Synergism and phenolic bioaccessibility during in vitro co‐digestion of cooked cowpea with orange juice

Synergism and phenolic bioaccessibility during in vitro co‐digestion of cooked cowpea with orange juice

Summary Foods are susceptible to matrix interferences during the gastrointestinal transit that can affect bioactive molecules. We proposed in vitro co‐digestion of cowpea beans and orange juice to assess polyphenols bioaccessibility and synergisms. We performed gastrointestinal simulation combining...

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Published in:International journal of food science & technology Vol. 58; no. 8; pp. 4476 - 4484
Main Authors: Honaiser, Tuany Camila, Arcari, Stefany Grutzmann, Fabiane, Keli Cristina, Rocha, Maurisrael de Moura, Fedrigo, Isabela Maia Toaldo, Arisi, Ana Carolina Maisonnave
Format: Journal Article
Language:English
Published: Oxford Wiley Subscription Services, Inc 01-08-2023
Subjects:
Antioxidant capacity
Beans
bioactive compounds
Bioavailability
Chlorogenic acid
Cowpeas
Digestion
Epicatechin
Food
Fruit juices
Fruits
Gallic acid
gastrointestinal simulation
Heat treatment
Intestine
Juices
legumes
Liquid chromatography
Oranges
Phenolic compounds
Phenols
Polyphenols
Protein interaction
Solvent extraction
Synergism
Vegetables
Vigna unguiculata
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Abstract Summary Foods are susceptible to matrix interferences during the gastrointestinal transit that can affect bioactive molecules. We proposed in vitro co‐digestion of cowpea beans and orange juice to assess polyphenols bioaccessibility and synergisms. We performed gastrointestinal simulation combining beans and a fruit beverage, to mimic a common meal in a more realistic set‐up than the usual single‐food models. Twenty phenolic compounds were released in oral, gastric and intestinal compartments and were identified by HPLC‐DAD. Gallic acid, (−)‐epicatechin and chlorogenic acid were the most bioaccessible polyphenols. Cooking and solvent extraction of cowpea beans affected their polyphenolic concentrations. After digestion, the bioaccessibility indexes were higher for cowpea (136.11%) and cooked cowpea (744.74%) when compared to orange juice (31.87%) indicating that the thermal treatment enhanced the bioaccessibility of cowpea phenolics. The antioxidant capacity was higher in the end of co‐digestion compared to cooked cowpea and orange juice digested alone due to synergistic polyphenol‐polyphenol interactions or polyphenol‐protein interactions. The combination of orange juice with cooked cowpea in co‐digestion promoted high content of some bioaccessible phenolics, with 10 out of 20 compounds showing positive interactions at the intestinal phase, suggesting that food synergisms are not neglectable for beans and citrus polyphenols release during the digestion course. The combination of orange juice with cooked cowpea in co‐digestion promoted high content of some bioaccessible phenolics during gastrointestinal simulation, suggesting food components synergism.
AbstractList Foods are susceptible to matrix interferences during the gastrointestinal transit that can affect bioactive molecules. We proposed in vitro co‐digestion of cowpea beans and orange juice to assess polyphenols bioaccessibility and synergisms. We performed gastrointestinal simulation combining beans and a fruit beverage, to mimic a common meal in a more realistic set‐up than the usual single‐food models. Twenty phenolic compounds were released in oral, gastric and intestinal compartments and were identified by HPLC‐DAD. Gallic acid, (−)‐epicatechin and chlorogenic acid were the most bioaccessible polyphenols. Cooking and solvent extraction of cowpea beans affected their polyphenolic concentrations. After digestion, the bioaccessibility indexes were higher for cowpea (136.11%) and cooked cowpea (744.74%) when compared to orange juice (31.87%) indicating that the thermal treatment enhanced the bioaccessibility of cowpea phenolics. The antioxidant capacity was higher in the end of co‐digestion compared to cooked cowpea and orange juice digested alone due to synergistic polyphenol‐polyphenol interactions or polyphenol‐protein interactions. The combination of orange juice with cooked cowpea in co‐digestion promoted high content of some bioaccessible phenolics, with 10 out of 20 compounds showing positive interactions at the intestinal phase, suggesting that food synergisms are not neglectable for beans and citrus polyphenols release during the digestion course.
Foods are susceptible to matrix interferences during the gastrointestinal transit that can affect bioactive molecules. We proposed in vitro co‐digestion of cowpea beans and orange juice to assess polyphenols bioaccessibility and synergisms. We performed gastrointestinal simulation combining beans and a fruit beverage, to mimic a common meal in a more realistic set‐up than the usual single‐food models. Twenty phenolic compounds were released in oral, gastric and intestinal compartments and were identified by HPLC‐DAD. Gallic acid, (−)‐epicatechin and chlorogenic acid were the most bioaccessible polyphenols. Cooking and solvent extraction of cowpea beans affected their polyphenolic concentrations. After digestion, the bioaccessibility indexes were higher for cowpea (136.11%) and cooked cowpea (744.74%) when compared to orange juice (31.87%) indicating that the thermal treatment enhanced the bioaccessibility of cowpea phenolics. The antioxidant capacity was higher in the end of co‐digestion compared to cooked cowpea and orange juice digested alone due to synergistic polyphenol‐polyphenol interactions or polyphenol‐protein interactions. The combination of orange juice with cooked cowpea in co‐digestion promoted high content of some bioaccessible phenolics, with 10 out of 20 compounds showing positive interactions at the intestinal phase, suggesting that food synergisms are not neglectable for beans and citrus polyphenols release during the digestion course.
Summary Foods are susceptible to matrix interferences during the gastrointestinal transit that can affect bioactive molecules. We proposed in vitro co‐digestion of cowpea beans and orange juice to assess polyphenols bioaccessibility and synergisms. We performed gastrointestinal simulation combining beans and a fruit beverage, to mimic a common meal in a more realistic set‐up than the usual single‐food models. Twenty phenolic compounds were released in oral, gastric and intestinal compartments and were identified by HPLC‐DAD. Gallic acid, (−)‐epicatechin and chlorogenic acid were the most bioaccessible polyphenols. Cooking and solvent extraction of cowpea beans affected their polyphenolic concentrations. After digestion, the bioaccessibility indexes were higher for cowpea (136.11%) and cooked cowpea (744.74%) when compared to orange juice (31.87%) indicating that the thermal treatment enhanced the bioaccessibility of cowpea phenolics. The antioxidant capacity was higher in the end of co‐digestion compared to cooked cowpea and orange juice digested alone due to synergistic polyphenol‐polyphenol interactions or polyphenol‐protein interactions. The combination of orange juice with cooked cowpea in co‐digestion promoted high content of some bioaccessible phenolics, with 10 out of 20 compounds showing positive interactions at the intestinal phase, suggesting that food synergisms are not neglectable for beans and citrus polyphenols release during the digestion course. The combination of orange juice with cooked cowpea in co‐digestion promoted high content of some bioaccessible phenolics during gastrointestinal simulation, suggesting food components synergism.
Author Arcari, Stefany Grutzmann
Fabiane, Keli Cristina
Honaiser, Tuany Camila
Arisi, Ana Carolina Maisonnave
Fedrigo, Isabela Maia Toaldo
Rocha, Maurisrael de Moura
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  fullname: Arisi, Ana Carolina Maisonnave
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CitedBy_id crossref_primary_10_1016_j_foodchem_2023_137780
crossref_primary_10_1111_ijfs_16518
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Snippet Summary Foods are susceptible to matrix interferences during the gastrointestinal transit that can affect bioactive molecules. We proposed in vitro...
Foods are susceptible to matrix interferences during the gastrointestinal transit that can affect bioactive molecules. We proposed in vitro co‐digestion of...
Foods are susceptible to matrix interferences during the gastrointestinal transit that can affect bioactive molecules. We proposed in vitro co‐digestion of...
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SubjectTerms Antioxidant capacity
Beans
bioactive compounds
Bioavailability
Chlorogenic acid
Cowpeas
Digestion
Epicatechin
Food
Fruit juices
Fruits
Gallic acid
gastrointestinal simulation
Heat treatment
Intestine
Juices
legumes
Liquid chromatography
Oranges
Phenolic compounds
Phenols
Polyphenols
Protein interaction
Solvent extraction
Synergism
Vegetables
Vigna unguiculata
Title Synergism and phenolic bioaccessibility during in vitro co‐digestion of cooked cowpea with orange juice
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fijfs.16144
https://www.proquest.com/docview/2836691072
Volume 58
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