The Final Common Channel: Measurement Of Nerve Excitability In Epilepsy.
Funder
National Health and Medical Research Council
Funding Amount
$301,376.00
Summary
Epilepsy may be due to either one single genetic mutation or a combination of several gene-environment interactions, affecting how ion channels function. It is not possible to directly interrogate channels in the living human brain but, because similar channels are found in peripheral nerve, much may be learned about aberrant channel function from peripheral nerve. This project aims to measure peripheral nerve excitability in epilepsy patients, using it as a marker of the final common pathway of ....Epilepsy may be due to either one single genetic mutation or a combination of several gene-environment interactions, affecting how ion channels function. It is not possible to directly interrogate channels in the living human brain but, because similar channels are found in peripheral nerve, much may be learned about aberrant channel function from peripheral nerve. This project aims to measure peripheral nerve excitability in epilepsy patients, using it as a marker of the final common pathway of channel dysfunction.Read moreRead less
Viral-mediated Modulation Of BDNF Expression In Motor Neurons To Promote The Recovery Of Hand/digits Function In A Rat Model Of Spinal Cord Injury That Impairs Normal Grasping Action.
Funder
National Health and Medical Research Council
Funding Amount
$341,427.00
Summary
This project seeks to lure injured axons towards motor neurons, a process that is essential for the recovery of motor function. BDNF gradients will be created along the injured axons path. Axons will have to elongate to reach the first source of BDNF. They will need to elongate even more to get to the next source of BDNF, hence bringing them each time closer to their lost targets. This gene therapy scenario has the potential to bring gene therapy a step closer for human spinal cord injury.
A DENDRITIC SUBSTRATE FOR THE CHOLINERGIC CONTROL OF NEOCORTICAL OUTPUT
Funder
National Health and Medical Research Council
Funding Amount
$898,340.00
Summary
The forebrain cholinergic system controls neocortical activity and cognitive function. This project will investigate the mechanisms by which the cholinergic system controls neocortical circuit activity in rodent models using advanced optical and electrical recording methods. The results will provide a foundation for the understanding of how dysfunction of the cholinergic system results in cognitive decline in humans, and identify new targets for improved treatment of human cognitive impairment.
Cortical Excitation In Migraine: Using Vision To Understand And Track Brain Excitability
Funder
National Health and Medical Research Council
Funding Amount
$521,628.00
Summary
Migraine is a common neurological condition affecting approximately 15% of adults. Therapies are most effective if used early, yet many people are unable to predict their migraines or to recognize early signs. In addition to headache, key symptoms include abnormal visual and auditory experience. We propose that aspects of vision and hearing will vary systematically according to the current brain status. Our translational goal is to develop tests that allow individuals to better manage migraine.
Function And Physiological Role Of Inhibitory Circuits In The Amygdala
Funder
National Health and Medical Research Council
Funding Amount
$741,518.00
Summary
The amygdala is part of the brain that assigns emotional content to our sensory world and dysfunction of the amygdala is responsible for many anxiety-related disorders. Many anxiolytics, like valium, act on receptors in the amygdala. In this project we will study circuits in the amygdala that are modulated by anxiolytics. These studies will provide essential information in the understanding of anxiety disorders and help in developing drugs to treat these disorders.
Role Of Calcium-activated Potassium Channels In Neuronal Excitability, Synaptic Plasticity And Sensory Processing
Funder
National Health and Medical Research Council
Funding Amount
$612,272.00
Summary
Disturbances in brain function, as occur in diseases such as epilepsy and schizophrenia, are associated with abnormal electrical activity. This electrical activity leads to increases in calcium inside nerve cells. In this project we plan to investigate how changes in calcium inside nerve cells regulates electrical activity, and how this impacts on the capacity of the brain to process and learn new information.
Nerve Excitability Assessment: A Novel Biomarker For The Early Detection Of Diabetic Neuropathy.
Funder
National Health and Medical Research Council
Funding Amount
$375,203.00
Summary
Australia has one of the highest rates of diabetes in the world. Diabetes may be complicated by the development of nerve damage, causing weakness and pain in the upper and lower limbs. The cause remains unclear and there are no tools available for its early detection. This study will provide further information about the cause of diabetic neuropathy and will investigate more sophisticated means for its early detection.
Regulation Of Cortical Excitability By GABAB Receptors
Funder
National Health and Medical Research Council
Funding Amount
$340,976.00
Summary
In the brain electrical activity either excites or inhibits nerve cells. Excitation is balanced by inhibition. If these two processes become unbalanced we can become unconscious or go into seizure. These extreme conditions emphasize the importance of the balance between excitation and inhibition in the brain. While there has been much work on the role of excitation, less is known about inhibition. In this project proposal we will investigate how inhibition regulates excitation in the cortex.
Persistent Firing In Cortical Interneurons: Mechanisms And Potential Anticonvulsant Role
Funder
National Health and Medical Research Council
Funding Amount
$520,552.00
Summary
The normal brain treads a fine line between too much electrical activity (epilepsy) and too little (sedation). We have discovered a class of brain cell that seems to behave like a sentinel, monitoring brain activity for signs of epilepsy. If a seizure occurs, this cell switches on an electrical brake that dampens excess activity. In this project we will study how this brake works and whether it really can inhibit seizures. Our research may lead to better treatments for epilepsy.
VISUAL HALLUCINATIONS: MECHANISTIC BIOMARKERS AND NOVEL TREATMENTS
Funder
National Health and Medical Research Council
Funding Amount
$464,793.00
Summary
This proposal will address an urgent need to develop novel treatment strategies for hallucinations. A critical starting point in this endeavour is to look at the pathophysiology underlying hallucinations because these mechanisms represent the targets that can be modulated by treatment. This proposal will provide strong evidence for two biomarkers of hallucinations 1. Behavioural and 2. Neural.