Neurodevelopmental Role Of Susceptibility Genes For Autism Spectrum Disorders: From Genes To Behaviour
Funder
National Health and Medical Research Council
Funding Amount
$482,968.00
Summary
Autism is a developmental neuropsychiatric syndrome characterised by impairments in three principal domains: social interaction, language and behavioural inflexibility. Autism spectrum disorder (ASD) refers to a group of neurodevelopmental syndromes with the common feature of dysfunctional reciprocal social interaction. In this project we will investigate the role of genes that increase the risk of ASD in the development of behaviours using an animal model. This work will lead to a better unders ....Autism is a developmental neuropsychiatric syndrome characterised by impairments in three principal domains: social interaction, language and behavioural inflexibility. Autism spectrum disorder (ASD) refers to a group of neurodevelopmental syndromes with the common feature of dysfunctional reciprocal social interaction. In this project we will investigate the role of genes that increase the risk of ASD in the development of behaviours using an animal model. This work will lead to a better understanding of the genetic basis of ASD.Read moreRead less
Development of normal brain function requires information transfer and integration from outside and within the brain. Normal brain wiring is guided by genetic and environmental cues, whose relative contributions remain controversial. This project investigates the physiological and behavioural consequences of abnormal brain wiring, and the potential for controlled environments and targeted interventions to overcome the deficits. Relevance includes neurotrauma as well as mental illnesses.
Prof Alan Connelly is an internationally recognised neuroimaging researcher specialising in MRI. His major areas of research are in the development of new methods to acquire and process MR images of both structural and functional aspects of the brain, and the application of these novel methods to clinical neuroscience problems. His work has had a major impact in the field of epilepsy, where techniques that he pioneered have been widely adopted in specialist epilepsy centres worldwide.
Pain has a detrimental impact on ones quality of life and a significant financial impact on the community. It has recently been revealed that chronic pain is associated with altered brain anatomy and function. Using human brain imaging, we aim to determine the underlying reason for these changes by following individuals during the development of pain. Defining the mechanism underlying pain will aid in the development of better treatment regimens.
Control Of Prosthetic Limbs From Decoded Brain Signals
Funder
National Health and Medical Research Council
Funding Amount
$895,832.00
Summary
This research will restore mobility to patients who suffer from paralysis. We aim to create a device, known as a brain-machine interface, which is an artificial communication path from the brain that bypasses an injury, such as a damaged spinal cord or stroke. The interface will decode a user’s intent and act upon it. Decoders will use physiological principals and state-of-the-art machine learning methods. We will test a user’s ability to control an artificial limb using decoded brain activity.
Advancing The Evidence-base For Childhood Brain Insult: Diagnosis, Assessment And Intervention
Funder
National Health and Medical Research Council
Funding Amount
$575,662.00
Summary
My research has 4 primary objectives, representing major gaps in current knowledge: 1. improve knowledge of recovery and determinants of post-concussive symptoms 2. establish the impact of child brain insult on socio-emotional function and identify contributing factors 3. develop an iPad based tool for socio-emotional function 4. evaluate and disseminate e-heath treatments for child brain insult
Novel Methods To Study Structural-functional Connectivity In Epilepsy And Schizophrenia
Funder
National Health and Medical Research Council
Funding Amount
$697,605.00
Summary
Magnetic Resonance Imaging (MRI) is a non-invasive method that has revolutionised our understanding of clinical neuroscience. MRI provides not only high-contrast anatomical images, but also information on brain physiology and function. My primary goal is to develop and optimise novel MRI methods for a more accurate measure of brain structure and function. My research program will focus on the application of these methods to the investigation of epilepsy and schizophrenia.
High-resolution Brain Imaging Of Basal Ganglia Function
Funder
National Health and Medical Research Council
Funding Amount
$589,083.00
Summary
This project will develop new methods for high resolution MRI imaging of the human brain. We will assess functions of deep brain areas known as the basal ganglia that play a critical role in movement planning and co-ordination. Dysfunction within the basal ganglia is responsible for the motor impairments seen in people with Parkinson’s disease. In this project, we will examine changes in basal ganglia function and structure that lead to individual differences in movement control and learning.
Mechanisms And Consequences Of Cholinergic Signaling In Neocortical Pyramidal Neurons
Funder
National Health and Medical Research Council
Funding Amount
$258,000.00
Summary
Dementia, including Alzheimer s Disease, represents the second highest non-fatal disease burden in Australia. Modern theories suggest that cognitive deficits associated with disorders such as Alzheimer s Disease result in part from impairment of the action of the neurotransmitter acetylcholine. Despite the obvious importance of acetylcholine in brain function, there is currently a lack of basic knowledge regarding how this chemical works at the cellular level. We have recently discovered that ac ....Dementia, including Alzheimer s Disease, represents the second highest non-fatal disease burden in Australia. Modern theories suggest that cognitive deficits associated with disorders such as Alzheimer s Disease result in part from impairment of the action of the neurotransmitter acetylcholine. Despite the obvious importance of acetylcholine in brain function, there is currently a lack of basic knowledge regarding how this chemical works at the cellular level. We have recently discovered that acetylcholine produces opposing phasic and tonic actions on the excitability of brain cells in the cortex. The data collected in this study will reveal the receptor type, intracellular signalling pathways, and ionic mechanisms through which acetylcholine influences information processing in the brain. Together, these results will provide a framework for understanding the biological basis by which acetylcholine influences cognitive function. This new knowledge will in turn increase our understanding of why dysfunction of this important neurotransmitter system leads to the functional deficits observed in Alzheimer s Disease and other forms of dementia, and will hopefully suggest new targets for therapeutic intervention.Read moreRead less
The Role Of Action Potentials In Local Calcium Signalling And Induction Of Different Forms Of LTP
Funder
National Health and Medical Research Council
Funding Amount
$330,691.00
Summary
Our understanding of how the brain learns and remembers things is still limited. There is good evidence that changing the strength of the connections (synapses) between brain cells (neurons) can allow information to be stored. One type of synaptic change is called long-term potentiaton (LTP), which is a long-lasting increase in the efficacy of communication between neurons. Recently, I have described 3 different forms of LTP in a region of the brain that is known to be important for learning and ....Our understanding of how the brain learns and remembers things is still limited. There is good evidence that changing the strength of the connections (synapses) between brain cells (neurons) can allow information to be stored. One type of synaptic change is called long-term potentiaton (LTP), which is a long-lasting increase in the efficacy of communication between neurons. Recently, I have described 3 different forms of LTP in a region of the brain that is known to be important for learning and memory. These forms of LTP have different persistence characteristics - LTP 1 is relatively short-lasting, LTP 2 is of intermediate duration, and LTP 3 is very long-lasting and perhaps even permanent. Each form of LTP is selectively triggered by an increase in calcium in a different part of the neuron. In the present study, I will investigate the relationships between electrical activity in different parts of the neuron in order to define the 'rules' for triggering each form of LTP. This information is important for future studies into the specific role played by each form of LTP in learning and memory processing in the brain. A better understanding of the relationship between LTP and learning and memory will assist in developing effective treatment strategies for disorders of memory, including Alzheimer s disease, addictive bahaviour, and learning disorders.Read moreRead less