Dietary proteins extend the survival of Salmonella Dublin in a gastric acid environment

Tina Birk; Kim Kristiansen; Anne Harboe; Tina Beck Hansen; Hanne Ingmer; Rob De Jonge; Katsuhisa Takumi; Søren Aabo

doi:10.4315/0362-028x.jfp-11-132

Dietary proteins extend the survival of Salmonella Dublin in a gastric acid environment

Tina Birk, Kim Kristiansen, Anne Harboe, Tina Beck Hansen, Hanne Ingmer, Rob De Jonge, Katsuhisa Takumi, Søren Aabo

6 Citations (Scopus)

Abstract

The pH of the human stomach is dynamic and changes over time, depending on the composition of the food ingested and a number of host-related factors such as age. To evaluate the number of bacteria surviving the gastric acid barrier, we have developed a simple gastric acid model, in which we mimicked the dynamic pH changes in the human stomach. In the present study, model gastric fluid was set up to imitate pH dynamics in the stomachs of young and elderly people after ingestion of a standard meal. To model a serious foodborne pathogen, we followed the survival of Salmonella enterica serotype Dublin, and found that the addition of proteins such as pepsin, ovalbumin, and blended turkey meat to the simple gastric acid model significantly delayed pathogen inactivation compared with the control, for which no proteins were added. In contrast, no delay in inactivation was observed in the presence of bovine serum albumin, indicating that protection could be protein specific. The simple gastric acid model was validated against a more laborious and complex fermenter model, and similar survival of Salmonella Dublin was observed in both models. Our gastric acid model allowed us to evaluate the influence of food components on survival of pathogens under gastric conditions, and the model could contribute to a broader understanding of the impact of specific food components on the inactivation of pathogens during gastric passage.

Original language	English
Journal	Journal of Food Protection
Volume	75
Issue number	2
Pages (from-to)	353-358
Number of pages	6
ISSN	0362-028X
DOIs	https://doi.org/10.4315/0362-028x.jfp-11-132
Publication status	Published - 2012

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title = "Dietary proteins extend the survival of Salmonella Dublin in a gastric acid environment",

abstract = "The pH of the human stomach is dynamic and changes over time, depending on the composition of the food ingested and a number of host-related factors such as age. To evaluate the number of bacteria surviving the gastric acid barrier, we have developed a simple gastric acid model, in which we mimicked the dynamic pH changes in the human stomach. In the present study, model gastric fluid was set up to imitate pH dynamics in the stomachs of young and elderly people after ingestion of a standard meal. To model a serious foodborne pathogen, we followed the survival of Salmonella enterica serotype Dublin, and found that the addition of proteins such as pepsin, ovalbumin, and blended turkey meat to the simple gastric acid model significantly delayed pathogen inactivation compared with the control, for which no proteins were added. In contrast, no delay in inactivation was observed in the presence of bovine serum albumin, indicating that protection could be protein specific. The simple gastric acid model was validated against a more laborious and complex fermenter model, and similar survival of Salmonella Dublin was observed in both models. Our gastric acid model allowed us to evaluate the influence of food components on survival of pathogens under gastric conditions, and the model could contribute to a broader understanding of the impact of specific food components on the inactivation of pathogens during gastric passage.",

author = "Tina Birk and Kim Kristiansen and Anne Harboe and Hansen, {Tina Beck} and Hanne Ingmer and Jonge, {Rob De} and Katsuhisa Takumi and S{\o}ren Aabo",

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T1 - Dietary proteins extend the survival of Salmonella Dublin in a gastric acid environment

AU - Birk, Tina

AU - Kristiansen, Kim

AU - Harboe, Anne

AU - Hansen, Tina Beck

AU - Ingmer, Hanne

AU - Jonge, Rob De

AU - Takumi, Katsuhisa

AU - Aabo, Søren

PY - 2012

Y1 - 2012

N2 - The pH of the human stomach is dynamic and changes over time, depending on the composition of the food ingested and a number of host-related factors such as age. To evaluate the number of bacteria surviving the gastric acid barrier, we have developed a simple gastric acid model, in which we mimicked the dynamic pH changes in the human stomach. In the present study, model gastric fluid was set up to imitate pH dynamics in the stomachs of young and elderly people after ingestion of a standard meal. To model a serious foodborne pathogen, we followed the survival of Salmonella enterica serotype Dublin, and found that the addition of proteins such as pepsin, ovalbumin, and blended turkey meat to the simple gastric acid model significantly delayed pathogen inactivation compared with the control, for which no proteins were added. In contrast, no delay in inactivation was observed in the presence of bovine serum albumin, indicating that protection could be protein specific. The simple gastric acid model was validated against a more laborious and complex fermenter model, and similar survival of Salmonella Dublin was observed in both models. Our gastric acid model allowed us to evaluate the influence of food components on survival of pathogens under gastric conditions, and the model could contribute to a broader understanding of the impact of specific food components on the inactivation of pathogens during gastric passage.

AB - The pH of the human stomach is dynamic and changes over time, depending on the composition of the food ingested and a number of host-related factors such as age. To evaluate the number of bacteria surviving the gastric acid barrier, we have developed a simple gastric acid model, in which we mimicked the dynamic pH changes in the human stomach. In the present study, model gastric fluid was set up to imitate pH dynamics in the stomachs of young and elderly people after ingestion of a standard meal. To model a serious foodborne pathogen, we followed the survival of Salmonella enterica serotype Dublin, and found that the addition of proteins such as pepsin, ovalbumin, and blended turkey meat to the simple gastric acid model significantly delayed pathogen inactivation compared with the control, for which no proteins were added. In contrast, no delay in inactivation was observed in the presence of bovine serum albumin, indicating that protection could be protein specific. The simple gastric acid model was validated against a more laborious and complex fermenter model, and similar survival of Salmonella Dublin was observed in both models. Our gastric acid model allowed us to evaluate the influence of food components on survival of pathogens under gastric conditions, and the model could contribute to a broader understanding of the impact of specific food components on the inactivation of pathogens during gastric passage.

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DO - 10.4315/0362-028x.jfp-11-132

M3 - Journal article

C2 - 22289597

SN - 0362-028X

VL - 75

SP - 353

EP - 358

JO - Journal of Food Protection

JF - Journal of Food Protection

IS - 2

ER -

Dietary proteins extend the survival of Salmonella Dublin in a gastric acid environment

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