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Fermentation of dietary fibre components in the rat intestinal tract

Nyman, M LU and Asp, N G LU (1982) In British Journal of Nutrition 47(3). p.66-357
Abstract

1. The fermentative breakdown of dietary fibre from various sources in the intestinal tract was studied using rat balance experiments and gas-liquid chromatograhic analysis of dietary fibre monomers in feed and faces. 2. On a basal diet with 690 g maize starch/kg but no added fibre, small but detectable amounts of polymeric glucose, rhamnose, arabinose, xylose, galactose, mannose and uronic acids, i.e. sugars occurring in dietary fibre, were excreted in faeces. 3. Dietary fibre in wheat bran was rather resistant to fermentation; 63% was recovered in the faeces. Guar gum, on the other hand, was almost completely fermented, whereas 19 and 25% of the uronic acids in low and high methoxylated pectin respectively, were excreted in faeces.... (More)

1. The fermentative breakdown of dietary fibre from various sources in the intestinal tract was studied using rat balance experiments and gas-liquid chromatograhic analysis of dietary fibre monomers in feed and faces. 2. On a basal diet with 690 g maize starch/kg but no added fibre, small but detectable amounts of polymeric glucose, rhamnose, arabinose, xylose, galactose, mannose and uronic acids, i.e. sugars occurring in dietary fibre, were excreted in faeces. 3. Dietary fibre in wheat bran was rather resistant to fermentation; 63% was recovered in the faeces. Guar gum, on the other hand, was almost completely fermented, whereas 19 and 25% of the uronic acids in low and high methoxylated pectin respectively, were excreted in faeces. The various constituents of sugar-beet dietary fibre (approximately equal amounts of arabinose-based hemicellulose, pectin and non-starch glucan (cellulose)) showed quite variable availability for micro-organisms in that 6-12% of the arabinose, 17-25% of the uronic acids, and 52-58% of the cellulose were recovered in the faeces. 4. Faecal nitrogen excretion increased on addition of any one of the dietary fibre preparations studied, resulting in decreased true and apparent protein digestibility values. 5. The faecal dry weight increment was most pronounced when feeding bran and could then almost be accounted for by the remaining fibre and by protein. The less-prominent bulking effect of guar gum and pectins, that were much more extensively fermented, could be only partly explained by dietary fibre and protein.

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organization
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type
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publication status
published
subject
keywords
Animals, Carbohydrates/analysis, Dietary Fiber/analysis, Dietary Proteins/metabolism, Feces/analysis, Fermentation, Galactans/metabolism, Intestines/metabolism, Male, Mannans/metabolism, Pectins/metabolism, Plant Gums, Rats, Rats, Inbred Strains, Triticum/metabolism
in
British Journal of Nutrition
volume
47
issue
3
pages
10 pages
publisher
Cambridge University Press
external identifiers
  • scopus:0020134737
  • pmid:6282300
ISSN
0007-1145
DOI
10.1079/BJN19820047
language
English
LU publication?
yes
id
f1bbb187-f27d-46d5-b575-1713f4a4018b
date added to LUP
2018-10-16 18:33:18
date last changed
2024-04-01 11:15:38
@article{f1bbb187-f27d-46d5-b575-1713f4a4018b,
  abstract     = {{<p>1. The fermentative breakdown of dietary fibre from various sources in the intestinal tract was studied using rat balance experiments and gas-liquid chromatograhic analysis of dietary fibre monomers in feed and faces. 2. On a basal diet with 690 g maize starch/kg but no added fibre, small but detectable amounts of polymeric glucose, rhamnose, arabinose, xylose, galactose, mannose and uronic acids, i.e. sugars occurring in dietary fibre, were excreted in faeces. 3. Dietary fibre in wheat bran was rather resistant to fermentation; 63% was recovered in the faeces. Guar gum, on the other hand, was almost completely fermented, whereas 19 and 25% of the uronic acids in low and high methoxylated pectin respectively, were excreted in faeces. The various constituents of sugar-beet dietary fibre (approximately equal amounts of arabinose-based hemicellulose, pectin and non-starch glucan (cellulose)) showed quite variable availability for micro-organisms in that 6-12% of the arabinose, 17-25% of the uronic acids, and 52-58% of the cellulose were recovered in the faeces. 4. Faecal nitrogen excretion increased on addition of any one of the dietary fibre preparations studied, resulting in decreased true and apparent protein digestibility values. 5. The faecal dry weight increment was most pronounced when feeding bran and could then almost be accounted for by the remaining fibre and by protein. The less-prominent bulking effect of guar gum and pectins, that were much more extensively fermented, could be only partly explained by dietary fibre and protein.</p>}},
  author       = {{Nyman, M and Asp, N G}},
  issn         = {{0007-1145}},
  keywords     = {{Animals; Carbohydrates/analysis; Dietary Fiber/analysis; Dietary Proteins/metabolism; Feces/analysis; Fermentation; Galactans/metabolism; Intestines/metabolism; Male; Mannans/metabolism; Pectins/metabolism; Plant Gums; Rats; Rats, Inbred Strains; Triticum/metabolism}},
  language     = {{eng}},
  number       = {{3}},
  pages        = {{66--357}},
  publisher    = {{Cambridge University Press}},
  series       = {{British Journal of Nutrition}},
  title        = {{Fermentation of dietary fibre components in the rat intestinal tract}},
  url          = {{http://dx.doi.org/10.1079/BJN19820047}},
  doi          = {{10.1079/BJN19820047}},
  volume       = {{47}},
  year         = {{1982}},
}