The Development Of Novel, Biofilm-resistant Biomaterials
Funder
National Health and Medical Research Council
Funding Amount
$147,360.00
Summary
Almost all patients who are catheterised long term develop a bacterial infection. Most often, the infection is the result of colonisation of the catheter surface by bacteria. Bacterial colonisation of the surface of biomedical devices represents a significant health threat as such bacterial biofilms are extremely resistant to traditional antibiotic regimens. This project aims to develop novel materials that prevent bacterial colonisation on catheters and other biomedical related devices. Our tec ....Almost all patients who are catheterised long term develop a bacterial infection. Most often, the infection is the result of colonisation of the catheter surface by bacteria. Bacterial colonisation of the surface of biomedical devices represents a significant health threat as such bacterial biofilms are extremely resistant to traditional antibiotic regimens. This project aims to develop novel materials that prevent bacterial colonisation on catheters and other biomedical related devices. Our technology is based on compounds identified from a marine alga that prevent bacterial colonisation of its surface. Similarly, we have shown that these compounds, when coated onto test surfaces, prevent bacterial colonisation of a range of materials.Read moreRead less
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.
Acoustic Blood Pressure Measurement On Implanted Biomedical Surfaces
Funder
National Health and Medical Research Council
Funding Amount
$184,687.00
Summary
Measurement of local blood pressure in is of great clinical importance. An application of particular interest is the pressure measurement in and around endoluminal stents grafts, which are used for the treatment of Abdominal Aortic Aneurysms (AAAs). These grafts are implanted by keyhole surgery and are used to reduce the pressure on the aneurysm walls so that the artery can revert to its more anatomically correct shape on a timescale of one to two years. If the seal between the graft and the art ....Measurement of local blood pressure in is of great clinical importance. An application of particular interest is the pressure measurement in and around endoluminal stents grafts, which are used for the treatment of Abdominal Aortic Aneurysms (AAAs). These grafts are implanted by keyhole surgery and are used to reduce the pressure on the aneurysm walls so that the artery can revert to its more anatomically correct shape on a timescale of one to two years. If the seal between the graft and the artery wall is not blood tight, then the aneurysm can become repressurised and may keep on expanding. Over time, an untreated, expanding AAA is likely to rupture with severe consequences for the patient. Thus a convenient, non-invasive means of measuring the pressure within the aneurysm and within the graft is highly desirable. In this proposal, we seek to produce a device that can be incorporated into the walls of the endoluminal graft, which can measure absolute pressure inside and outside the graft and where the pressure measurements can be obtained via standard acoustic or medical ultrasound equipment. To do this, we would use specially designed 'bubbles' which can be incorporated onto either side of the graft walls, where the resonant frequency of the bubbles provides a direct measurement of the pressure around the bubbles. Trials at the CSIRO have found that pressures can be measured to a resolution of better than 10 mmHg by using this technique on air bubbles in water. In this proposal, we wish to develop flexible, but semi-permanent bubbles that can be incorporated onto a biomedical implant surface. If such bubbles can be made, the researchers will use CSIRO-developed software and acoustic equipment such that local blood pressure can be measured in real time.Read moreRead less