The grand challenge of predicting human movement energetics. This Project aims to advance our understanding of how the neuromuscular system uses energy during movement by exploring the interplay of different factors that influence movement energetics. The Project will explore different levels of organisation; from how muscle fibres consume energy to how those fibres interact and are subsequently controlled within a complex neuromuscular system. Expected outcomes of this Project will be an improv ....The grand challenge of predicting human movement energetics. This Project aims to advance our understanding of how the neuromuscular system uses energy during movement by exploring the interplay of different factors that influence movement energetics. The Project will explore different levels of organisation; from how muscle fibres consume energy to how those fibres interact and are subsequently controlled within a complex neuromuscular system. Expected outcomes of this Project will be an improved capacity to predict energy expenditure of the vast array of movements that humans perform. This will enable accurate monitoring of human energy expenditure and will provide benefits for individualised exercise prescription, enhancing work productivity or designing devices to augment human performance.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100992
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
The role of neuropeptides driving plasticity in the control of blood pressure and breathing. This project aims to understand how pathways in the brain, that control blood pressure, develop 'memory' after repeated episodes of low oxygen, as occurs in sleep apnoea. Based on the assumption that long-lasting excitatory actions are responsible for this change in nerve behaviour this project will increase knowledge about how the brain controls blood pressure.
Gastrointestinal hormones: linking insulin dysregulation and laminitis. This project aims to identify the earliest pathogenic factors of disease by investigating two key hormones, ghrelin and GLP-2, and whether a specific genetic mutation underlies insulin dysregulation. Using innovative approaches the project will enable the identification of at-risk animals and pinpoint novel treatment strategies. In the long term improved disease treatment and prevention will reduce the suffering associated w ....Gastrointestinal hormones: linking insulin dysregulation and laminitis. This project aims to identify the earliest pathogenic factors of disease by investigating two key hormones, ghrelin and GLP-2, and whether a specific genetic mutation underlies insulin dysregulation. Using innovative approaches the project will enable the identification of at-risk animals and pinpoint novel treatment strategies. In the long term improved disease treatment and prevention will reduce the suffering associated with painful and often lethal co-morbidities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100135
Funder
Australian Research Council
Funding Amount
$395,199.00
Summary
Understanding equine incretins: a novel approach to laminitis prevention. Laminitis is a crippling foot disease in horses which incurs significant economic and social costs. Recent studies have shown that persistently high insulin concentrations can trigger laminitis, and that high insulin levels are caused by the excessive release of hormones called incretins. This project aims to determine the role of incretins and their receptors in causing abnormal equine insulin secretion. The distribution ....Understanding equine incretins: a novel approach to laminitis prevention. Laminitis is a crippling foot disease in horses which incurs significant economic and social costs. Recent studies have shown that persistently high insulin concentrations can trigger laminitis, and that high insulin levels are caused by the excessive release of hormones called incretins. This project aims to determine the role of incretins and their receptors in causing abnormal equine insulin secretion. The distribution of equine incretin receptors will be described for the first time, and the consequences of incretin receptor binding will be characterised. Understanding equine incretin biology may lead to novel therapies for laminitis.Read moreRead less
Neuronal activity underlying efficient sensory processing. This project aims to study how neuronal activity in the sensory cortex efficiently represents the external world. Operating with a finite quantity of attentional resources, the brain needs to prioritise processing to provide important information about a situation. This project combines neurophysiology, behavioural and computational sciences to study attention mechanisms in rodents. This multidisciplinary project aims to develop a novel ....Neuronal activity underlying efficient sensory processing. This project aims to study how neuronal activity in the sensory cortex efficiently represents the external world. Operating with a finite quantity of attentional resources, the brain needs to prioritise processing to provide important information about a situation. This project combines neurophysiology, behavioural and computational sciences to study attention mechanisms in rodents. This multidisciplinary project aims to develop a novel paradigm for studying sensory prioritisation in rodents as a model organism.Read moreRead less
Computational neuroanatomy: analysis of neural connections in the primate brain. This project will map the full network of connections between brain cells, using a computer graphics database that will consolidate data from hundreds of experiments. This will allow the first realistic simulations of neural activity, and will provide new insights about the structure and function of the nervous system.
Investigating a new way in which diet impacts animal biology. This project aims to investigate the importance of a new way in which diet can alter animal biology. High fat or high sugar diets increase the binding of products of metabolism to chromosomes, which can completely alter the way that DNA is packaged and read. This project will use cell culture, rodent and fly models to identify the regions of the genome that are most affected by the new process. The project will also determine whether ....Investigating a new way in which diet impacts animal biology. This project aims to investigate the importance of a new way in which diet can alter animal biology. High fat or high sugar diets increase the binding of products of metabolism to chromosomes, which can completely alter the way that DNA is packaged and read. This project will use cell culture, rodent and fly models to identify the regions of the genome that are most affected by the new process. The project will also determine whether the cell is harmed, or in fact harnesses the process to control development or metabolism. This project has implications for our understanding of the ways in which genes interact with the environment especially in times of change.Read moreRead less
Saving your skin: physiology of immune regulation in mammalian lymph nodes. The overall aim of this proposal is to understand the mechanisms through which a rare population of regulatory cells maintains skin integrity. Despite their importance, little is known about the regulatory pathways these cells utilise. Previous work from the team has described an innovative technique to enrich these cells for in-depth study and demonstrated their potent regulatory capacity in vivo. This project will enha ....Saving your skin: physiology of immune regulation in mammalian lymph nodes. The overall aim of this proposal is to understand the mechanisms through which a rare population of regulatory cells maintains skin integrity. Despite their importance, little is known about the regulatory pathways these cells utilise. Previous work from the team has described an innovative technique to enrich these cells for in-depth study and demonstrated their potent regulatory capacity in vivo. This project will enhance our understanding of these cells and uncover their mechanisms of action. The outcomes of this work will therefore provide fundamental new knowledge of skin physiology, and lead to novel insights regarding how healthy skin, which is essential for the very survival and function of a living organism, may be maintained.Read moreRead less
Defining how serotonin regulates gut motility. This project aims to deepen knowledge of gastrointestinal physiology, and reveal the mechanisms by which the major gastrointestinal signalling molecule, serotonin, regulates gut peristalsis. Almost all of the serotonin in our body is made in the gastrointestinal tract where it controls many functions, including how our gut wall contracts during peristalsis. Proper control of gut peristalsis and the transit of material through our bowel is important ....Defining how serotonin regulates gut motility. This project aims to deepen knowledge of gastrointestinal physiology, and reveal the mechanisms by which the major gastrointestinal signalling molecule, serotonin, regulates gut peristalsis. Almost all of the serotonin in our body is made in the gastrointestinal tract where it controls many functions, including how our gut wall contracts during peristalsis. Proper control of gut peristalsis and the transit of material through our bowel is important for our health. This project expects to define how serotonin controls peristalsis, where in the bowel this serotonin comes from, how serotonin communicates with the nervous system in our gastrointestinal tract, and how the cells that synthesise gut serotonin respond to contraction to trigger the secretion of serotonin.Read moreRead less
Neurons and neurotransmitters that control the apnoeic response to irritation of the larynx. Normal function of the larynx enables breathing, cough, singing, speech and many other normal functions. This project will reveal how nerves in the brain coordinate to achieve these many functions; in particular the way that breathing stops if fluid or smoke enters the larynx.