Physiology of oxygen transport in the mammalian kidney. This project aims to improve understanding of oxygen regulation in renal tissue and knowledge of the physiology of the kidney. The mammalian kidney receives more oxygen than it uses or needs, and yet renal tissue is commonly found to be hypoxic. This project proposes that oxygen transport to the renal tissue is limited by blood vessel surface area. The project expects to generate anatomical data currently missing from the renal physiology c ....Physiology of oxygen transport in the mammalian kidney. This project aims to improve understanding of oxygen regulation in renal tissue and knowledge of the physiology of the kidney. The mammalian kidney receives more oxygen than it uses or needs, and yet renal tissue is commonly found to be hypoxic. This project proposes that oxygen transport to the renal tissue is limited by blood vessel surface area. The project expects to generate anatomical data currently missing from the renal physiology community, and potentially change the accepted story of oxygen homeostasis in the kidney. This will provide significant benefits, such as the provision of the foundational physiological science behind a determinant of kidney health and its flow-on impact to quality of life.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101503
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Design of a biologically inspired running and climbing robotic lizard. Watch any movie and it will tell you that robots are the future. The trouble is that recent attempts to build running and climbing robots have had limited success. This project explores locomotion of lizards to improve upon shortfalls in current robotic design, to build biologically inspired robots capable of running and climbing up and down walls.
The comparative physiology of oxygen delivery to the kidney. The kidney is in danger of hyperoxia because the kidney receives so much blood relative to its mass. It is proposed that shunting oxygen between arteries and veins substantially mitigates the risk of hyperoxia, but under certain circumstances shunting substantially increases the risk of kidney hypoxia. Using a combination of synchrotron and histological imaging, This project will carefully define the three-dimensional vasculature of th ....The comparative physiology of oxygen delivery to the kidney. The kidney is in danger of hyperoxia because the kidney receives so much blood relative to its mass. It is proposed that shunting oxygen between arteries and veins substantially mitigates the risk of hyperoxia, but under certain circumstances shunting substantially increases the risk of kidney hypoxia. Using a combination of synchrotron and histological imaging, This project will carefully define the three-dimensional vasculature of the renal cortex in several different species and interpret its functional significance using computational modeling. The outcome of this project will be a new understanding in the comparative physiology of oxygen transport and shunting in the kidney.Read moreRead less
The acoustics of a wide-range autonomous oscillator: how do brass players do it? While brass instruments are well understood, the complexities of the interaction with the player are not. This study will analyse how the player's lips and vocal tract interact with the instrument, leading to an understanding not only of the interesting physics involved, but to insight that will benefit players, teachers and students.
Exploring the unseen: the adaptive significance of animal-visible and infrared colour change. Our research on benefits of rapid colour change in cold-blooded animals, spanning the full spectrum of solar energy, will provide novel insights into the adaptive significance of animal colour patterns. It will also provide a natural model for development of advanced colour-changing materials with a wide range of applications.
Calcium signalling by intracellular calcium stores in rabbit, mouse and man: implications for muscle performance and athletic ability. This project addresses essential vital life functions such as respiration and movement and factors that determine whether muscles are better suited to weight lifting, endurance or sprint activities. The outcome will fill an information gap and provide therapeutic targets, significant in medicine, sports and veterinary science.
Regulated muscle-based thermogenesis for body temperature regulation. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the skeletal muscles that are closer to the body core contribute the majority of heat, how the muscles of the limbs have their heat generation curtailed as necessary, and how this is coordinated by the body in response to ambient temperature. Project out ....Regulated muscle-based thermogenesis for body temperature regulation. Mammals maintain a constant core body temperature by generating heat in resting muscles in response to changes in the environmental temperatures. This project aims to show how the skeletal muscles that are closer to the body core contribute the majority of heat, how the muscles of the limbs have their heat generation curtailed as necessary, and how this is coordinated by the body in response to ambient temperature. Project outcomes include defining, for the first time, how heat generation in the muscles of the body is regulated. This should provide critical knowledge of mammalian evolution and ways to manipulate metabolism, which may provide ways to assist the production of meat by managing hypothermia and hyperthermia risk in agriculture.Read moreRead less
How cholesterol optimises ion pump function in animal membranes. This project aims to determine how cholesterol optimises ion pump function in animal membranes and to identify the major effects of cholesterol and its derivatives on membranes’ physical properties. All animal cells need high levels of cholesterol in the plasma membrane for survival. Insufficient cholesterol biosynthesis leads to severe birth defects. The need for cholesterol is likely linked to its acceleration of sodium pump acti ....How cholesterol optimises ion pump function in animal membranes. This project aims to determine how cholesterol optimises ion pump function in animal membranes and to identify the major effects of cholesterol and its derivatives on membranes’ physical properties. All animal cells need high levels of cholesterol in the plasma membrane for survival. Insufficient cholesterol biosynthesis leads to severe birth defects. The need for cholesterol is likely linked to its acceleration of sodium pump activity, essential to physiological processes including cell division, nerve, muscle and kidney activity. An expected benefit of the project is knowledge on the molecular origin of diseases associated with inhibition of cholesterol production, and a more complete understanding of the crucial role played by cholesterol via its effect on ion pumping towards the healthy functioning of vital organs, particularly in heart muscle and nerves.Read moreRead less
Lipid-protein interplay in the mechanism of the sodium pump. The sodium pump is the major energy-consuming enzyme of animal cells. Its ion pumping is essential to numerous physiological processes (e.g. nerve, muscle and kidney activity and the maintenance of cell volume). Because of its importance in so many cell functions, the enzyme must be able to respond to cellular conditions. Using measurements of the enzyme's activity in isolated membrane fragments and comparison with its behaviour in liv ....Lipid-protein interplay in the mechanism of the sodium pump. The sodium pump is the major energy-consuming enzyme of animal cells. Its ion pumping is essential to numerous physiological processes (e.g. nerve, muscle and kidney activity and the maintenance of cell volume). Because of its importance in so many cell functions, the enzyme must be able to respond to cellular conditions. Using measurements of the enzyme's activity in isolated membrane fragments and comparison with its behaviour in living cells, this project aims to determine how sodium pump activity is modulated by transmembrane electric potential and intramembrane electric field strength. Our project could provide fundamental new knowledge on how membrane protein function in general can be controlled by electrical properties of their lipid surroundings.Read moreRead less
Molecular force sensing mechanisms of PIEZO channels. The aim of this project is to characterise the gating mechanism of Piezo mechanosensitive ion channels recently identified in animals and humans. Mechanotransduction is ancient, as indicated by the presence of mechanosensitive channels in bacteria where these channels are activated by the bilayer mechanism according to the force-from-lipids paradigm possibly applicable to gating of the Piezo channels as well. Piezo channels play a crucial rol ....Molecular force sensing mechanisms of PIEZO channels. The aim of this project is to characterise the gating mechanism of Piezo mechanosensitive ion channels recently identified in animals and humans. Mechanotransduction is ancient, as indicated by the presence of mechanosensitive channels in bacteria where these channels are activated by the bilayer mechanism according to the force-from-lipids paradigm possibly applicable to gating of the Piezo channels as well. Piezo channels play a crucial role in senses of touch and pain, and mutations in Piezo1 have been shown to cause Xerocytosis – a hereditary genetic disorder manifested in haemolytic anemia. This project aims to help answer fundamental questions in mechanotransduction in vertebrates.Read moreRead less