Epilepsy And Stress: An Explanatory Electrophysiological Model
Funder
National Health and Medical Research Council
Funding Amount
$100,233.00
Summary
Epilepsy is one of the most common recurrent neurological disorders worldwide, affecting between 1 and 2% of the population. The cascade of events culminating in epilepsy, or the role of seizures in altering brain structures and circuits has been difficult to define. Previous work from our group has shown that stress markedly accelerates the process of epilepsy development. I am developing a model of brain functioning from observed brain cells to chart the changes associated with seizures, stres ....Epilepsy is one of the most common recurrent neurological disorders worldwide, affecting between 1 and 2% of the population. The cascade of events culminating in epilepsy, or the role of seizures in altering brain structures and circuits has been difficult to define. Previous work from our group has shown that stress markedly accelerates the process of epilepsy development. I am developing a model of brain functioning from observed brain cells to chart the changes associated with seizures, stress, and potential treatments.Read moreRead less
Elucidating The Role Of Transthalamic Pathways In Cortical Processing
Funder
National Health and Medical Research Council
Funding Amount
$792,688.00
Summary
Your brain senses the world and produces a suitable motor response by processing information between brain regions, such as primary sensory cortex to secondary cortex. Surprisingly, cortical pathways have a parallel route through the thalamus (transthalamic pathways) but their function is entirely unknown. We will use novel genetic and viral tools to shut down neural pathways while mice make decisions, thus identifying new circuits in our understanding of disorders with cognitive deficits.
Motivation For Starvation: Understanding The Neurobiology Of Anorexia Nervosa
Funder
National Health and Medical Research Council
Funding Amount
$773,142.00
Summary
Anorexia nervosa is a debilitating psychiatric disorder which is currently untreatable. It is characterised by disrupted reward and cognitive processing. This project, which will ultimately inform treatment strategies, utilises the activity-based anorexia rat model combined with innovative behavioural paradigms and sophisticated techniques to manipulate and record from neural circuits. This will furnish a comprehensive understanding of the neurobiology involved in pathological weight loss.
Mechanical Factors In Normal Human Colonic Motility
Funder
National Health and Medical Research Council
Funding Amount
$650,023.00
Summary
Abnormal human colonic contractions cause significant medical, societal and financial burdens. Diagnosis and treatment of motility disorders requires an understanding of normal colonic contractility against which to measure dysfunction. Through state-of-the-art recording and analytical techniques, developed by the applicants, this project will provide the first clear description of normal human colonic motor patterns and how they are generated.
Redefining Proprioceptive Circuitry At A Molecular Level
Funder
National Health and Medical Research Council
Funding Amount
$564,482.00
Summary
Neurons form an extensive series of connections to relay information across the entire body. It is essential to understand how neurons know to find their way, and form the right connections, in a developing animal. This project will investigate the genes which control formation of neural circuits that are essential for correct movement.
The Orexin System: A Link Between Addiction And Depression
Funder
National Health and Medical Research Council
Funding Amount
$378,426.00
Summary
Relapse represents the most significant barrier to the successful treatment of addiction Interestingly, relapse rates are significantly higher amongst addicts with a concurrent mood disorder such as depression. This fellowship will use a number of cutting-edge techniques to explore the role of a hypothalamic peptide called 'orexin' in both relapse and depression and will thereby guide translational research aimed at developing pharmacotherapies designed to treat these disorders.
Proof Of Principle For Minimally-Invasive Intravascular Brain-Computer Interface
Funder
National Health and Medical Research Council
Funding Amount
$110,068.00
Summary
Severe injury to limb or spinal cord leads to significant disability. Despite advances in many areas of modern medicine, prosthetic limbs have changed little over decades. A new field of medicine seeks to create a "brain-computer interface" that is capable of controlling a robotic limb, or any electronic device just by thinking. Brain-computer interfaces are currently implanted in an open brain operation. This project aims to demonstrate that a brain-computer interface can be be implanted in a m ....Severe injury to limb or spinal cord leads to significant disability. Despite advances in many areas of modern medicine, prosthetic limbs have changed little over decades. A new field of medicine seeks to create a "brain-computer interface" that is capable of controlling a robotic limb, or any electronic device just by thinking. Brain-computer interfaces are currently implanted in an open brain operation. This project aims to demonstrate that a brain-computer interface can be be implanted in a minimally invasive procedure.Read moreRead less
Aberrant Ependymal Development And The Formation Of Hydrocephalus
Funder
National Health and Medical Research Council
Funding Amount
$660,005.00
Summary
Foetal hydrocephalus is a prevalent neurodevelopmental condition associated with severe intellectual impairment. Breakdown of the ependymal cell layer, which acts as a barrier between brain tissue and the ventricular space, is a major cause of hydrocephalus. Despite the importance of these cells, we have little understanding of the molecular mechanisms that regulate their production. This project will identify critical signalling pathways governing the establishment of the ependymal layer.
Bone mass is regulated by a number of processes that originate in the brain, however, the mechanism whereby the bone signals to the brain is unknown. Osteoblasts, the cells that form bone, secrete a hormone, osteocalcin that signals in other tissues to control energy and glucose homeostasis. This proposal explores osteocalcin signalling in bone as well as in the brain as a potential feedback from bone to the brain.