Genes Important For Early Brain Development Are Also Important For Adult Brain Disease
Funder
National Health and Medical Research Council
Funding Amount
$850,346.00
Summary
I committed to understanding of how the brain develops, grows and regenerates. My laboratory is active in finding a cure for brain injury following brain trauma or brain ischemia. I have discovered that the genes that drive neuron migration and wiring in the fetus also function in the adult brain to improve neuron survival and regeneration. Probing the function of these genes will deliver twin benefits in preventing brain disorder in the newborn and treating brain disease in the adult.
Mechanisms Of PTEN Regulation By Ndfip1 And Their Biological Consequences For Neuron Survival During Brain Injury
Funder
National Health and Medical Research Council
Funding Amount
$686,640.00
Summary
We have discovered a new protein (Ndfip1) that protects brain cells from death after brain injury from trauma and stroke. We will investigate why this protein is activated only in some, but not in other, brain cells after injury. In this application, we will study the mechanisms behind neuron protection, and use this information to explore how to increase the number of brain cells activating Ndfip1.
FETAL BRAIN INJURY RESULTING FROM INTRAUTERINE INFECTION: LONG TERM CONSEQUENCES AND THE POTENTIAL FOR INTERVENTION
Funder
National Health and Medical Research Council
Funding Amount
$452,640.00
Summary
Brain damage during fetal life is a significant cause of later neurological problems such as cerebral palsy. Recent studies have shown that brain injury detected in infants is usually caused by adverse conditions within the uterus prior to labour, but the exact causes are poorly understood. It is also apparent that babies born prematurely are at increased risk of suffering serious brain damage. Unfortunately, at present, it is not possible to prevent or effectively treat brain damage in the fetu ....Brain damage during fetal life is a significant cause of later neurological problems such as cerebral palsy. Recent studies have shown that brain injury detected in infants is usually caused by adverse conditions within the uterus prior to labour, but the exact causes are poorly understood. It is also apparent that babies born prematurely are at increased risk of suffering serious brain damage. Unfortunately, at present, it is not possible to prevent or effectively treat brain damage in the fetus or newborn, partly due to ignorance about how and when the damage is occurring. In recent years it has become evident that infections in the mother, may be linked to both premature birth and brain damage. It has been proposed that the certain chemicals (cytokines) which are released during an infection can across the placenta to the fetus, causing inflammatory changes that lead to brain damage. However, although associations have been shown in studies of women, there is little evidence that infections actually cause brain damage in the fetus. This project will define the effects of an inflammation inducing chemical (bacterial endotoxin) on the fetal brain and the pattern of inflammation it sets up in the fetus. We will also examine the effects of brain damage caused by endotoxin in the newborn lamb, and relate this to alterations in behaviour. Once we have defined the effects of endotoxin on brain structure, we will test the effects of chemicals that are known to block the actions of inflammatory cytokines. We hope that by blocking the chemical pathway that leads to the production of harmful cytokines we may be able to prevent brain injury from occurring when the fetus is exposed to an infection in the mother. It is expected that this project will provide important information that helps us to understand how infection in the mother can cause brain injury in the fetus. This information is vital if strategies to prevent or treat brain injury are to be developed.Read moreRead less
Emotion Regulation After Brain Injury: New Approaches To Remediation
Funder
National Health and Medical Research Council
Funding Amount
$922,662.00
Summary
Traumatic brain injuries, often from motor vehicle accidents, devastate the lives of thousands of young Australians each year and can lead to changes in personality and emotional regulation. Frontal lobe damage may cause apathy, withdrawal and loss of motivation or a loss of control leading to poor inhibition and anger outbursts. In this project we trial some experimental approaches to improving emotion regulation including biofeedback, self-control therapy and direct cortical stimulation.
Understanding White Matter Injury In Term-born Children With Cerebral Palsy
Funder
National Health and Medical Research Council
Funding Amount
$193,863.00
Summary
The type of brain injury in cerebral palsy varies. In some children the brain develops abnormally in early pregnancy; others have a stroke or suffer from lack of oxygen around the time of birth. Little is known about the group of children born at term who have damage to the brain’s white matter, a pattern more typical of premature birth. This project will explore brain imaging, potential risk factors, and clinical outcomes for these children to identify possible causes and prevention pathways.
Potential For Creatine Or Melatonin As Dietary Supplements In Pregnancy To Prevent Perinatal Brain Damage
Funder
National Health and Medical Research Council
Funding Amount
$483,217.00
Summary
Brain damage in the newborn - particularly in prematurely born infants - remains a significant health problem. At present there are very few treatments that can be used to minimize damage when it becomes apparent in the newborn, and none that can be used PROSPECTIVELYduring pregnancy to protect the developing brain from damage. The most likely cause of damage to the fetal brain during pregnancy or at birth is global ASPHYXIA, either by itself or in association with other problems of pregnancy su ....Brain damage in the newborn - particularly in prematurely born infants - remains a significant health problem. At present there are very few treatments that can be used to minimize damage when it becomes apparent in the newborn, and none that can be used PROSPECTIVELYduring pregnancy to protect the developing brain from damage. The most likely cause of damage to the fetal brain during pregnancy or at birth is global ASPHYXIA, either by itself or in association with other problems of pregnancy such as infection, preterm birth, or fetal growth retardation. In this project we propose that providing extra amounts of the dietary constituent creatine, or of the hormone melatonin, to the pregnant animal in late gestation, will provide NEUROPROTECTION to the developing brain in the face of an asphyxial challenge that otherwise causes damage. We will use pregnant sheep to investigate the effects of asphyxia in utero on the fetal brain using techniques that allow us to monitor metabolic changes within the brain in real time. In addition, we will use the pregnant Spiny Mouse to investigate the effects of birth asphyxia on the postnatal brain structure and behavioral development. We will study groups of animals fed a normal diet, and compare then to animals that receive additional amounts of creatine or melatonin. We expect to determine if either of these treatments have the potential to protect the developing brain from asphyxial damage, and to recommend if similar treatments could be used in pregnant women where the obstetrician suspects the baby's brain is at risk of damage.Read moreRead less
Deciphering The Mechanisms For Constructing The Olfactory System
Funder
National Health and Medical Research Council
Funding Amount
$496,321.00
Summary
The olfactory (smell) system is a unique part of the nervous system; nerve cells are generated throughout life and it can regenerate even after injury. It therefore provides an excellent model for examining the growth, development and maintenance of nerve cells. This project will examine the effects on the organisation of the olfactory system when some guidance signals are altered. Information we obtain about how this system develops and regenerates may be useful in treating brain disorders and ....The olfactory (smell) system is a unique part of the nervous system; nerve cells are generated throughout life and it can regenerate even after injury. It therefore provides an excellent model for examining the growth, development and maintenance of nerve cells. This project will examine the effects on the organisation of the olfactory system when some guidance signals are altered. Information we obtain about how this system develops and regenerates may be useful in treating brain disorders and spinal injuries The results of these experiments will provide important information on the the initial growth and targeting of these nerve cells which may have implications for regeneration of these as well as other nerve cells.Read moreRead less
A Molecular Approach To Constructing The Olfactory System
Funder
National Health and Medical Research Council
Funding Amount
$440,250.00
Summary
The olfactory (smell) system is a unique part of the nervous system; nerve cells are generated throughout life and it can regenerate even after injury. It therefore provides an excellent model for examining the growth, development and maintenance of nerve cells. This project will examine the effects on the organisation of the olfactory system when some guidance signals are altered. Information we obtain about how this system develops and regenerates may be useful in treating brain disorders and ....The olfactory (smell) system is a unique part of the nervous system; nerve cells are generated throughout life and it can regenerate even after injury. It therefore provides an excellent model for examining the growth, development and maintenance of nerve cells. This project will examine the effects on the organisation of the olfactory system when some guidance signals are altered. Information we obtain about how this system develops and regenerates may be useful in treating brain disorders and spinal injuries In the current project we will examine the effects of specific nerve cell guidance molecules by generating transgenic mice that produce these molecules only in the olfactory system. We can then determine what changes occur to the nerve cells when these extra molecules are produced. The results of these experiments will provide important information on the the initial growth and targeting of these nerve cells which may have implications for regeneration of these as well as other nerve cells.Read moreRead less