How the brain regulates blood pressure. This project will test whether a group of nerve cells in the rostral ventrolateral medulla generate sympathetic activity in blood vessels. The brain regulates blood pressure through several pathways, including nerves in the sympathetic nervous system that constrict blood vessels and increase the heart rate. Activity of these sympathetic nerves regulates blood pressure, but it is unknown which nerve cells in the brain cause this activity. This information i ....How the brain regulates blood pressure. This project will test whether a group of nerve cells in the rostral ventrolateral medulla generate sympathetic activity in blood vessels. The brain regulates blood pressure through several pathways, including nerves in the sympathetic nervous system that constrict blood vessels and increase the heart rate. Activity of these sympathetic nerves regulates blood pressure, but it is unknown which nerve cells in the brain cause this activity. This information is essential to understand how blood pressure is controlled under healthy conditions.Read moreRead less
Muscling in on the brain. This project investigates an enzyme that 'matures' neurotransmitters in the brain that regulate food intake, energy expenditure and blood pressure by the brain; these neurotransmitters arise from the same precursor molecule. This project will show the physiological relevance of this enzyme in obesity.
Action-related learning and plasticity in the cortico-striatal network. This project focuses on the neural bases of adaptive behaviour, specifically on the neural processes through which new actions are acquired. This project aims to establish the neural networks involved as well as the locus of the critical cellular plasticity mediating this learning process in the brain.
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
Neural circuits that mediate fear conditioning and extinction. Understanding of how the brain processes, stores and retrieves information and produces behavioural outcomes is in its infancy. This project will use electrophysiology and molecular techniques to understand the circuits that mediate one form of emotional learning.
Adaptation of respiratory chemoreception: role of inhibitory neuropeptides. The project aims to investigate how the retrotrapezoid nucleus (RTN) is involved in respiratory adaptation to hypercapnia. Chemoreceptor neurons in the RTN are crucial for life however, the mechanisms that underlie their basal and stimulated activity, to control breathing, remain to be clarified. This project will investigate the role of galanin in RTN-mediated regulation of breathing. The project looks to determine inst ....Adaptation of respiratory chemoreception: role of inhibitory neuropeptides. The project aims to investigate how the retrotrapezoid nucleus (RTN) is involved in respiratory adaptation to hypercapnia. Chemoreceptor neurons in the RTN are crucial for life however, the mechanisms that underlie their basal and stimulated activity, to control breathing, remain to be clarified. This project will investigate the role of galanin in RTN-mediated regulation of breathing. The project looks to determine instructive and multifunctional roles of peptidergic chemosensory neurons and their contribution to local inhibitory control of the respiratory network. New knowledge from the project may in the future assist translational research into respiratory disorders and lead to technological advances.Read moreRead less
Understanding brain mechanisms that control autonomic function. This project aims to understand the how the brain regulates sympathetic nerve activity, thereby increasing our understanding of the biology and function of nascent neurons on the adult brain stem. This challenges the current notion that new neurons are only made during development. The project will also determine how brain inflammation impacts blood-brain barrier function and affects sympathetic nerve regulation. The basic fundament ....Understanding brain mechanisms that control autonomic function. This project aims to understand the how the brain regulates sympathetic nerve activity, thereby increasing our understanding of the biology and function of nascent neurons on the adult brain stem. This challenges the current notion that new neurons are only made during development. The project will also determine how brain inflammation impacts blood-brain barrier function and affects sympathetic nerve regulation. The basic fundamental insights and conceptual advances into how autonomic function is controlled by the brain will provide a better understanding of these fundamental processes and will contribute to Australia’s priority research areas to improve health and advance product development.Read moreRead less
The neural basis of the cognitive effects of prefrontal cortex stimulation. This project aims to discover what exactly happens to brain cells (neurons) when transcranial Direct Current Stimulation (tDCS) is administered. Direct current stimulation of prefrontal cortex has gained much attention as an easy to use and self-administered brain stimulation technique for improving learning and performance in tests, and even for management of conditions such as overeating and gambling. Despite the wides ....The neural basis of the cognitive effects of prefrontal cortex stimulation. This project aims to discover what exactly happens to brain cells (neurons) when transcranial Direct Current Stimulation (tDCS) is administered. Direct current stimulation of prefrontal cortex has gained much attention as an easy to use and self-administered brain stimulation technique for improving learning and performance in tests, and even for management of conditions such as overeating and gambling. Despite the widespread use of tDCS the neural basis of its effects remain unknown. By applying tDCS in animals performing cognitive tasks, this projects aims to address fundamental unanswered questions about 'where' and 'how' the tDCS influences neural information encoding and behaviour using cellular- and neural circuit-level evidence.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120102883
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Understanding the function of a visual pathway to the limbic cortex. This project will study an area located deep in the brain, about which very little is known. Based on recent studies, it is suspected that this area is important for visual perception. By understanding the patterns of electrical activity of cells in this region, the project aims to decipher its contribution to cognition and emotion.
How appetite-suppressing brain cells maintain normal function and prevent the development of obesity. The brain plays a critical role in body weight gain by balancing appetite-inducing and appetite-suppressing signals. An imbalance in this process causes obesity and promotes diabetes. The aim of this research is to identify how appetite-suppressing brain cells maintain normal function and prevent the development of obesity.