5D Imaging Flow Cytometry for in vivo Quantification of Biological Fluids. Rapid and accurate quantification of live biological fluid properties at sub-cellular and molecular levels forms the bedrock of biofluidic sciences. Majority of the biofluidic devices rely on quantifying biological fluids after its removal from the body in an in vitro Flow Cytometer (FC). FC faces many caveats i.e. biological degradation and small volume etc. In this project, we shall engineer the first in vivo 5D imaging ....5D Imaging Flow Cytometry for in vivo Quantification of Biological Fluids. Rapid and accurate quantification of live biological fluid properties at sub-cellular and molecular levels forms the bedrock of biofluidic sciences. Majority of the biofluidic devices rely on quantifying biological fluids after its removal from the body in an in vitro Flow Cytometer (FC). FC faces many caveats i.e. biological degradation and small volume etc. In this project, we shall engineer the first in vivo 5D imaging flow cytometer (5D IFC) capable of continuous assessment of potentially entire blood volume in a living mice without removing fluid out of the body. The project represents a major advancement beyond any existing flow cytometer and overcome the engineering limits of state-of-art laser scanning imaging devices.Read moreRead less
Thermodynamics inversion for mineral systems. This project aims to provide a newly developed science approach to the Australian Lithospheric Architecture Magnetotelluric Project (AusLAMP). AusLAMP provides unparalleled geophysical information aimed at unravelling the tectonic history of the Australian continent and its mineral potential. The project will use thermodynamically based geodynamic simulators to jointly analyse and quantify intraplate deformation. This will illuminate the cause of dri ....Thermodynamics inversion for mineral systems. This project aims to provide a newly developed science approach to the Australian Lithospheric Architecture Magnetotelluric Project (AusLAMP). AusLAMP provides unparalleled geophysical information aimed at unravelling the tectonic history of the Australian continent and its mineral potential. The project will use thermodynamically based geodynamic simulators to jointly analyse and quantify intraplate deformation. This will illuminate the cause of driving fluid flow thorough the lithosphere, mineralisation phenomena, their datasets and geometries, and dynamic aspects of the processes driving mineral systems.Read moreRead less
Environmentally sustainable shipping through improved understanding and management of wall-bounded turbulence. The thin region of turbulent flow that is pulled along by a ship's hull as it moves through the water accounts for up to 90 per cent of the overall resistance and a large amount of the fuel burnt. This project aims to control or tame recurrent flow patterns within these turbulent regions to reduce resistance, overall fuel cost and emissions from shipping.
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: LE120100043
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Development of an ultra-high speed spinning disk confocal micro-particle image velocimetry (PIV) platform for the investigation of cardiovascular disease . This facility will establish a microscope system specifically designed to investigate the function of blood cells in the context of cardiovascular diseases such as heart attack and stroke.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100181
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
Strengthening merit-based access and support at the new National Computing Infrastructure petascale supercomputing facility. World-leading high-performance computing is fundamental to Australia's international research success. This facility will provide access to the new National Computational Infrastructure facility by world-leading researchers from six research universities, and sustain ground-breaking work in an increasingly competitive environment.