Preventing Adverse Outcomes Of Neonatal Hypoxic Ischaemic Encephalopathy With Erythropoietin: A Randomised Controlled Multicentre Australian Trial
Funder
National Health and Medical Research Council
Funding Amount
$2,103,844.00
Summary
One in five babies die worldwide from Hypoxic Ischaemic Encephalopathy caused by low oxygen or blood supply to the brain around birth. Survivors often have low IQ, cerebral palsy, epilepsy or autism. Cooling the baby after birth (hypothermia) reduces the severity of brain damage, but half still die or are disabled. This randomised, controlled trial will test whether Erythropoietin (a natural hormone) can further protect and repair these babies' brains, saving lives and preventing disability.
A Randomised Controlled Trial Of Whole Body Cooling On The Outcome Of Term Infants With Hypoxic Ischaemic Encephalopathy
Funder
National Health and Medical Research Council
Funding Amount
$386,732.00
Summary
The aim of this project is to investigate whether the brain damage caused by a serious lack of oxygen around the time of birth can be prevented or reduced by cooling the baby's temperature to 34C for 72 hours. The consequences, of a lack of oxygen, to the brain, around the time of birth can be devastating. Over 30% of those babies with abnormal brain function soon after birth either die or survive with severe permanent brain damage. There is no specific treatment for these infants. Evidence from ....The aim of this project is to investigate whether the brain damage caused by a serious lack of oxygen around the time of birth can be prevented or reduced by cooling the baby's temperature to 34C for 72 hours. The consequences, of a lack of oxygen, to the brain, around the time of birth can be devastating. Over 30% of those babies with abnormal brain function soon after birth either die or survive with severe permanent brain damage. There is no specific treatment for these infants. Evidence from studies in animals, as well as human adults and a small number of newborn infants, suggests that moderate body cooling started soon after birth in babies with serious abnormal brain function might prevent or reduce brain damage. This project is a multicentre trial, where infants who have suffered from a severe lack of oxygen around birth, are randomised to body cooling to 34C for 72 hours. This will be started as soon as possible after birth at their hospital of birth. If the baby needs to be transported this will be started when the newborn transport team collects the baby for transfer to a newborn intensive care unit. This new treatment will be compared with maintaining the baby's temperature at 37C. This project will investigate a new, simple and pragmatic treatment that might reduce brain damage. If it finds that cooling infants who have been severely deprived of oxygen is an effective and safe treatment, the information will be applicable to any of the very large number of babies around the world who suffer from a serious lack of oxygen around the time of birth.Read moreRead less
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
Newborn babies are at risk of becoming short of oxygen during delivery. Death or brain damage may result. In the days after birth, when the brain is attempting to recover from the lack of oxygen, seizures (also called fits) are common. Seizures may cause further damage to the brain because they release damaging chemicals such as glutamate or because they make extra energy demands on the brain that cannot be met. It is difficult to be certain whether unusual movements or twitches are seizures or ....Newborn babies are at risk of becoming short of oxygen during delivery. Death or brain damage may result. In the days after birth, when the brain is attempting to recover from the lack of oxygen, seizures (also called fits) are common. Seizures may cause further damage to the brain because they release damaging chemicals such as glutamate or because they make extra energy demands on the brain that cannot be met. It is difficult to be certain whether unusual movements or twitches are seizures or not. To detect seizures, it is necessary to measure the EEG, the tiny electrical signals from the brain that can be measured from the scalp using small stick on electrodes. It is difficult to measure EEG, particularly for longer periods, because the electrodes may fall off, the baby may move excessively or electrical interference may ruin the recording. We are proposing to measure EEG for 48 hours in babies who have suffered a lack of oxygen during delivery. We will develop, optimise and implement a new method of automatically detecting seizures, building upon 6 years of fundamental signal processing research work that we have done in the newborn. We will test this system against the 'gold standard' to determine how accurate it will be in detecting seizures. We will also try to find out whether damage in particular areas of the brain or in particular cell types within the brain is most likely to be associated with seizures. The anticipated outcome is that we will be able to accurately identify seizures. This is a major step on the path to being able to prevent injury to the brain and to monitor the effectiveness of new experimental treatments.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
Mechanisms Contributing To Long-term Neuronal Loss After Hypoxia-ischemia In The Premature Neonate Brain.
Funder
National Health and Medical Research Council
Funding Amount
$432,535.00
Summary
A lack of oxygen (hypoxia) and blood flow to the brain (ischemia) around the time of birth can cause brain injury that perists into adulthood. The burdens on financial, educational and healthcare resources are enormous. We will improve our understanding of what parts of the brain are injured and the mechanisms contributing to on-going brain injury after hypoxia-ischemia.This is important to devise treatments and to provide a healthy start to life for neonates.