155 research outputs found
Threonine utilization is high in the intestine of piglets
The whole-body threonine requirement in parenterally fed piglets is
substantially lower than that in enterally fed piglets, indicating that
enteral nutrition induces intestinal processes in demand of threonine. We
hypothesized that the percentage of threonine utilization for oxidation
and intestinal protein synthesis by the portal-drained viscera (PDV)
increases when dietary protein intake is reduced. Piglets (n = 18)
received isocaloric normal or protein-restricted diets. After 7 h of
enteral feeding, total threonine utilization, incorporation into
intestinal tissue, and oxidation by the PDV, were determined with stable
isotope methodology [U-(13)C threonine infusion]. Although the absolute
amount of systemic and dietary threonine utilized by the PDV was reduced
in protein-restricted piglets, the percentage of dietary threonine intake
utilized by the PDV did not differ between groups (normal protein 91% vs.
low protein 85%). The incorporation of dietary threonine into the proximal
jejunum was significantly different compared with the other intestinal
segments. Dietary, rather than systemic threonine was preferentially
utilized for protein synthesis in the small intestinal mucosa in piglets
that consumed the normal protein diet (P < 0.05). Threonine oxidation by
the PDV was limited during normal protein feeding. In protein-restricted
pigs, half of the total whole-body oxidation occurred in the PDV. We
conclude that, in vivo, the PDV have a high obligatory visceral
requirement for threonine. The high rate of intestinal threonine
utilization is due mainly to incorporation into mucosal protein
Insulin-like growth factor 1 supplementation supports motor coordination and affects myelination in preterm pigs
IntroductionPreterm infants have increased risk of impaired neurodevelopment to which reduced systemic levels of insulin-like growth factor 1 (IGF-1) in the weeks after birth may play a role. Hence, we hypothesized that postnatal IGF-1 supplementation would improve brain development in preterm pigs, used as a model for preterm infants.MethodsPreterm pigs delivered by cesarean section received recombinant human IGF-1/IGF binding protein-3 complex (rhIGF-1/rhIGFBP-3, 2.25 mg/kg/day) or vehicle from birth to postnatal day 19. Motor function and cognition were assessed by monitoring of in-cage and open field activities, balance beam test, gait parameters, novel object recognition and operant conditioning tests. Collected brains were subject to magnetic resonance imaging (MRI), immunohistochemistry, gene expression analyses and protein synthesis measurements.ResultsThe IGF-1 treatment increased cerebellar protein synthesis rates (both in vivo and ex vivo). Performance in the balance beam test was improved by IGF-1 but not in other neurofunctional tests. The treatment decreased total and relative caudate nucleus weights, without any effects to total brain weight or grey/white matter volumes. Supplementation with IGF-1 reduced myelination in caudate nucleus, cerebellum, and white matter regions and decreased hilar synapse formation, without effects to oligodendrocyte maturation or neuron differentiation. Gene expression analyses indicated enhanced maturation of the GABAergic system in the caudate nucleus (decreased NKCC1:KCC2 ratio) with limited effects in cerebellum or hippocampus.ConclusionSupplemental IGF-1 during the first three weeks after preterm birth may support motor function by enhancing GABAergic maturation in the caudate nucleus, despite reduced myelination. Supplemental IGF-1 may support postnatal brain development in preterm infants, but more studies are required to identify optimal treatment regimens for subgroups of very or extremely preterm infants
Nourishing America’s Preemies Scientists Confront the Challenges of IV Feeding
Each year, more than a half-million infants are born prematurely in the United States. Many of these preemies, particularly those whose tiny digestive systems are simply too underdeveloped to handle mother’s milk or infant formula, may need to be nourished exclusively via intravenous feeding, known as “total parenteral nutrition,” or TPN.
TPN solutions, usually administered at the hospital for anywhere from a few days to a month or more, provide essential nutrients broken down into a very basic form. This liquid is gently and continuously infused into the infant’s bloodstream, completely bypassing the digestive tract.
“TPN helps save the lives of newborns and supports their growth and development, especially of the brain,” says Douglas G. Burrin, an Agricultural Research Service physiologist at the Children’s Nutrition Research Center in Houston, Texas, and a faculty member at Baylor College of Medicine, also in Houston.
But preemies who are on TPN for longer than 2 weeks may develop complications that might affect their health later in life. Since 1998, Burrin and colleague Barbara Stoll, who is also with the nutrition center and the college faculty, have worked with teams of scientists in the United States and abroad to discover more about the unwanted side effects of TPN and to develop new, safe, effective ways to prevent these unintended consequences or, at the very least, to minimize their impact
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