TY - JOUR
T1 - Degree of hydrolysis is a poor predictor of the sensitizing capacity of whey- and casein-based hydrolysates in a Brown Norway rat model of cow’s milk allergy
AU - Lindholm Bøgh, Katrine
AU - Møller Nielsen, Ditte
AU - Mohammad-Beigi, Hossein
AU - Frahm Christoffersen, Heidi
AU - Neergaard Jacobsen, Lotte
AU - Krogh Norrild, Rasmus
AU - Svensson, Birte
AU - Schmidthaler, Klara
AU - Szépfalusi, Zsolt
AU - Upton, Julia
AU - Eiwegger, Thomas
AU - Bertelsen, Hans
AU - Kai Buell, Alexander
AU - Vestergaard Sørensen, Laila
AU - Madura Larsen, Jeppe
PY - 2024
Y1 - 2024
N2 - The use of infant formulas (IFs) based on hydrolyzed cow’s milk proteins to prevent cow’s milk allergy (CMA) is highly debated. The risk of sensitization to milk proteins induced by IFs may be affected by the degree of hydrolysis (DH) as well as other physicochemical properties of the cow’s milk-based protein hydrolysates within the IFs. The immunogenicity (specific IgG1 induction) and sensitizing capacity (specific IgE induction) of 30 whey- or casein-based hydrolysates with different physicochemical characteristics were compared using an intraperitoneal model of CMA in Brown Norway rats. In general, the whey-based hydrolysates demonstrated higher immunogenicity than casein-based hydrolysates, inducing higher levels of hydrolysate-specific and intact-specific IgG1. The immunogenicity of the hydrolysates was influenced by DH, peptide size distribution profile, peptide aggregation, nano-sized particle formation, and surface hydrophobicity. Yet, only the surface hydrophobicity was found to affect the sensitizing capacity of hydrolysates, as high hydrophobicity was associated with higher levels of specific IgE. The whey- and casein-based hydrolysates exhibited distinct immunological properties with highly diverse molecular composition and physicochemical properties which are not accounted for by measuring DH, which was a poor predictor of sensitizing capacity. Thus, future studies should consider and account for physicochemical characteristics when assessing the sensitizing capacity of cow’s milk-based protein hydrolysates.
AB - The use of infant formulas (IFs) based on hydrolyzed cow’s milk proteins to prevent cow’s milk allergy (CMA) is highly debated. The risk of sensitization to milk proteins induced by IFs may be affected by the degree of hydrolysis (DH) as well as other physicochemical properties of the cow’s milk-based protein hydrolysates within the IFs. The immunogenicity (specific IgG1 induction) and sensitizing capacity (specific IgE induction) of 30 whey- or casein-based hydrolysates with different physicochemical characteristics were compared using an intraperitoneal model of CMA in Brown Norway rats. In general, the whey-based hydrolysates demonstrated higher immunogenicity than casein-based hydrolysates, inducing higher levels of hydrolysate-specific and intact-specific IgG1. The immunogenicity of the hydrolysates was influenced by DH, peptide size distribution profile, peptide aggregation, nano-sized particle formation, and surface hydrophobicity. Yet, only the surface hydrophobicity was found to affect the sensitizing capacity of hydrolysates, as high hydrophobicity was associated with higher levels of specific IgE. The whey- and casein-based hydrolysates exhibited distinct immunological properties with highly diverse molecular composition and physicochemical properties which are not accounted for by measuring DH, which was a poor predictor of sensitizing capacity. Thus, future studies should consider and account for physicochemical characteristics when assessing the sensitizing capacity of cow’s milk-based protein hydrolysates.
KW - Whey
KW - Casein
KW - Hydrolysates
KW - Infant formula
KW - Physicochemical properties
KW - Sensitization
KW - Immunogenicity
KW - IgE
KW - IgG1
KW - Milk allergy
KW - Food allergy
KW - Animal model
U2 - 10.1016/j.foodres.2024.114063
DO - 10.1016/j.foodres.2024.114063
M3 - Journal article
C2 - 38448113
SN - 0963-9969
VL - 181
JO - Food Research International
JF - Food Research International
M1 - 114063
ER -