant it come into contact with blood. The surfaces of traditional biomaterials induce a foreign body reaction. The aim of this project is to test the bone forming capacity of a biomaterial that is optimised to produce a natural response from ....Development of a Prothrombogenic Bone Graft Substitute. The clinical demand for bone is massive and to counter this bone can be either harvested from the patient or bone substitutes are used. The success or failure of a bone substitute is determined the instant it come into contact with blood. The surfaces of traditional biomaterials induce a foreign body reaction. The aim of this project is to test the bone forming capacity of a biomaterial that is optimised to produce a natural response from the blood. This response will lead to the formation new viable tissue and eventually bone. Such a material will cause faster bone healing, less pain from graft sites, shorter hospital stays and shorter waiting lists. Read moreRead less
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.
Development Of Endovascular Stents With Proactive Biocompatibility
Funder
National Health and Medical Research Council
Funding Amount
$428,470.00
Summary
Metallic cardiovascular implants, such as stents, used in the treatment of heart disease are not compatible with blood. They cause inflammation at the site of implantation and increase the risk of blood clots forming. We have developed a unique method of binding bioactive protein layers to the surface of metal alloys, and shown a significant improvement in their compatibility. Stents coated using our technology stand to dramatically improve the treatment of cardiovascular disease.
Development of a Light-Activated Bioadhesive for Low Temperature Tissue Repair. While sutures currently represent the gold standard for wound closure, their fundamental technology has changed little in thousands of years. Surgical sealants and energy based closure devices are expected to increasingly replace or complement sutures, improving tissue closure and wound healing. The innovative research in this proposal will develop the next generation of surgical bioadhesive technology and claim a s ....Development of a Light-Activated Bioadhesive for Low Temperature Tissue Repair. While sutures currently represent the gold standard for wound closure, their fundamental technology has changed little in thousands of years. Surgical sealants and energy based closure devices are expected to increasingly replace or complement sutures, improving tissue closure and wound healing. The innovative research in this proposal will develop the next generation of surgical bioadhesive technology and claim a stake in the estimated US$ 4 billion market. The project outcomes will enhance Australia's reputation in the biomedical field and will have world-wide social and health care benefits by ultimately allowing better functional healing through bioadhesives that can be effectively applied rapidly and consistently.Read moreRead less
Tissue Engineering of Human Heart Valve Grown In Vitro. Tissue engineering (TE) of heart valves is a new approach to cultivate a functional heart valve from human autologous cells. This innovative study aims to develop the technology to transplant cells onto a 3D biocompatible valve scaffold that is capable of mimicking native valve. The work proposed is a ground breaking study that will encompass development of a new biomaterial, manufacture of scaffolds using the Fused Deposition Modelling ra ....Tissue Engineering of Human Heart Valve Grown In Vitro. Tissue engineering (TE) of heart valves is a new approach to cultivate a functional heart valve from human autologous cells. This innovative study aims to develop the technology to transplant cells onto a 3D biocompatible valve scaffold that is capable of mimicking native valve. The work proposed is a ground breaking study that will encompass development of a new biomaterial, manufacture of scaffolds using the Fused Deposition Modelling rapid prototyping process, hemodynamic optimisation and in vitro cell culture. This will advance our knowledge in cellular and scaffold technologies and may ultimately lead to the development of a TE heart valve.Read moreRead less
Fluid dynamics and mechanical stress of tissue heart valves. Major problems with thrombo-embolic complications and leaflet failure and calcification still exist with bioprosthetic valves. Valves fabricated from polyether urethanes are efficient and can offer more resistance to calcification. No complete study on the haemodynamics and structure interactions is found in literature. Moreover, todate the effect of aortic wall motion on the blood flow has never been examined. A complete holistic ap ....Fluid dynamics and mechanical stress of tissue heart valves. Major problems with thrombo-embolic complications and leaflet failure and calcification still exist with bioprosthetic valves. Valves fabricated from polyether urethanes are efficient and can offer more resistance to calcification. No complete study on the haemodynamics and structure interactions is found in literature. Moreover, todate the effect of aortic wall motion on the blood flow has never been examined. A complete holistic approach to simulataneuosly simulating the fluid dynamics, the valve motion and the stress in a synthetic Polyether urethane valve is proposed. Cell adhesion study will also be carried out. The findings may yield to new insights into valve research.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