Unified framework of intestinal motility. The project aims to establish how a few fundamental mechanisms determine the large repertoire of intestinal motor patterns responsible for moving nutrients along the digestive tract. The project will combine experimental and theoretical data, with biomechanical and electrophysiological models to create a new understanding of this essential function of the body.
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
Design of the cardiovascular system of living and fossil vertebrates. This project aims to understand how the heart and blood vessels evolved in mammals, birds, reptiles and fish to achieve efficiency. The heart is the most important organ for life. The project will study the structure and function of vertebrate animals’ hollow and spongy hearts to show how energetics shaped their evolution. It will measure arterial holes in bone to gauge brain and bone metabolism, which opens up a new way to me ....Design of the cardiovascular system of living and fossil vertebrates. This project aims to understand how the heart and blood vessels evolved in mammals, birds, reptiles and fish to achieve efficiency. The heart is the most important organ for life. The project will study the structure and function of vertebrate animals’ hollow and spongy hearts to show how energetics shaped their evolution. It will measure arterial holes in bone to gauge brain and bone metabolism, which opens up a new way to measure metabolism in extinct animals directly from fossils, rather than by inference from living relatives. The expected outcome is to correlate cardiovascular design and metabolic rates of organs.Read moreRead less
Endogenous and environmental regulation of energy expenditure in skeletal muscle. Circadian and seasonal cycles impact on body weight; night shift workers have disrupted light-dark cycles and are predisposed to obesity. The project will investigate effects of both short and long term changes in day length on energy expenditure in skeletal muscle. Furthermore, the project will investigate mechanisms that control energy expenditure in muscle.
Deconstructing the neural circuits regulating appetite. This project aims to expand our knowledge about the neural circuits that influence a feeding response in the absence of emotional or cognitive obstacles. Feeding behaviour is a fundamental physiological process in all animals. Despite the seemingly simple endpoint, feeding behaviour is affected by numerous factors including stress and motivation that can inhibit feeding behaviour. This knowledge is critical to maximise growth and survival i ....Deconstructing the neural circuits regulating appetite. This project aims to expand our knowledge about the neural circuits that influence a feeding response in the absence of emotional or cognitive obstacles. Feeding behaviour is a fundamental physiological process in all animals. Despite the seemingly simple endpoint, feeding behaviour is affected by numerous factors including stress and motivation that can inhibit feeding behaviour. This knowledge is critical to maximise growth and survival in many Australian sectors including agriculture, conservation and basic science.Read moreRead less