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
Contribution Of Disturbed Blood Flow And Cerebral Metabolism To White Matter Damage In The Perinatal Brain
Funder
National Health and Medical Research Council
Funding Amount
$369,375.00
Summary
It has been known for some time that the white matter regions of the developing brain are particularly vulnerable to damage. These regions are deep in the brain near the ventricles, and are rich in myelin sheaths wrapped around the nerve fibres running from cell-rich areas in the outer layers of the brain to other regions, and down into the spinal cord. Damage to white matter usually leads to behavioural, learning and motor problems in the newborn infant - in its severest form, seen as cerebral ....It has been known for some time that the white matter regions of the developing brain are particularly vulnerable to damage. These regions are deep in the brain near the ventricles, and are rich in myelin sheaths wrapped around the nerve fibres running from cell-rich areas in the outer layers of the brain to other regions, and down into the spinal cord. Damage to white matter usually leads to behavioural, learning and motor problems in the newborn infant - in its severest form, seen as cerebral palsy. Such outcomes are often associated with the presence of asphyxia and infection during pregnancy, leading to the belief that the damage first arises while the baby is still in utero. In this application we suggest that asphyxia and-or infection during pregnancy cause prolonged disturbances in the regulation of blood flow and integrity of the blood-brain barrier in the developing brain, together with changes in metabolism that result in accumulation of prostaglandins and the toxic hydroxyl radical, leading irreversibly to cell death. If this series of events proves to be true, we have suggested and will test several protocols for protecting the fetal brain, which should be readily translatable to clinical practice.Read moreRead less
Extracellular Acidosis And PH-modulating Drugs As Novel Therapies For Neuroprotection In Hypoxia/ischemia In The Newborn
Funder
National Health and Medical Research Council
Funding Amount
$452,310.00
Summary
Approximately 4 out of every 1000 babies suffer severe perinatal asphyxia (a period of a shortage of oxygen) during the birth process which carries with it a high risk of brain damage or death. Those babies surviving with a severe disability cost Australia $500,000,000 per annum in lifelong costs. With currently available methods, the presence of asphyxia is difficult to detect and hence prevention is often not possible. At present, there are no effective medications to treat asphyxia-related br ....Approximately 4 out of every 1000 babies suffer severe perinatal asphyxia (a period of a shortage of oxygen) during the birth process which carries with it a high risk of brain damage or death. Those babies surviving with a severe disability cost Australia $500,000,000 per annum in lifelong costs. With currently available methods, the presence of asphyxia is difficult to detect and hence prevention is often not possible. At present, there are no effective medications to treat asphyxia-related brain damage in babies. This study brings together a multi-disciplinary team driven by the clinical need to develop suitable strategies for neuroprotection in the developing brain. We will investigate the neuroprotective properties of the clinically relevant factor of acidosis and determine how acidosis influences neuroprotectant drugs. In the future, it is envisaged that this study will lead to rationally-based clinical trials aimed at improving neurodevelopmental outcomes for babies who suffer asphyxia and for infants who are victims of near-drowning or head trauma.Read moreRead less
The exposure of infants to adverse events both before and after birth can cause death or permanent disability (eg cerebral palsy) for the infant. Our primary research objective is to minimize the impact and improve outcomes for infants exposed to adverse events before and/or after birth. We will use a multi-disciplinary approach that aims to understand the science and to develop new treatments, thereby representing true “bench to bedside” research.
Newborn babies are at risk of becoming short of oxygen during delivery and sustaining brain damage. Seizures may cause further damage to the brain because they release damaging chemicals or make extra energy demands on the brain that cannot be met. To detect seizures, it is necessary to measure the EEG, the tiny electrical signals from the brain. We are proposing to automatically detect and count seizures, building upon 8 years of fundamental EEG signal processing research work we have undertake ....Newborn babies are at risk of becoming short of oxygen during delivery and sustaining brain damage. Seizures may cause further damage to the brain because they release damaging chemicals or make extra energy demands on the brain that cannot be met. To detect seizures, it is necessary to measure the EEG, the tiny electrical signals from the brain. We are proposing to automatically detect and count seizures, building upon 8 years of fundamental EEG signal processing research work we have undertaken. We anticipate that the product will be of major commercial interest. We will further explore what is a rapidly expanding marketplace and ensure we maximize the commercial return on this product.Read moreRead less
Recent scientific advances provide a window into the developing brain. This research will investigate the profound and challenging ethical questions raised by these new technologies. It will look at scientific and ethical questions relating to the use of new brain scans for fetuses and premature newborn infants. It will develop a resource for parents facing potentially heart-breaking decisions about their seriously ill infants.
Early Identification Of Infants Who Will Benefit From Neural Rescue Treatment
Funder
National Health and Medical Research Council
Funding Amount
$206,320.00
Summary
Lack of oxygen supply before, during or immediately after birth can lead to severe disability or death. This occurs in about 1 in every 500 births and is one of the most important but unsolved problems in pediatrics. The costs (financial and other) to both the individuals involved, and the community in general, is very high. However the outlook for those affected by this condition is improving. Recent research has focused on the development of neural rescue therapies, which may decrease the exte ....Lack of oxygen supply before, during or immediately after birth can lead to severe disability or death. This occurs in about 1 in every 500 births and is one of the most important but unsolved problems in pediatrics. The costs (financial and other) to both the individuals involved, and the community in general, is very high. However the outlook for those affected by this condition is improving. Recent research has focused on the development of neural rescue therapies, which may decrease the extent of disabilities suffered by these children. The same treatments may also be helpful in children following near drowning and head trauma. Neural rescue therapies must be applied less than 24 hours following the event which has caused the reduction in oxygen supply. Thus, before these treatments can be tested, it is necessary to find a way to quickly tell which babies may benefit from the treatments. This study will trial a new method which is inexpensive and can be used without moving the baby away from its incubator. This technique involves a new application of an established technology to detect the redistribution of water within the brain one of the earliest signs of impending brain cell death. The research team consists of medical personnel from the intensive care nurseries of both the Royal Women's Hospital and the Mater Mother s Hospital, as well as scientific staff experienced in the use of this technology. If this technique is effective, it will enable babies to receive maximum benefit from new treatments and reduce long-term difficulties suffered by these children and their families.Read moreRead less