Optimizing blood flow in stented arteries: a fluid mechanics approach incorporating optical coherence tomography. Constriction in coronary arterial blood flow is a leading cause of death in Australia. Insertion of stents can rectify this problem but potentially lead to further complications. This project will use medical imaging data to construct computer models to study blood flow and particle motions in coronary arteries and improve stent designs.
Optimising haemodynamics in complex stented arteries. This project aims to optimise the hemodynamics (blood flow) in coronary arteries with high curvatures and bifurcations. Experience has shown that the build-up of plaque — and the resulting occlusion of blood flow — tends to occur in these complex arterial regions. The most common therapeutic strategy is the insertion of a stent to prop open the artery. However, the nature of the geometry often leads to post-stenting complications such as rest ....Optimising haemodynamics in complex stented arteries. This project aims to optimise the hemodynamics (blood flow) in coronary arteries with high curvatures and bifurcations. Experience has shown that the build-up of plaque — and the resulting occlusion of blood flow — tends to occur in these complex arterial regions. The most common therapeutic strategy is the insertion of a stent to prop open the artery. However, the nature of the geometry often leads to post-stenting complications such as restenosis and thrombosis, ultimately resulting in negative outcomes. In this project, advanced research methods from fluid dynamics and optimisation and control will be used to potentially minimise these highly undesirable effects.Read moreRead less
Aerodynamic interaction of bluff bodies with applications to sports aerodynamics. Numerical modelling and experiments will be combined by this project to characterise the flow and reduce drag on a set of objects in the wake of another object. The Olympic pursuit cycling team is a typical application, with small improvements leading to major competitiveness gains. Findings will also apply to Paralympic team sports, and potentially transportation.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100166
Funder
Australian Research Council
Funding Amount
$637,800.00
Summary
Four-dimensional coherent imaging velocimetry facility for fluid mechanics research. This project aims to enhance understanding of multi-scale fluid flows in engineering, geophysics and biomedicine by delivering a facility for high temporal and spatial resolution, three-dimensional velocity measurements. The four-dimensional, coherent imaging velocimetry facility for fluid mechanics research is aimed at addressing limitations of commercially available imaging systems. It is expected to provide ....Four-dimensional coherent imaging velocimetry facility for fluid mechanics research. This project aims to enhance understanding of multi-scale fluid flows in engineering, geophysics and biomedicine by delivering a facility for high temporal and spatial resolution, three-dimensional velocity measurements. The four-dimensional, coherent imaging velocimetry facility for fluid mechanics research is aimed at addressing limitations of commercially available imaging systems. It is expected to provide unprecedented measurement capabilities with significant benefit to the design, control and modelling of complex fluid flows found in many areas. Applications include the jets used for heating, cooling, mixing, and drug delivery in engineering and pharmacy to the kinematics of sperm and micro-organisms in bio-medicine, and wave-particle flows in geo-physics.Read moreRead less