View clinical trials related to Intraventricular Hemorrhage.
Filter by:The research endeavors to examine the critical composition of Polyunsaturated Fatty Acids (PUFAs) in premature infants across different gestational stages and under varying disease conditions, and delineate the metabolic attributes of PUFAs in premature infants and their interplay with the onset of diseases. This study anticipates furnishing a theoretical foundation for the rationalization of PUFAs supplementation in premature infants and for informing strategies related to disease prevention and management.
Background: Multiple neonatal disorders are associated with risks of neurological injury. Thus, management of these infants should involve a coordinated approach to permit early diagnosis with improved clinical care. Such initiative involves the use of standardized protocols, continuous and specialized brain monitoring with electroencephalography (EEG), amplitude integrated EEG (aEEG) and Near Infrared Spectroscopy (NIRS), neuroimaging and training. Brazil is a very large country with disparities in health care assessment; some neonatal intensive care units (NICUs) are not well structured and trained to provide adequate neurocritical care. However, the development and implementation of these neurocritical care units requires high expertise and significant investment of time, manpower and equipment. In order to reduce the existing gap, a unique advanced telemedicine model of neurocritical care called Protecting Brains and Saving Futures (PBSF) protocol was developed and implemented in some Brazilian NICUs. Methods: A prospective observational cohort study will be conducted in 20 Brazilian NICUs that have adopted the PBSF protocol. All infants receiving the protocol during January 2021 to December 2023 will be eligible. Ethical approval will be obtained from the participating institutions. The primary objective is to describe the use of the PBSF protocol and clinical outcomes, by center and over a 3 years period. The use of the PBSF protocol will be measured by quantification of neuromonitoring, neuroimaging exams and sub-specialties consultation. Clinical outcomes of interest after the protocol implementation are length of hospital stay, detection of EEG seizures during hospitalization, use of anticonvulsants, inotropes, and fluid resuscitation, death before hospital discharge, and referral of patients to high-risk infant follow-up. These data will be also compared between infants with primarily neurologic and primarily clinical diagnosis. Discussion: The implementation of the PBSF protocol may provide adequate remote neurocritical care in high-risk infants with optimization of clinical management and improved outcomes. Data from this large, prospective, multicenter study are essential to determine whether neonatal neurocritical units can improve outcomes. Finally, it may offer the necessary framework for larger scale implementation and help in the development of studies of remote neuromonitoring.
Intraventricular haemorrhage (IVH) - bleeding into the normal fluid spaces (ventricles) within the brain - is associated with a high risk of death or significant long-term disability. IVH leads to an increase pressure within the head and triggers inflammation and swelling in the surrounding brain. The ideal treatment for IVH would both rapidly relieve pressure and safely remove as much blood as possible to prevent any further injury to the brain. Currently, patients are managed by inserting a tube into the ventricle that drains fluid to the outside and helps reduce pressure, but does not address the blood clot itself, which naturally dissolves only over several days or weeks. Furthermore, these drains frequently block because of blood clots that for within them. If that occurs a repeat operation is required to replace them. Experimental treatments include infusing drugs to accelerate clot breakdown but this can nonetheless still take a number of days and the process introduces a risk of infection and fresh bleeding. Surgery to remove the blood clot is hazardous, technically challenging, and generally not very successful. Therefore, at the present time, none of the available options achieve all the stated goals of IVH treatment and there is an unmet need for better interventions. In this study the investigators propose to pilot a novel instrument that employs a high pressure but very localised microjet of water to mechanically disrupt blood clots and then sucks the debris away. This technique has been highly successful in reopening blocked arteries in the heart and, importantly, does so without damaging the underlying vessel lining. In the context of IVH, this should allow rapid removal of blood from the ventricles while causing minimal trauma to the brain. Clearing the blood early will prevent the build-up of pressure and inflammation, and improve the chances of patients making a good recovery.
Periventricular leukomalacia (PVL) is one of the most common brain injuries that occur in preterm infants. Inflammation, hypoxia-ischemia, free oxygen radical formation and excitotoxicity are all known pathogenic mechanisms that mediate this injury. Erythropoietin (EPO) has been shown to be protective against hypoxic-ischemic and inflammatory injuries. During the past decade, recombinant human Epo (rhEpo) has been widely used in preterm infants to prevent or treat the anemia of prematurity, in general, rhEpo has been considered to be safe and well tolerated in preterm infants. EPO was considered not capable of passing through blood-brain-barrier at low dose. Evidence from animal experiments reveals that rhEpo must be given in high doses at the beginning or within a short (up to 6 hours), critical time period after the onset of brain injury to achieve a significant neuroprotective effect. A recent study using high-dose rhEpo (3000 U rhEpo/kg body weight at birth) for neuroprotection in very preterm infants revealed that no signs of adverse effects of early high-dose rhEpo treatment in very preterm infants were identified. Contrary to this, a recent study in PVL of a rat model revealed that using a low dose rhEpo (50-100 U/kg) was effective in the treatment of brain damage induced by hypoxia-ischemia and did not affect normal oligodendrocyte maturity. On this basis, the researchers intent to investigate (1) whether low-dose rhEpo (100 U/kg) or high-dose rhEpo (3,000 U/kg) given to very preterm infants (gestation age < 32 weeks) immediately after birth and subsequently during the first 2 days is safe and possesses neuroprotective properties;(2) whether there are gender differences in response to the hypoxia-ischemic insult and EPO treatment; (3)the pharmacokinetics of low dose and high dose rhEPO. Very preterm infants with gestational age of < 32 weeks and admitted to the NICU are eligible for enrollment.