View clinical trials related to Hypoxia-Ischemia, Brain.
Filter by:This study examines the effect of inhaled xenon gas in the treatment of newborn infants with hypoxic-ischemic encephalopathy (HIE) in combination with cooling, which is the standard treatment for this condition. The hypothesis is that the xenon + cooling combination will produce better neuroprotection than the standard treatment of cooling alone.
The brain is such a metabolically active organ that it consumes about 20% of oxygen burned every minute by an average adult even though it only contributes about 2% of the body weight. As a result, the brain produces a disproportionately high amount of CO2 every minute in comparison with the rest of the body.
Neonatal hypoxic ischemic encephalopathy (HIE) is a serious neurological condition characterised by acute or subacute brain injury arising from perinatal hypoxia. HIE is thought to affect approximately 0.2% of live births, and is associated with a high risk of mortality or long-term neurological disability. Accurate biomarkers for long-term neuro-developmental outcome following HIE are extremely important both for clinical management and the evaluation of therapeutic approaches. According to a recent meta-analysis, the ratio of the cerebral concentrations of lactate and N-acetyl aspartate (NAA), two neuro-metabolites detectable with magnetic resonance spectroscopy (MRS), currently represents the most accurate prognostic indicator of outcome following HIE. However, for various technical reasons standard MRS methods do not offer optimal sensitivity for detecting lactate, which may potentially be improved with a custom lactate editing MRS sequence. In addition, while perfusion has also been suggested as a potential biomarker for neuro-developmental outcome following HIE, due to a paucity of MR perfusion imaging studies in neonates, the prognostic accuracy of perfusion MR measures has not been evaluated in comparison with more established MR biomarkers. The aims of this study are: 1. to evaluate the relative sensitivity of a custom lactate editing MRS pulse sequence (specialist software) relative to the standard point resolved (PRESS) MRS sequence for detecting lactate in neonates with suspected HIE. 2. to evaluate the sensitivity and specificity of MR perfusion measures in comparison to MRS measures as predictors of neuro-developmental outcome at 2 years.
Selective head cooling or whole body hypothermia has become the standard of care for neonatal hypoxia-ischemia encephalopathy (HIE). Despite early intervention death or major neurodevelopmental disability still occurs in nearly 50% of infants ≥ 36 weeks gestational age (GA) treated with cooling. No additional therapies have proven to be efficacious in further reducing brain injury and impairment for these high risk infants. Neuroprotective strategies aimed at improving early childhood outcomes are still needed. An important area of study includes therapies that may complement the neuroprotective effects of hypothermia and promote neuronal regeneration, recovery and neurovascular remodeling. Among these therapies, erythropoiesis stimulating agents (ESA) have been shown to provide neuroprotection, improving short and long-term neurologic outcome in brain injury and HIE in neonatal and adult animal models. Parallel with neuroprotective effects in experimental settings, recent small clinical studies suggest improved outcomes after ESA administration in patients with severe traumatic brain injury and HIE. ESA may work through several important mechanisms including reduced inflammation, limited oxidative stress, decreased apoptosis and white matter injury, as well as via pro-angiogenic and neurogenic properties. Darbepoetin alfa (Darbe), a recombinant human erythropoietin (EPO)-derived molecule, has an extended circulating half life and comparable biological activity to EPO, including activation of the EPO receptor. The proposed study is a Phase I/II dose safety and pharmacokinetic trial of early Darbe administered concurrent with hypothermia in human newborn infants with moderate to severe birth asphyxia. The long-term objectives of the proposed research are to reduce mortality and to decrease the risk of long-term disabilities in infants with HIE who survive beyond the newborn period.
The purpose of this study is to determine whether the administration of topiramate to newborns with hypoxic-ischemic encephalopathy potentiates the neuroprotective effect of treatment with hypothermia.
The Optimizing Cooling trial will compare four whole-body cooling treatments for infants born at 36 weeks gestational age or later with hypoxic-ischemic encephalopathy: (1) cooling for 72 hours to 33.5°C; (2) cooling for 120 hours to 33.5°C; (3) cooling for 72 hours to 32.0°C; and (4) cooling for 120 hours to 32.0°C. The objective of this study is to evaluate whether whole-body cooling initiated at less than 6 hours of age and continued for 120 hours and/or a depth at 32.0°C in will reduce death and disability at 18-22 months corrected age.
A prospective randomized control trial to examine safety and effectiveness of whole body cooling to a rectal temperature of 33.5 C using phase changing material in neonatal encephalopathy. Effectiveness will be defined by examining the stability of rectal temperature during cooling. Monitoring of vital signs, infection screen, blood counts, coagulation screen, liver and renal function tests, cranial US and MR imaging will be performed on recruited infants to evaluate safety of cooling. EEG will be performed on day 4 and hearing evaluation at discharge. Neurodevelopmental evaluation will be performed at 1 year of age.
Hundreds of babies in the world are being treated with brain cooling to prevent brain injury after they lose oxygen at birth. This study will use the newly developed information from the magnet resonance image to determine the actual temperature of the brain. This will enable us to determine if the brain is being uniformly cooled and if techniques that provide cooling need to be changed to improve the injury prevention from cooling.
The aim of this study is to determine the efficacy of therapeutic hypothermia following perinatal asphyxia on neurological and neuropsychological outcomes and also to assess academic attainment and any additional health, societal or educational costs associated with changes in outcome as a result of the intervention. This study will determine whether the apparent initial benefits of cooling are maintained in the longer term. Perinatal asphyxia (a lack of oxygen occurring around the time of birth) may have long term consequences on brain functioning, which may be altered by treatment with hypothermia (cooling). Currently, there is no information on the effect of cooling on outcome beyond 18 months of age. We intend to assess at 6 - 7 years of age, the children that participated in the TOBY trial of whole body cooling following perinatal asphyxia and compare between the children that had received the cooling treatment soon after birth and those that were not treated with cooling, the number that survived with an intelligence quotient (IQ) greater than 84, the presence and severity of disabilities, educational attainment and the economic impact on families and service providers. If possible, children will be assessed in their school, with the option of alternative venues such as home or clinic if required. During the assessment a paediatrician will conduct a neurological examination. A psychologist will administer psychometric tests to evaluate cognitive, behavioural and motor development. Questionnaires completed by parents and teachers will complete the data collection. Economic factors will also be assessed in the parent questionnaire. Each child will have contact with the assessors during one school day with appropriate breaks. Assessments will take place over a period of 3 years.
The purpose of this study is to determine whether nerve growth factor (cerebrolysin®) therapy will improve the psychomotor outcome in infants with moderate and severe hypoxic ischemic encephalopathy after hospital discharge.