Interaction between protein allergens and model gastric emulsions

G R Burnett; M Wickham; A Fillerty-Travis; J A Robertson; P S Belton; S M Gilbert; A S Tatham; P R Shewry; E N C Mills

doi:10.1042/bst0300916

Interaction between protein allergens and model gastric emulsions

G R Burnett, M Wickham, A Fillerty-Travis, J A Robertson, P S Belton, S M Gilbert, A S Tatham, P R Shewry, E N C Mills

School of Chemistry

Research output: Contribution to journal › Article › peer-review

27 Citations (Scopus)

Abstract

The observed resistance to pepsinolysis of known food allergens has been suggested as a predictor of their allergenic risk. Consequently, resistance to pepsinolysis has become incorporated into decision tree assessment for potential allergenic risk posed by novel foods. However, existing methods take little account of the interaction between food structure and physiological conditions existing during digestion in vivo. Here we show that a range of protein allergens can adsorb to model stomach emulsions, providing a further means of resisting digestion. We also show that raising the pH and the addition of bile salts to a model stomach emulsion, thereby mimicking the duodenal environment, has the effect of desorbing the adsorbed protein.

Original language	English
Pages (from-to)	916-918
Number of pages	3
Journal	Biochemical Society Transactions
Volume	30
Issue number	6
DOIs	https://doi.org/10.1042/bst0300916
Publication status	Published - 2002

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10.1042/bst0300916

Cite this

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title = "Interaction between protein allergens and model gastric emulsions",

abstract = "The observed resistance to pepsinolysis of known food allergens has been suggested as a predictor of their allergenic risk. Consequently, resistance to pepsinolysis has become incorporated into decision tree assessment for potential allergenic risk posed by novel foods. However, existing methods take little account of the interaction between food structure and physiological conditions existing during digestion in vivo. Here we show that a range of protein allergens can adsorb to model stomach emulsions, providing a further means of resisting digestion. We also show that raising the pH and the addition of bile salts to a model stomach emulsion, thereby mimicking the duodenal environment, has the effect of desorbing the adsorbed protein.",

author = "Burnett, {G R} and M Wickham and A Fillerty-Travis and Robertson, {J A} and Belton, {P S} and Gilbert, {S M} and Tatham, {A S} and Shewry, {P R} and Mills, {E N C}",

year = "2002",

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T1 - Interaction between protein allergens and model gastric emulsions

AU - Burnett, G R

AU - Wickham, M

AU - Fillerty-Travis, A

AU - Robertson, J A

AU - Belton, P S

AU - Gilbert, S M

AU - Tatham, A S

AU - Shewry, P R

AU - Mills, E N C

PY - 2002

Y1 - 2002

N2 - The observed resistance to pepsinolysis of known food allergens has been suggested as a predictor of their allergenic risk. Consequently, resistance to pepsinolysis has become incorporated into decision tree assessment for potential allergenic risk posed by novel foods. However, existing methods take little account of the interaction between food structure and physiological conditions existing during digestion in vivo. Here we show that a range of protein allergens can adsorb to model stomach emulsions, providing a further means of resisting digestion. We also show that raising the pH and the addition of bile salts to a model stomach emulsion, thereby mimicking the duodenal environment, has the effect of desorbing the adsorbed protein.

AB - The observed resistance to pepsinolysis of known food allergens has been suggested as a predictor of their allergenic risk. Consequently, resistance to pepsinolysis has become incorporated into decision tree assessment for potential allergenic risk posed by novel foods. However, existing methods take little account of the interaction between food structure and physiological conditions existing during digestion in vivo. Here we show that a range of protein allergens can adsorb to model stomach emulsions, providing a further means of resisting digestion. We also show that raising the pH and the addition of bile salts to a model stomach emulsion, thereby mimicking the duodenal environment, has the effect of desorbing the adsorbed protein.

U2 - 10.1042/bst0300916

DO - 10.1042/bst0300916

M3 - Article

VL - 30

SP - 916

EP - 918

JO - Biochemical Society Transactions

JF - Biochemical Society Transactions

SN - 0300-5127

IS - 6

ER -