Engineering Imaging and Supercomputer Prediction of Biofluid Flows. The potential of the information gained from the lung imaging for improving the diagnosis and monitoring of adult respiratory diseases, such as emphysema, pulmonary fibrosis and asthma, is enormous. Abnormalities in the structure and function of the kidney circulation are likely key factors causing hypertension, so a detailed understanding of the kidney circulation is required before we can cure or prevent hypertension. The rese ....Engineering Imaging and Supercomputer Prediction of Biofluid Flows. The potential of the information gained from the lung imaging for improving the diagnosis and monitoring of adult respiratory diseases, such as emphysema, pulmonary fibrosis and asthma, is enormous. Abnormalities in the structure and function of the kidney circulation are likely key factors causing hypertension, so a detailed understanding of the kidney circulation is required before we can cure or prevent hypertension. The research underpinning cardiovascular and renal flows will assist in the understanding of hypertension, a major risk factor for cardiovascular disease, which accounts for approximately 40% of all deaths in Australia and particularly high for dialysis patients. Read moreRead less
Creation of functional surfaces for biodevices and aerospace applications. Polymers are poised to become the materials of choice for a host of applications because of their lightness, strength, ease of forming and biocompatibility. The major challenge lies in optimising their surfaces for each application. For biodevices in particular, the surfaces must support a range of complex and specific interactions. This project will create new polymer surface modifications through innovations in plasma s ....Creation of functional surfaces for biodevices and aerospace applications. Polymers are poised to become the materials of choice for a host of applications because of their lightness, strength, ease of forming and biocompatibility. The major challenge lies in optimising their surfaces for each application. For biodevices in particular, the surfaces must support a range of complex and specific interactions. This project will create new polymer surface modifications through innovations in plasma science and technology. The outcomes will be new surfaces for diagnostic arrays in medicine, biosensors and durable polymer surfaces for low earth orbit.Read moreRead less
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
Biomolecular films on silicon substrates. Construction of hybrid carbon-silicon devices in which molecular organic molecular films are covalently linked to silicon wafers. Biomolecular nanostructures on silicon wafers can be studied using unique impedance spectroscopy instrumentation that we have developed as well as X-ray and neutron reflectometry. The system will be used to study a variety of molecular films as well as molecularly tethered lipid bilayer membranes that mimic aspects of cell mem ....Biomolecular films on silicon substrates. Construction of hybrid carbon-silicon devices in which molecular organic molecular films are covalently linked to silicon wafers. Biomolecular nanostructures on silicon wafers can be studied using unique impedance spectroscopy instrumentation that we have developed as well as X-ray and neutron reflectometry. The system will be used to study a variety of molecular films as well as molecularly tethered lipid bilayer membranes that mimic aspects of cell membranes and these will be used to investigate the effect of sterols on such membranes.Read moreRead less
Bacterial cell behaviour in micro/nano-confined environments. The project aims to progress the understanding of the mechanisms of marine bacteria biofilm formation and surface-modulated metabolic response. We will adjust the surface characteristics of photopolymers (as ?model? surfaces) and probe the bacterial response to surfaces, passively with micro/nano-fabricated structures and Atomic Force Microscopy; and actively with optical manipulation of single cells. The results will contribute to th ....Bacterial cell behaviour in micro/nano-confined environments. The project aims to progress the understanding of the mechanisms of marine bacteria biofilm formation and surface-modulated metabolic response. We will adjust the surface characteristics of photopolymers (as ?model? surfaces) and probe the bacterial response to surfaces, passively with micro/nano-fabricated structures and Atomic Force Microscopy; and actively with optical manipulation of single cells. The results will contribute to the fundamental knowledge regarding central biological phenomena -down to single-cell processes- as well as on applied knowledge regarding the manufacturing of antimicrobial surfaces that mimic natural bactericide processes, with larger implications on biomedical practice, and environmental, civil, mining and manufacturing industrial applications.Read moreRead less