Active clinical trials for "Enterocolitis, Necrotizing"

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.

Hypothesis to be Tested: Since the first description of intravenous alimentation over half a century ago, parenteral nutrition (PN) has become a common nutritional intervention for conditions characterized by inability to tolerate enteral feeds such as Short Bowel Syndrome, Chronic Intestinal Pseudoobstruction, Microvillus Inclusion Disease, Crohn's disease, multi-organ failure and prematurity. Parenteral Nutrition-Associated Liver Disease (PNALD) encompasses a spectrum of disease including cholestasis, hepatitis, steatosis and gallbladder sludge/stones which may progress to liver cirrhosis and even failure. There is a direct correlation between duration of parenteral nutrition and development of cholestasis in infants. There is evidence in animals and humans that cycling of parental nutrition, defined as infusing nutrients over a time period shorter than 24 hours, reduces cholestasis. There is also data that premature infants with gestational age (GA) < 32 weeks and birth weight <1500g, as well as infants with congenital anomalies of the gastrointestinal tract, are among those at highest risk of developing Parenteral Nutrition-Associated Cholestasis (PNAC). We therefore hypothesize that infants with gestational age (GA) <32 weeks and birth weight (BW) between <1500g, or with congenital anomaly of the gastrointestinal tract regardless of GA or BW, receiving PN over a period of 20 hours will have a decrease severity of PNAC, demonstrated by a lower peak direct bilirubin, compared to a similar control population receiving standard 24 hour infusion.

This proposal will test the hypothesis that synthesis and catabolism of epidermal growth factor (EGF), the genotype of the EGF gene, and the microbiome interact to influence EGF expression in infants at risk for necrotizing enterocolitis (NEC).

Necrotizing enterocolitis (NEC) and intestinal perforation are common in premature infants. Often surgery is needed to remove the dead bowel and create an ostomy (a temporary intestinal opening on the infant's abdomen). Infants with ostomies cannot digest and absorb food well, and must receive nutrition through the blood stream, i.e. parental nutrition (PN). However, prolonged dependence on PN can severely damage the liver and gut. Therefore, giving nutrition through the gut, i.e. enteral nutrition, is the primary treatment for infants with ostomies. Enteral fats, especially polyunsaturated fatty acids (PUFA), are most beneficial in stimulating gut mucosal adaptation, which begins 24 to 48 hours following bowel resection. In addition, the premature intestine has a rapid growth rate. It is likely that the current clinical practice of giving a relatively low-fat diet to infants with ostomies may not meet their high metabolic needs. The investigators hypothesize that increasing dietary fat content by early supplementation with MicroLipid® (ML, n-6 PUFA) and fish oil (FO, n-3 PUFA) to preserve the proper balance of n-6 and n-3 PUFA, may (i) improve bowel adaptation and infant growth; (ii) reduce the use of PN; and (iii) prevent liver damage and/or cholestasis (jaundice) in infants with ostomies.

The purpose of this study was to evaluate the safety of a probiotic foodstuff and its influence on emergence and development of natural intestinal flora and the clinical status of premature very low birth weight neonates. The study was also intended to investigate reduction of colonisation by pathogenic bacteria and to estimate the incidence of gastrointestinal disorders. Probotic bacteria contained in the investigational product administered directly after birth are beneficial for the development of normal gut microflora and can prevent or significantly limit gastrointestinal colonisation by pathogenic bacteria and the development of pathogenic flora in a hospital setting. Permanent colonisation with commensal flora in very early life improves gastrointestinal function in premature neonates by reducing the onset of or by decreasing the severity of the signs and symptoms of feeding intolerance and generalised bacterial infections, including sepsis and necrotizing enterocolitis.

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.

Very preterm infants (<32 weeks gestation) with very low birth weight (VLBW, <1500 g) show immaturity of organs and have high nutrient requirements forgrowth 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 VLBW 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 VLBW infants. Mother´s own milk (MM) is considered the best source of EN for VLBW 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 VLBW 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, we hypothesize that BC, used as a fortifier for MM or DM, can induce similar growth and better NEC and LOS resistance, than conventional fortifiers. A pilot trial is required 1) to test the feasibility and initial safety of BC as a fortifier (e.g. similar growth rates and clinical variables as conventional fortification), 2) to calculate the sample size for a later, larger RCT with NEC +LOS as the primary outcome, and 3) record paraclinical outcomes associated with type of fortifier.

Feeding intolerance is a common problem in very preterm infants due to their immature digestive system. This intolerance extends the time to full enteral feeding and thereby also prolongs the time on parenteral nutrition (PN). Prolonged time to full enteral feeding may predispose these infants to a higher risk of growth retardation, infections and organ dysfunctions (e.g. liver, brain). Mother's own milk (MM) is considered the optimal nutrition for preterm infants and is superior to infant formula (including preterm formula, PF) in stimulating gut maturation, feeding tolerance, resistance against necrotizing enterocolitis (NEC) and late-onset sepsis (LOS), and long-term neurodevelopmental outcomes. However, MM is often absent, or not available in sufficient amounts, during the first days or weeks after preterm delivery. Human donor milk (DM) is probably a better supplement to MM than PF, but DM is not available for all hospitals. To supplement insufficient MM during the early neonatal period in hospital settings with no access to donor milk, we suggest that bovine colostrum (BC) may be used instead of PF for very preterm infants during early life. BC, the first milk from cows after birth, is a rich source of protein and bioactive components, including lactoferrin, lysozyme, lactoperoxidase, immunoglobulins, and various growth factors, such as IGF-I and -II, EGFs, and TGF-β. BC has repeatedly been shown to improve gut maturation and NEC/LOS resistance in a well-established piglet model of preterm infants. We suggest a randomized, controlled trial to investigate the effects of BC vs. PF, supplemented to MM during the first 2 weeks, on the time to full enteral feeding in very preterm infants.

Feeding preterm infants is of great challenge in the NICUs. Mother's own milk is considered as the best for the digestive system followed by donor milk. Preterm infant formula is related to more feeding problems and other gut complications in these babies, such as necrotizing enterocolitis. Bovine colostrum contains higher amounts of protein, growth factors and immuno-regulatory components (e.g. immunoglobulins), which has been used in many other situations to promote health. The investigators plan to give bovine colostrum to preterm infants with birth weights between 1000 and 1800 g, or born between 27+0 and 32+6 weeks of gestational age, in order to promote feeding and intestinal health in these babies. This current study is a feasibility pilot study and the investigators hypothesized that supplementing BC to MM (if available) is safe and tolerable when used within the first 10-14 days of life in preterm infants.

During the first four days of life, intestinal fatty acid binding protein (iFABP) is elevated in the urine of premature babies who go on to develop necrotizing enterocolitis (NEC) days to weeks later. This study aims to determine whether the withholding of feedings in babies with an elevated urinary iFABP can reduce the incidence of NEC.