Functional MRI And MR Spectroscopic Studies Of Penicillin Induced And Kindled Sheep Models Of Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$311,244.00
Summary
Epilepsy is one of the most common neurological disorders, affecting 1-2% of the population. Many epilepsy patients do not respond to drug therapy and their only hope for seizure control is surgical removal of the part of the brain responsible for their seizures. Successful surgery is very much dependent on the ability to exactly localize the seizure focus and this is often not possible using the imaging techniques currently available. Functional magnetic resonance imaging (fMRI) is a new techni ....Epilepsy is one of the most common neurological disorders, affecting 1-2% of the population. Many epilepsy patients do not respond to drug therapy and their only hope for seizure control is surgical removal of the part of the brain responsible for their seizures. Successful surgery is very much dependent on the ability to exactly localize the seizure focus and this is often not possible using the imaging techniques currently available. Functional magnetic resonance imaging (fMRI) is a new technique which may improve our ability to localize the seizure focus from which seizures arise, if the brain can be imaged at, or near, the time of a seizure. MR spectroscopy (MRS) enables us to detect metabolic changes in the brain which may persist at the site where seizures have begun for up to 30 minutes after the seizure. The aim of our research is to obtain a greater understanding of the changes detected with these MR modalities so that we can learn to apply these techniques to human sufferers of epilepsy. Ultimately it may help enable previously incurable epilepsy patients to undergo successful surgery and live normal lives.Read moreRead less
Do Changes In HCN Channels Function Cause Epilepsy?
Funder
National Health and Medical Research Council
Funding Amount
$386,172.00
Summary
About 100 000 people suffer from epilepsy in Australia with about one third poorly controlled with current anti-epileptic drugs. It is important to continue to develop novel modes of treatment for this debilitating disease. This project investigates an ion channel, known as HCN that is thought to be involved in making a brain epileptic. Understanding how changes in HCN channels make nerve cells and nerve networks more excitable will help us develop better strategies for designing drugs.
Disruption Of The Ability To Simulate One’s Personal Future: Insights From Epilepsy And Implications For Neurosurgical Planning And Presurgical Counselling
Funder
National Health and Medical Research Council
Funding Amount
$353,711.00
Summary
The human memory system supports not only recollecting the past but also imagining the future (prospection). This is an important skill, enabling us to envision the consequences of alternative courses of action. Patients with temporal lobe epilepsy (TLE) frequently experience memory problems, suggesting that they will show parallel difficulties with prospection. We will study prospection in TLE patients before and after temporal lobe surgery, and the clinical implications thereof.
Altered HCN Channel Expression And Function In Acquired Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$279,912.00
Summary
About 100 000 people currently suffer from epilepsy in Australia and of these about one third are poorly controlled with current anti-epileptic drugs. It is therefore important to continue to develop novel modes of treatment for this debilitating disease. This projects investigates an ion channel, known as the HCN channel, that is thought to be involved in making a brain epileptic. We explore how changes in this channel can make a brain more excitable. Also, our group is the first in the world t ....About 100 000 people currently suffer from epilepsy in Australia and of these about one third are poorly controlled with current anti-epileptic drugs. It is therefore important to continue to develop novel modes of treatment for this debilitating disease. This projects investigates an ion channel, known as the HCN channel, that is thought to be involved in making a brain epileptic. We explore how changes in this channel can make a brain more excitable. Also, our group is the first in the world to discover a mutation in this channel that is linked to epilepsy. We will also investigate how this mutation changes the channel properties to make a brain more likely to be epileptic. The HCN channel is an important target for developing anti-epileptic drugs. Understanding how changes in HCN channels make nerve cells and therefore nerve cell networks more excitable will help us develop better strategies for designing anti-epileptic drugs.Read moreRead less