Premature Infants Have Lower Gastric Digestion Capacity for Human Milk Proteins Than Term Infants

Overview

Journal J Pediatr Gastroenterol Nutr

Publisher Wiley

Date 2017 Nov 15

PMID 29135822

Citations 20

Authors

Veronique Demers-Mathieu

Yunyao Qu

Mark A Underwood

Robyn Borghese

David Charles Dallas

Affiliations

Soon will be listed here.

Abstract

Objectives: Whether premature infants have lower gastric protein digestive capacity than term infants and the extent to which human milk proteases contribute to overall gastric digestion are unknown and were investigated in this study.

Methods: Human milk and infant gastric samples were collected from 16 preterm (24-32 wk gestational age) and 6 term (38-40 wk gestational age) mother-infant pairs within a range of 5 to 42 days postnatal age. For each pair, an aliquot of human milk was adjusted to pH 4.5 and incubated for 2 hours at 37 °C to simulate the gastric conditions without pepsin (milkinc). Their gastric protein digestion capacity was measured as proteolysis (free N-terminals) and protease activities. Two-way analysis of variance followed by Tukey post hoc test was applied to compare measurements between preterm and term infants as well as among human milk, milkinc, and gastric samples.

Results: Measurements of gastric protein digestion were significantly lower in preterm infants than term infants. Overall milk protease activity did not differ between human milk samples from term- and preterm-delivering mothers. As protease activity did not increase with simulated gastric incubation, milk proteases likely contributed minimally to gastric digestion.

Conclusions: Preterm infants have lower gastric protein digestion capacity than term infants, which could impair nutrient acquisition. Human milk proteases contribute minimally to overall gastric digestion. The limited activity of milk proteases suggests that these enzymes cannot compensate for the premature infant's overall lower gastric protein digestion.

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