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Impact of cocoa on short chain fatty acid production from ispaghula by colonic bacteria in vitro

Published online by Cambridge University Press:  19 October 2012

B. Mansoorian
Affiliation:
University of Glasgow, Human Nutrition, Yorkhill hospital, Glasgow G3 8SJ, UK
A. Garcia
Affiliation:
University of Glasgow, Human Nutrition, Yorkhill hospital, Glasgow G3 8SJ, UK
E. Combet
Affiliation:
University of Glasgow, Human Nutrition, Yorkhill hospital, Glasgow G3 8SJ, UK
C. A. Edwards
Affiliation:
University of Glasgow, Human Nutrition, Yorkhill hospital, Glasgow G3 8SJ, UK
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Abstract

Type
Abstract
Copyright
Copyright © The Authors 2012

Studies investigating the food matrix interactions between fibre and polyphenols are scarce, especially in humans. In vitro studies have suggested that fermentable carbohydrates can alter the rate of bacterial metabolism of polyphenols and the concentrations of intermediate( Reference Jaganath, Mullen and Lean 1 ) and final metabolites( Reference Saura-Calixto, Perez-Jimenez and Tourino 2 ). Several polyphenols have been shown to have antibacterial properties( Reference Kurek, Grudniak and Kraczkiewicz-Dowjat 3 , Reference Cushnie and Lamb 4 ) which may potentially inhibit carbohydrate fermentation. In animal studies, polyphenolics had little impact on fibre fermentation( Reference Juskiewicz, Zary-Sikorska and Zdunczyk 5 ). In this study, the impact of cocoa (C) on fermentation of ispaghula (I, psyllium husk) was investigated. Fresh faecal samples from 10 healthy volunteers (21–34 years) who followed a low polyphenol diet 3 days before sample collection were used to inoculate an in-vitro fermentation model( Reference Edwards, Gibson and Champ 6 ). Fibre (1 g) and dark cocoa (0.5 g extra brute Cocoa-Cacao Barr, Barry Callebaut, Hardricourt, France; 0.13 g fibre) were added to 50 ml incubation bottles based on physiological proportions. Short chain fatty acids in fermentation fluid were estimated in duplicate by gas chromatography (FID)( Reference Laurentin and Edwards 7 ).

The fermentation of ispaghula (I) was as expected with a higher propionic acid production, albeit at a slower rate than cocoa (C). Thus propionic acid production was higher in the combined C+I incubations than those containing C or I alone at 6 h, however at 24 h no difference was observed when compared with I on its own (Figure). Similar results were observed for acetic acid, butyric acid and total short chain fatty acids although there was no significant difference between cocoa+ispaghula and cocoa for butyric acid. A predicted SCFA production was calculated by assuming the interaction of the fermentation of the ispaghula and fibre in cocoa was additive and compared to the actual SCFA of the mixture. There was no difference between predicted and actual values for the ispaghula+cocoa combination. This data does not support any inhibitory effect of cocoa polyphenolics on fermentation of ispaghula.

References

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