Effects Of Fast Versus Slow Weight Loss On Fat, Muscle And Bone In Postmenopausal Women
Funder
National Health and Medical Research Council
Funding Amount
$316,450.00
Summary
Very low energy diets (VLED) are increasingly used to treat obesity. Of concern is the fact that VLED induce adaptive responses that can inhibit loss of, and promote regain of, abdominal fat while decreasing lean body mass, muscle strength and bone density. This project will therefore determine whether VLEDs could have negative effects on body composition that increase the risk of metabolic disease, sarcopenia or osteoporosis, and if so, what mechanisms are involved.
Suppression Of NADPH Oxidase-derived Oxidative Stress By Anti-sense Probes And HDL In Human Vascular Endothelium
Funder
National Health and Medical Research Council
Funding Amount
$455,250.00
Summary
In Australia, coronary heart disease (CHD) causing heart attacks remains the largest cause of death, claiming a staggering 28,000 lives a year. Oxidative stress, resulting from increased production of oxygen free radicals in arteries, is an important cause of CHD, heart attacks and strokes. We seek to understand how such oxyradicals are produced in the key cells that form the lining of all arteries, known as the vascular endothelium. By using novel DNA-type molecules (known as anti-sense) develo ....In Australia, coronary heart disease (CHD) causing heart attacks remains the largest cause of death, claiming a staggering 28,000 lives a year. Oxidative stress, resulting from increased production of oxygen free radicals in arteries, is an important cause of CHD, heart attacks and strokes. We seek to understand how such oxyradicals are produced in the key cells that form the lining of all arteries, known as the vascular endothelium. By using novel DNA-type molecules (known as anti-sense) developed in our laboratory, which block a particular gene causing oxidative stress, we will determine whether this gene is responsible for the formation of oxyradicals in human and mouse cells grown in culture. In addition, we will explore whether this gene is turned on by factors known to be involved in CHD. Finally, we will also investigate whether the good cholesterol known as HDL can act to prevent oxidative stress in human cells, as we discovered it appears to do in living arteries in vivo. If we find it has the same protective effect in endothelium, we will determine how it does this, and which component proteins of the HDL particle are important. This might suggest new treatments to prevent acute events leading to heart attack and stroke, and possibly new applications where damage appears to result from acute oxidative stress, such as in the brain soon after a stroke has occurred. We also have a plan to develop antisense drugs that will target the important gene specifically in the affected endothelium. In addition, we have other specific new drugs that will block this system in arteries. Simultaneously we will be testing the role of this gene in mouse and rabbit models of artery disease, for both our types of drugs might provide valuable new therapeutic agents to target the underlying cause of CHD and not just its symptoms as current drugs do.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100627
Funder
Australian Research Council
Funding Amount
$436,250.00
Summary
Topological phonons in solids. This project aims to create a complete list of possible topological phonons in time-reversal-invariant systems via symmetry analysis, to determine ideal topological phononic materials, and to study topological phonon-related properties and possible applications. The significant outcomes of this project will be the generation of new knowledge that will help conclude the search for novel topological phonons and the prediction of novel topological phononic materials b ....Topological phonons in solids. This project aims to create a complete list of possible topological phonons in time-reversal-invariant systems via symmetry analysis, to determine ideal topological phononic materials, and to study topological phonon-related properties and possible applications. The significant outcomes of this project will be the generation of new knowledge that will help conclude the search for novel topological phonons and the prediction of novel topological phononic materials based on the complete classification list of topological phonons. The outcomes of this project should unlock the physics of the exotic topological phonons and lay a solid foundation for applying topological phononic materials based on their unprecedented properties.Read moreRead less
Hot Topic: Quantum Design of Phononic Heat Filters. Heat management is critical to many technologies for sustainable energy, electronics, protective equipment and energy-efficient buildings. The phonon is the quantum particle representing a travelling vibration and is responsible for the transmission of heat in solids. This project will study the new mechanisms for phonon transport in solids modified with embedded nanoparticles, which operate as phononic filters. Neutron spectroscopy provides a ....Hot Topic: Quantum Design of Phononic Heat Filters. Heat management is critical to many technologies for sustainable energy, electronics, protective equipment and energy-efficient buildings. The phonon is the quantum particle representing a travelling vibration and is responsible for the transmission of heat in solids. This project will study the new mechanisms for phonon transport in solids modified with embedded nanoparticles, which operate as phononic filters. Neutron spectroscopy provides a tool to measure the phonon density of states which is critical for developing a mathematical model of thermal boundary resistance. This is expected to identify mechanisms for ultra-low thermal conductivity leading to potential applications in thermoelectric generators and heat-resistant materials.Read moreRead less
Liquid Metal Interfaces – A Novel Platform for Catalysis. This project aims to develop the basic design principles that govern the performance of liquid metal alloy catalysts for the methane pyrolysis reaction and manufacturing of ammonia. The project expects to generate new knowledge in understanding the reaction dynamics occurring at the gas-liquid metal interface under true working conditions and the composition-catalytic activity relationships of multi-component liquid alloy catalysts throug ....Liquid Metal Interfaces – A Novel Platform for Catalysis. This project aims to develop the basic design principles that govern the performance of liquid metal alloy catalysts for the methane pyrolysis reaction and manufacturing of ammonia. The project expects to generate new knowledge in understanding the reaction dynamics occurring at the gas-liquid metal interface under true working conditions and the composition-catalytic activity relationships of multi-component liquid alloy catalysts through a combined experimental and computational/theoretical approach. The expected outcomes are new liquid metal alloys that open the gateway to a new dimension of catalytic applications. The project should benefit Australia’s key societal challenges of emissions reduction, hydrogen storage and food security.Read moreRead less
An In Depth Analysis Of Clinical And Virological Outcomes Of 2 Strategies For The Antiretroviral Salvage Of First-line Regimen Virological Failure For HIV-1 Infection Tested In An Australian-led Randomised, International, Multi-centre Clinical Trial
Funder
National Health and Medical Research Council
Funding Amount
$421,747.00
Summary
The recently completed Australian-led SECOND-LINE trial is the first high quality study to provide reliable evidence for policy recommendations for the composition of anti-HIV drug cocktails after standard initial treatment has failed. This award will support the researcher in further refining our understanding of how to manage second-line therapy including proposals to test the use of low-cost technologies for application in resource-limited settings where the majority of people with HIV live.
Complex Interfaces and Solid-State Precipitation in Advanced Materials. Solid-state precipitates are key features of the microstructures of many natural and artificial materials and govern their properties. Yet understanding, let alone designing, the microstructures of materials remains a formidable challenge. The recent discovery of a new class of embedded interfaces in aluminium alloys offers the prospect of determining the atomic-scale mechanisms of precipitation. This project aims to apply t ....Complex Interfaces and Solid-State Precipitation in Advanced Materials. Solid-state precipitates are key features of the microstructures of many natural and artificial materials and govern their properties. Yet understanding, let alone designing, the microstructures of materials remains a formidable challenge. The recent discovery of a new class of embedded interfaces in aluminium alloys offers the prospect of determining the atomic-scale mechanisms of precipitation. This project aims to apply the latest microscopy and computational techniques synergistically to characterise such interfaces and develop atomic-scale mechanisms of nucleation and growth in model alloy systems. It is expected that this work will constitute a major step towards practical control of solid-state precipitation in technologically important materials.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101499
Funder
Australian Research Council
Funding Amount
$355,801.00
Summary
First-principles design and characterisation of topological materials. It has long been predicted that materials may contain special topological order. The recent discovery of topological insulators reveals the tip of the iceberg, but many theoretical hypotheses, such as the existence of the fractional Chern insulator and quantum spin liquid, remain elusive. This project aims to bridge the gap between conceptual models and real materials by using first-principles calculations. The plan is to ide ....First-principles design and characterisation of topological materials. It has long been predicted that materials may contain special topological order. The recent discovery of topological insulators reveals the tip of the iceberg, but many theoretical hypotheses, such as the existence of the fractional Chern insulator and quantum spin liquid, remain elusive. This project aims to bridge the gap between conceptual models and real materials by using first-principles calculations. The plan is to identify and engineer topological electronic bands in experimentally feasible materials, characterise existing quantum frustrated materials and connect these materials with minimal theoretical models. This project also aims to reveal further families of topological materials and clarify their physical properties.Read moreRead less
Rational Design of Novel Multiferroic Materials for Energy Harvesting and Energy Efficiency. Multiferroics are a class of fundamentally complex materials in which several ferroic orders (for example, ferroelectric and ferromagnetic) coexist. The coupling between their electric and magnetic degrees of freedom is controllable via stress and external fields, thus opening the possibility for breakthrough technological developments. By working at the frontier of complex nanostructured oxide materials ....Rational Design of Novel Multiferroic Materials for Energy Harvesting and Energy Efficiency. Multiferroics are a class of fundamentally complex materials in which several ferroic orders (for example, ferroelectric and ferromagnetic) coexist. The coupling between their electric and magnetic degrees of freedom is controllable via stress and external fields, thus opening the possibility for breakthrough technological developments. By working at the frontier of complex nanostructured oxide materials, this project aims to establish the rational basis for systematic design of novel artificially layered multiferroics, develop accurate and computationally affordable methods to simulate these materials under finite-temperature conditions, and exploit this knowledge to devise likely revolutionary photovoltaic, nanoelectronic and energy conversion applications.Read moreRead less