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Development of a dedicated repertoire and food frequency questionnaire for estimating dietary fiber intake taking into account prebiotic (oligo)saccharides
- Audrey M. Neyrinck, Julie-Anne Nazare, Monique Sothier, Laurie Vandenberghe, Camille Amadieu, Julie Rodriguez, Maud Alligier, Martine Laville, Nathalie M. Delzenne
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- Journal:
- Proceedings of the Nutrition Society / Volume 79 / Issue OCE2 / 2020
- Published online by Cambridge University Press:
- 10 June 2020, E422
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Rationale
The scientific rationale for the recommendation in dietary fiber (DF) intake comes from the recognition of their health benefits. European Food Safety Authority (EFSA) recommend 25 g/d, based on the amount needed for intestinal laxation. Gut microbiota related health benefits are not yet included in the current dietary recommendations. Appropriate (and consensual) quantitative and qualitative analysis of DF are missing in food composition tables. One of the aim of the FiberTAG(1) project was to develop a dedicated database and a food frequency questionnaire (FFQ) allowing DF intake estimation including prebiotic (oligo)saccharides.
MethodsA repertoire of DF detailing total, soluble and insoluble DF in food products consumed in Europe has been established based on the Souci-Fachmann-Kraut database, completed for soluble versus insoluble DF () and for prebiotic (oligo)saccharide levels using published data. The FiberTAG FFQ was submitted to healthy volunteers (7 men, 8 women; mean age: 21 yrs; mean BMI: 22kg/m2) and DF intakes were calculated using the new FiberTAG repertoire.
ResultsThe FiberTAG repertoire detailed DF in 400 food items allocated into 4 categories (fruits, vegetables, cereal products and others) and 15 subcategories. The fiberTAG FFQ consists in 280 items regrouped in 4 high DF-containing food groups (vegetables including legumes, fruits including nuts and seed, cereal products and others) using frequency scale (6 categories), photographs for portion size and taking into account the seasonal occurrence for some vegetables or fruits. Data obtained from FiberTAG FFQ indicate a total DF intake of 36.44 g/d. This reveals a higher DF intake compared to previously reported intake for adults in Europe ranging from 16 to 24 g/d based on 24 h-recall or 3–7 days records(2). This difference might be explained by a more adequate inclusion of fruits and vegetables intake in FFQ than with other methods, as previously reported(3). Our data also showed that fructan, inulin and fructo-oligosaccharides intakes were 4.18, 2.95 and 1.00 g/day, respectively whereas galacto-oligosaccharides intake was 0.28 g/d.
ConclusionThe new FiberTAG DF repertoire and FFQ are tools to evaluate the total amount of DF including prebiotic (oligo)saccharides ingested by healthy volunteers. The FiberTAG project generates scientific knowledge that helps to take into account microbiota-nutrient interactions to establish DF intake recommendations as part of healthy lifestyles.
Metabolic breath signature of 13C-enriched wheat bran consumption related to gut fermentation in humans: a Fiber-TAG study
- Anne-Esther Breyton, Valérie Sauvinet, Laure Meiller, Stéphanie Lambert-Porcheron, Christelle Machon, Anne Mialon, Laurie Vandenberghe, Monique Sothier, Sylvie Normand, Alexandra Meynier, Maud Alligier, Audrey Neyrinck, Martine Laville, Nathalie Delzenne, Sophie Vinoy, Julie-Anne Nazare
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- Journal:
- Proceedings of the Nutrition Society / Volume 79 / Issue OCE2 / 2020
- Published online by Cambridge University Press:
- 10 June 2020, E132
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- Article
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AbstractIntroduction
Dietary fibers (DF) have been classified mainly according to their physico-chemical and fermentability properties but it remains unclear whether such classification is relevant when addressing their health effects. Indeed, the nature of physiological effects induced by DF, particularly through their interaction with gut microbiota, remains poorly known due to their diversity, to gut microbiota inter-subjects variability and to the lack of validated non-invasive biomarkers to characterize DF-gut microbiota interaction. The aim of this pilot study was 1) to follow the metabolic fate of 13C-labeled DF through the assessment of 13C-labelled gut-derived metabolites in excreted breath and 2) to evaluate novel non-invasive breath-derived biomarkers of DF-gut microbiota interactions.
Materials and methodsSix healthy women (29.7 ± 1.7 years old, BMI: 23.2 ± 0.9kg/m2, fiber intake: 23 ± 1g/d) consumed in research settings a controlled breakfast containing eight 13C-labelled wheat bran biscuits (50 g of labelled wheat bran, 3.0At%13C). 13C-labelled wheat bran was obtained from wheat cultivated under 13CO2 enriched atmosphere. Samples of expired gases were collected during 24 h after ingestion in order to measure H2 and CH4 by gas chromatography (GC) with piezoelectric detection and 13CO2 and 13CH4 by gas chromatography coupled with an isotope ratio mass spectrometer (GC-IRMS). Apart test breakfast, subjects only consumed standardized meals without fibers.
ResultsThe analysis of H2 and CH4 24h-kinetic measurements distinguished 2 groups in terms of fermentation related gas excretion: the high-CH4 producers with high baseline CH4 concentrations (42.1 ± 13.7ppm) and low baseline H2 concentrations (7.3 ± 5.8ppm) and the low-CH4 producers with low baseline CH4 concentrations (6.5 ± 3.6ppm) and high baseline H2 concentrations (20.8 ± 16.0ppm). Following the 13C-wheat bran biscuits’ ingestion, postprandial H2 and CH4 concentrations increased more significantly in the high-CH4 producer subjects. 13C enrichment was detectable in expired gases in all subjects. 13CO2 kinetics were similar for all subjects and correspond to the oxidation of the digestible part of the bran. The appearance of 13CH4 was significantly enhanced and prolonged after 180 min in high-CH4 producers compared to low-CH4 producers, suggesting distinct fiber fermentation profile.
DiscussionThis pilot study allowed to consider novel procedures for development of non-invasive breath biomarkers of fiber-gut microbiota interactions. Assessment of expired gas excretion following 13C-labelled fiber ingestion allowed deciphering distinct fermentation profiles: high-CH4 producers vs low-CH4 producers and accordingly provide a related non-invasive breath metabolic signature of the fiber fermentation for each profile. Further gut microbiota and 13C-metabolites analysis will permit to relate the gut bacteria composition with breath gas excretion kinetics according to fiber fermentation profile.