View clinical trials related to Necrotizing Enterocolitis.
Filter by:The aim of the project is to study the effects of fortification (using a Human Milk Donor Fortifier) of an exclusive preterm human milk diet on outcome of extremely preterm neonates, born at less or equal to 27 weeks.
BACKGROUND Treatment of neonatal respiratory distress syndrome with exogenous surfactant and mechanical ventilation made millions of preterm infants survived in neonatal intensive care unit (NICU). Endotracheal intubation surfactant administration is related to invasive intubation and short periods of positive pressure ventilation and implies the risk of lung injury. Continuous positive airway pressure (CPAP) or NIPPV (Non-invasive positive pressure ventilation) with surfactant but without intubation may work synergistically. This randomized trial investigated a minimal invasive surfactant administration (MISA). To test the hypothesis that MISA increases survival without bronchopulmonary dysplasia (BPD) at 36 weeks' gestational age in very low birth weight infants. DESIGN, SETTING, AND PARTICIPANTS The Minimal Invasive Surfactant Administration (MISA) was a multicenter, randomized, clinical, parallel-group study conducted between July 1st, 2017, and November 30, 2018, in 8 level III neonatal intensive care units in Beijing, Tianjin, and Hebei province, China. The final follow-up date was March 30, 2019. Participants enrolled spontaneously breathing preterm infants born between 26.1 and 31.9 weeks' gestational age with signs of respiratory distress syndrome. In an intention-to-treat design, infants were randomly assigned to receive surfactant (Calf pulmonary surfactant, Double-Crane Pharmaceutical Co., China) either via a 5Fr nasogastric tube during CPAP/NIPPV-assisted spontaneous breathing (minimal invasive surfactant administration group, MISA group) or after conventional endotracheal intubation during mechanical ventilation (endotracheal intubation surfactant administration group, EISA group). INTERVENTION MISA via a 5Fr nasogastric tube with an ophthalmic surgery straight forceps.
This is an observational study to identify genetic risks for neonatal diseases, necrotizing enterocolitis (NEC) using genome-wide association study (GWAS) and enterotype investigation. We hypothesize that specific genetic factors and microbiome could predispose preterm neonates for the development of NEC.
Background: Intestinal resections are commonly performed in the pediatric population. Perfusion of the bowel is one of the most important factors determining the viability of an intestinal anastomosis. Up to date, no ideal method to assess intestinal perfusion has proven its superiority. Objectives: Primary: The aim of this study is to establish the feasibility and impact of the use of indocyanine green technology on intestinal resection margins during elective and emergency pediatric surgeries. Secondary: The secondary outcomes of interest include collection of adverse events and difficulties encountered with the use of the indocyanine green (ICG) technology. Postoperative surgical complications will also be recorded. Study Design: An open observational clinical study will be performed by using a clinical drug (indocyanine green) and medical device (SPY Fluorescence Imaging) to assess intraoperatively intestinal perfusion in a specific pediatric population.
Necrotizing enterocolitis (NEC) is a devastating disease affecting the intestines of premature infants. It involves intestine swelling, tissue destruction, infection, and even death. Improved outcome is highly dependent on early recognition and treatment, however the signs and symptoms of NEC in early stages are not obvious making it difficult to diagnose. Abdominal x-rays and ultrasound can be non-specific and may not show signs of the disease until late in its course. Infrared imaging is a non-invasive, non-radiation method that can measure the heat given off of the surface of the body and create heat maps. It is being used clinically in other situations but is still under investigation for use in preterm infants with suspected NEC. Computer analysis of the measured heat maps can be used to detect changes in the intestine such as the swelling or tissue destruction involved in NEC. Our group has previously performed a pilot study that showed that infrared imaging on babies in the NICU can be used to create heat maps that are different between normal babies and those with NEC when analyzed using specialized computer programs. In this study the investigators will improve the imaging process by using special vision sensors to automate the imaging process and make it easier for bedside staff to use this technology. Special programs will be developed to automatically select areas of interest over which temperature maps will be analyzed. The investigators will use this new imaging technique to study a population of newborns diagnosed with definitive NEC and a healthy population of newborns without NEC, and compare the heat maps obtained from each group. From the analysis of the images obtained from these two populations, the investigators will determine the suitability and necessary fine-tuning of this new imaging technique with the hopes that this technology can someday aid in the early diagnosis of NEC.
IBP-9414 will be evaluated in preterm infants with a birth weight of 500-1500g, compared to placebo with regards to efficacy and safety in the prevention of necrotizing enterocolitis.
Necrotizing enterocolitis is the most common gastroenterological emergency in neonatology. Its mortality is high, ranging from 15 to 30%. Prematurity is the main risk factor for necrotizing enterocolitis, as well as the very low birth weight (<1500 g) associated with prematurity. Among the early neonatal complications of intrauterine growth restriction neonates, necrotizing enterocolitis is frequently reported in the literature. The situation of chronic hypoxia of these fetuses is at the origin of a vascular redistribution favoring the cerebral circulation to the detriment of the mesenteric vascularization, which could lead to the development of an necrotizing enterocolitis. However, data from the literature concerning this over-risk of necrotizing enterocolitis in the case of intrauterine growth restriction are discordant. The heterogeneity of the definitions used for the intrauterine growth restriction and diagnostic criteria for necrotizing enterocolitis from one study to another could explain these discrepancies. The investigator's hypothesis is that the risk of necrotizing enterocolitis is higher among newborns in intrauterine growth restriction compared to control children.
Very preterm infants (<32 weeks gestation) show the immaturity of organs and have high nutrient requirements for growth and development. In the first weeks, they have difficulties tolerating enteral nutrition (EN) and are often given supplemental parenteral nutrition (PN). A fast transition to full EN is important to improve gut maturation and reduce the high risk of late-onset sepsis (LOS), related to their immature immunity in gut and blood. Conversely, too fast increase of EN predisposes to feeding intolerance and necrotizing enterocolitis (NEC). Further, human milk feeding is not sufficient to support nutrient requirements for growth of very preterm infants. Thus, it remains a difficult task to optimize EN transition, achieve adequate nutrient intake and growth, and minimize NEC and LOS in the postnatal period of very preterm infants. Mother´s own milk (MM) is considered the best source of EN for very preterm infants and pasteurized human donor milk (DM) is the second choice if MM is absent or not sufficient. The recommended protein intake is 4-4.5 g/kg/d for very low birth infants when the target is a postnatal growth similar to intrauterine growth rates. This amount of protein cannot be met by feeding only MM or DM. Thus, it is common practice to enrich human milk with human milk fortifiers (HMFs, based on ingredients used in infant formulas) to increase growth, bone mineralization and neurodevelopment, starting from 7-14 d after birth and 80-160 ml/kg feeding volume per day. Bovine colostrum (BC) is the first milk from cows after parturition and is rich in protein (80-150 g/L) and bioactive components. These components may improve gut maturation, NEC protection, and nutrient assimilation, even across species. Studies in preterm pigs show that feeding BC alone, or DM fortified with BC, improves growth, gut maturation, and NEC resistance during the first 1-2 weeks, relative to DM, or DM fortified with conventional HMFs. On this background, the investigators hypothesize that BC, used as a fortifier for MM or DM, can reduce feeding intolerance than conventional fortifiers.
This is a randomised controlled multi-centre trial comparing the effect of diet supplementation of a human breast milk-based nutrient fortifier (H2MF®) with standard bovine protein-based nutrient fortifier in 222 extremely preterm infants (born before gestational week 28+0) exclusively fed with human breast milk (own mother´s milk and/or donor milk). The infants will be randomised to receive either the human breast-milk based H2MF® or the standard bovine protein-based nutrient fortifier when oral feeds have reached <100 ml/kg/day. The randomised intervention, stratified by centre, will continue until the target gestational week 34+0. The infant must not be fed with formula during the intervention period. The allocation will be concealed before inclusion, but after randomisation the study is not blinded. Primary endpoint of the intervention is the composite variable necrotizing enterocolitis (NEC), sepsis and mortality. The enrolled infants are characterised with clinical data including growth, feeding intolerance, use of enteral and parenteral nutrition, treatment, antibiotics and complications collected daily in a study specific case report form from birth until discharge from the hospital (not longer than gestational week 44+0). A follow up focusing on neurological development, growth and feeding problems will be performed at 2 years of age (corrected) and 5.5 years of age.
Premature infants are at risk for a variety of diseases, the investigators would like to learn more about why some premature babies are at higher risk and some are protected from these diseases. Scientists at UC Davis and other universities have developed new ways to measure the bacteria and a large number of small molecules in specimens of infant blood, urine, stomach fluid and poop and in mother's milk. These discoveries allow us to consider questions that were impossible to answer before these new techniques were developed. One such question is whether the bacteria in the poop of a premature baby can help us predict the baby's risk for developing infection or a common and serious disease of premature infants called necrotizing enterocolitis. A second question is whether the DNA of a premature baby (obtained from saliva with a q-tip) can predict higher risk for diseases of premature babies.