The Structure of Infant Formulas Impacts Their Lipolysis, Proteolysis and Disintegration During in Vitro Gastric Digestion

Overview

Journal Food Chem

Specialties Chemistry
Nutritional Sciences

Date 2015 Apr 6

PMID 25842331

Citations 31

Authors

Claire Bourlieu

Olivia Menard

Alix De La Chevasnerie

Laura Sams

Florence Rousseau

Marie-Noelle Madec

Benoit Robert

Amelie Deglaire

Stephane Pezennec

Said Bouhallab

Frederic Carriere

Didier Dupont

Affiliations

Soon will be listed here.

Abstract

Milk lipids supply most of the calories necessary for newborn growth in maternal milk or infant formulas. The chemical composition of infant formulas has been optimized but not the structure of the emulsion. There is still a major difference between the native emulsions of milk fat globules and processed submicronic emulsions in infant formulas. This difference may modify the kinetics of digestion of emulsions in newborns and influence lipid metabolism. To check this, semi-dynamic gastric in vitro digestions were conducted on three matrices: a standardized milk emulsion containing native milk fat globules referred to as minimally-processed emulsion and two processed model infant formulas (homogenized or homogenized/pasteurized). Gastric conditions mimicked those reported in newborns. The minimally-processed emulsion was lipolyzed and proteolyzed slower than processed formulas. The difference in initial structure persisted during digestion. The surface of the droplets was the key parameter to control gastric lipolysis kinetics, the pattern of released fatty acids and proteolysis by faster hydrolysis of adsorbed proteins.

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