View clinical trials related to Neonatal Encephalopathy.
Filter by:The goal of this single centre observational study is to use near-infrared spectroscopy (NIRS) monitoring to investigate cerebral oxygenation in two groups of newborn infants who are at high risk of brain injury. The NIRS monitor used in this study will be the Masimo O3 regional oximeter with neonatal sensors. Near-infrared spectroscopy (NIRS) monitoring uses near-infrared light to measure oxygen levels in the brain tissue (cerebral oxygenation). It provides information about blood flow to the brain and the balance between oxygen supply and demand in the brain tissue. It is non-invasive, safe and used routinely to monitor term and premature babies in the neonatal intensive care unit (NICU). This study will recruit two groups of infants admitted to the NICU who are at risk of brain injury in the newborn period, namely: - Term and near-term babies who are undergoing cooling treatment (therapeutic hypothermia) for moderate to severe hypoxic ischaemic encephalopathy (HIE). - Preterm babies who are born extremely prematurely (before 28 weeks of pregnancy). In the term/near-term group, the primary aims of the study are: - To investigate if cerebral oxygenation during and after cooling treatment relates to markers of brain injury detected on detailed brain scans (MRI and MRS scans). - To describe any changes in cerebral oxygenation which occur during and after seizures (fits) in babies undergoing cooling treatment. In the preterm group, the primary aims of the study are: - To investigate if any changes in cerebral oxygenation occurring during skin-to-skin care are different in premature babies with brain injury (bleeding or cysts in the brain seen on ultrasound scan) compared to babies without these changes. - To investigate if cerebral oxygenation at 36 weeks corrected gestational age differs in babies with bronchopulmonary dysplasia (BDP, a chronic lung disease of prematurity) compared to babies without BPD.
Sovateltide (PMZ-1620; IRL-1620) is targeted to be used as a "Treatment for hypoxic-ischemic encephalopathy in neonates," which is a life-threatening condition. Sovateltide augments neuronal progenitor cell differentiation and better mitochondrial morphology and biogenesis to activate a regenerative response in the central nervous system. The only treatment for HIE is therapeutic hypothermia with limited success, and studies indicate that sovateltide may be beneficial in these patients.
The research team plans to administer trophic enteral feeds to infants with Neonatal Encephalopathy that are undergoing therapeutic hypothermia. The team will monitor splanchnic NIRS values and compare these values to a group of historic infants who underwent hypothermia but did not receive feeds, to investigate whether there may be a range of values that can predict safe feeding. The team will also look at some clinical outcomes including feeding tolerance, time to achieve full enteral feeds, infection rates, length of hospital stay.
The purpose of this study is to see if the use of wireless brain wave monitoring can be helpful for newborns and help their medical providers identify seizures earlier and to monitor for the risk for seizures.
This is a clinical trial using telemedicine as an intervention twice in the first 6 hours of life to assess neonatal encephalopathy, one of the key factors involved in the decision to treat a neonate with therapeutic hypothermia (TH). The investigators aim to enroll up to 30 neonates, anticipating that there will be about 5 neonates, who do not demonstrate moderate to severe neonatal encephalopathy, and therefore do not meet criteria for treatment with TH. The investigators will prospectively follow the clinical course of all 30neonates through monitoring with electroencephalogram (EEG) for up to 24 hours after birth to determine if seizures are present and by MRI of the brain prior to hospital discharge to determine if there is evidence of brain injury. Neonates will be enrolled in the study for the duration of their hospital admission.
Neonatal mortality remains unacceptably high. Globally, the majority of mothers now deliver in health facilities in low resource settings where quality of newborn care is poor. Health systems strengthening through digitial quality improvement systems, such as the Neotree, are a potential solution. The overarching aim of this study is to complete the co-development of NeoTree-gamma with key functionalities configured, operationalised, tested and ready for large scale roll out across low resource settings. Specific study objectives are as follows: 1. To further develop and test the NeoTree at tertiary facilities in Malawi and Zimbabwe 2. To investigate HCPs and parent/carer view of the NeoTree, including how acceptable and usable HCWs find the app, and potential barriers and enablers to implementing/using it in practice. 3. To collect outcome data for newborns from representative sites where NeoTree is not implemented. 4. To test the clinical validity of key NeoTree diagnostic algorithms, e.g. neonatal sepsis and hypoxic ischaemic encephalopathy (HIE) against gold standard or best available standard diagnoses. 5. To add dashboards and data linkage to the functionality of the NeoTree 6. To develop and test proof of concept for communicating daily electronic medical records (EMR) using NeoTree 7. To initiate a multi-country network of newborn health care workers, policy makers and academics. 8. To estimate cost of implementing NeoTree at all sites and potential costs at scale
Babies who have brain injury also frequently have involvement of their kidneys, lung and heart. Although clinical care in the neonatal period is well defined there are few guidelines and evidence for developmental, heart and kidney followup in childhood. The investigators aim to develop and implement guidelines for health care workers and families on Followup after Neonatal Brain Injury. Inflammation is an important factor in brain injury of newborns and also affects their heart lungs and other parts of their body. The investigators will use tests from the newborn period to predict outcome and help parents with planning health needs for their baby rather than waiting until any issues arise later on. By understanding inflammation the investigators can find methods to decrease the negative effects and improve outcomes in the future for babies and families.
The aim of our study is to evaluate the feasibility of applying transcutaneous CO2 monitoring (tcPCO2) in neonates receiving therapeutic hypothermia and to quantify the agreement between tcPCO2 and PCO2 in this population with or without respiratory support. Although, transcutaneous measurement of CO2 tension is the most commonly used non-invasive CO2 monitoring system in neonatal intensive care, to date tcPCO2 technique has not been evaluated systematically or used routinely in the intensive care of infants with neonatal encephalopathy receiving hypothermia treatment.
Hypoxic Ischemic Encephalopathy is also known as 'birth asphyxia related brain injury' and happens when the brain does not receive enough oxygen or blood flow around the time of birth. Birth asphyxia related brain injury is the most common cause of death and neurodisability in term babies. Cooling therapy has substantially improved the outcomes of babies with HIE. However, unacceptably high rate of adverse outcomes are still seen in cooled babies with HIE. The EDEN trial is a 2 arm randomised control trial and aims to examine the physiological effects of Darbepoetin alfa (Darbe) therapy on proton magnetic resonance spectroscopy thalamic N-acetylaspartate (NAA) level in babies with neonatal encephalopathy undergoing cooling therapy. A total of 150 babies with neonatal encephalopathy will be recruited from the participating sites in UK over a 24 month period. The babies will be randomly allocated to darbepoetin or usual care. MR imaging and spectroscopy will be performed at 1 to 2 weeks of age to examine the brain injury. Neurodevelopmental outcomes will be assessed at 18 months of age.
Neonatal anoxia-ischemia causes significant neurodevelopmental disorders. In this study the investigators want to better understand the interactions between the nervous and the hemodynamic cerebral systems during the adaptation of the neonate to ectopic life just after birth. Birth is an at risk situation of neonatal anoxic ischemia and the lack of objective criteria for cerebral tissue oxygenation has consequences on neuronal activity. Ph cord analysis is inadequate and only indirectly reflects the state of cerebral oxygenation. Both neuronal and vascular systems are part of the same functional entity and the analysis of their interactions is likely to reveal some early malfunctions of these networks. In this study, the investigators want to develop a multi-scale, multimodal approach that allows simultaneous interrogation of both neuronal and vascular compartments during the 15 minutes after delivery. The investigators will record, with the aid of a single sensor placed on the scalp of the child, the electroencephalogram and the cerebral tissue oxygenation. The investigators will measure interactions by means of correlation analysis between both signals.