Ecstasy, Methamphetamine And Their Combination: Assessment Of Adverse Effects
Funder
National Health and Medical Research Council
Funding Amount
$384,250.00
Summary
MDMA (Ecstasy) and Methamphetamine (METH) are popular party drugs that are frequently used by young Australians. Health problems associated with MDMA and METH use are (1) many people suffer complications arising from the high body temperature (hyperthermia) that these drugs produce, and (2) MDMA and METH may both cause long-term loss of key neurotransmitters in the brain. This effect on the brain may well lead to psychological problems such as anxiety, depression, increased impulsive behaviour a ....MDMA (Ecstasy) and Methamphetamine (METH) are popular party drugs that are frequently used by young Australians. Health problems associated with MDMA and METH use are (1) many people suffer complications arising from the high body temperature (hyperthermia) that these drugs produce, and (2) MDMA and METH may both cause long-term loss of key neurotransmitters in the brain. This effect on the brain may well lead to psychological problems such as anxiety, depression, increased impulsive behaviour and memory impairment. However the link between MDMA and METH use and subsequent brain damage is still very controversial. Recently, we have found that when MDMA and METH are combined, a particularly toxic effect is seen with very high body temperatures and lasting adverse effects on mood and brain function. This is a major cause for concern because of evidence that many Australian drug users are combining METH and MDMA on a regular basis. This project will investigate the short and long-term effects of MDMA, METH and METH-MDMA combinations. Phase 1 is aimed at investigating whether different doses of the drugs lead to lasting changes in mood, behaviour and brain function and to compare the relative toxicity of the three treatments. Phase 2 will determine whether lack of fluid intake, high environmental temperatures and advanced age are risk factors in determining the toxicity of MDMA and METH. Phase 3 will assess whether the toxicity of these drug treatments depends upon whether an animal takes the drugs voluntarily or whether they are injected with the drug by the experimenter. The final part of the project will use a wide variety of advanced techniques to track the brain damage caused by these drug treatments given under a range of conditions. The significance of this project will be in increasing our understanding of how MDMA and METH affect the brain and behaviour and how the harms posed by these drugs may be predicted and therefore minimised.Read moreRead less
A Novel Knockin Model To Test The Role Of Nicotine Acting On Alpha4 Acetylcholine Receptors In Complex Behaviours
Funder
National Health and Medical Research Council
Funding Amount
$581,315.00
Summary
Cigarette smoking is the single largest preventable cause of death and disease in Australia and worldwide. Nicotine contained in tobacco products acts on brain nicotine receptors, which plays an intrinsic role in addiction. One type of receptor for nicotine found in regions of the brain associated with drug-seeking behaviour is called alpha4 nicotinic receptors. We have made a mouse with a mutation in this nicotine receptor to study nicotine addiction and anxiety.
Brain damage resulting from long-term alcohol abuse is localized to discrete regions of the brain and selectively impairs key neuropsychological functions. Alcohol misuse affects processes that control excitability in the brain, leading to the over-stimulation of brain cells. When this continues for long periods the cells are likely to die and most alcoholics misuse alcohol for most of their adult lives. We will study the human brain s capacity to use and respond to glutamate, its major natural ....Brain damage resulting from long-term alcohol abuse is localized to discrete regions of the brain and selectively impairs key neuropsychological functions. Alcohol misuse affects processes that control excitability in the brain, leading to the over-stimulation of brain cells. When this continues for long periods the cells are likely to die and most alcoholics misuse alcohol for most of their adult lives. We will study the human brain s capacity to use and respond to glutamate, its major natural excitant, in the regions that are selectively damaged by alcoholism. How these capacities are affected by heredity, and by diseases commonly associated with alcoholism such as cirrhosis of the liver, will also be explored. If we can understand how selective brain damage occurs in alcoholics we will be better able to devise new drug therapies to combat and prevent it. As well, localized brain damage is a feature of many neurological diseases, so the study will provide a general model of disease mechanisms.Read moreRead less
Structure-based Drug Design For Neuroprotection From Traditional Chinese Medicine
Funder
National Health and Medical Research Council
Funding Amount
$245,968.00
Summary
In the proposed research, three novo approaches for drug discovery will be explored: 1) The important neurodegenerative disease relevant protein JNK3 crystals will be used as the probe to fish out the potential inhibitors from Traditional Chinese Medicine (TCM); 2) Instead of individual drug components, the mixture of TCM will be used directly; 3) The composition of a TCM library are not randomly chosen but have been used in China for hundreds to thousands of years in curing neurodegenerative di ....In the proposed research, three novo approaches for drug discovery will be explored: 1) The important neurodegenerative disease relevant protein JNK3 crystals will be used as the probe to fish out the potential inhibitors from Traditional Chinese Medicine (TCM); 2) Instead of individual drug components, the mixture of TCM will be used directly; 3) The composition of a TCM library are not randomly chosen but have been used in China for hundreds to thousands of years in curing neurodegenerative disease.Read moreRead less
Cell Death In The Retina: Analysing The Switch That Triggers Dependency On Target-derived Trophic Factors
Funder
National Health and Medical Research Council
Funding Amount
$428,414.00
Summary
Construction of the developing nervous system in the embryo involves the creation of nerve cells and their connections, but also involves loss of a proportion of these cells prior to maturation. We will study this process of cell death and how developing nerve cells switch on their dependency to survival factors. In so doing we will better understand what happens when brain development goes wrong and also devise new ways to protect nerve cells in the injured or degenerate adult nervous system.
Development Of Pthaladyn-based Dynamin I-selective Inhibitors For Treatment Of Epilepsy
Funder
National Health and Medical Research Council
Funding Amount
$564,310.00
Summary
About 1% of the World�s population suffers from epilepsy; 30% fail to respond to anti-epileptic drugs (AED). Current AED development pathways have changed little in the past 20 years with the majority of current AEDs dampening the release of crucial chemical signals 24/7. Our new drugs, which inhibit a protein called dynamin, are only recruited at the onset of a seizure. Our approach will significantly enhance the day to day lives of those afflicted by epilepsy.
Inhibitory Neurotransmitter Receptors As Therapeutic Targets For Chronic Pain And Anxiety Disorders
Funder
National Health and Medical Research Council
Funding Amount
$763,409.00
Summary
There are currently few effective long-term treatments for chronic pain and anxiety disorders. Here we propose to develop innovative therapies for both of these debilitating neurological disorders. In addition, we plan to improve our current understanding of how these disorders occur in the first place. This may identify novel potential therapeutic strategies for treating pain, anxiety and a host of other neurological disorders.
Clinical Utility And Cost-effectiveness Of Genome Sequencing For Refractory Epilepsy In Children And Adults: A Multicentre Randomised Controlled Trial
Funder
National Health and Medical Research Council
Funding Amount
$720,609.00
Summary
A large number of genomic variants have been found to underpin common types of epilepsy and to predict adverse drug reactions. However, the adoption of genomic testing in the routine management of epilepsy is hampered by uncertainties around its clinical utility and cost-effectiveness. This randomised controlled trial aims to determine the diagnostic efficiency, clinical and psychosocial impact, and cost-effectiveness of whole genome sequencing for refractory epilepsy in children and adults.
Genomics Of Antiepileptic Drug-induced Stevens Johnson Syndrome
Funder
National Health and Medical Research Council
Funding Amount
$500,817.00
Summary
Epilepsy affects 3% of people. Severe skin reactions to anti-epileptic drugs are unpredictable and potentially fatal. This project aims to better understand the complex genetic architecture of these reactions using the latest sequencing platforms applied to a unique collection of samples, followed by functional analysis. The findings will enhance the practice of precision medicine in epilepsy treatment, shed light on the mechanisms of these reactions, and inform better drug design in the future.
Slowing Progression Of Alzheimer’s Disease By Modulating The Kynurenine Pathway
Funder
National Health and Medical Research Council
Funding Amount
$578,460.00
Summary
Chronic inflammation in the brain in known to be a factor in the progression of Alzheimer's disease. We are exploring if blocking a particular enzyme in a biochemical pathway involved in inflammation, can improve symptoms, or slow progression, of the disease in animal models of AD. If results are as expected, our proposal has the potential to generate a new a therapy for AD.