Boosting the value of insoluble dietary fiber to increase gut fermentability through food processing

Insoluble dietary fibers are typically known to be poorly fermented in the large intestine. However, their value may be high as evidence shows that important butyrogenic bacteria preferentially utilize insoluble substrates to support their energy needs. The objective of this study was to increase fe...

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Bibliographic Details
Published in:Food & function 2021-11, Vol.12 (21), p.1658-1666
Main Authors: Lamothe, Lisa M, Cantu-Jungles, Thaisa M, Chen, Tingting, Green, Stefan, Naqib, Ankur, Srichuwong, Sathaporn, Hamaker, Bruce R
Format: Article
Language:English
Subjects:
Accessibility
Acetic acid
Bacteria
Bacteroidetes
Dietary fiber
Dietary Fiber - administration & dosage
Dietary Fiber - analysis
Digestive system
Fatty acids
Fatty Acids, Volatile
Feces - microbiology
Fermentation
Fermented food
Fibers
Firmicutes
Food Handling
Food processing
Gastrointestinal tract
Gene sequencing
Humans
Intestine
Large intestine
Microbiota
Microwaves
Millet
Pennisetum - chemistry
Pennisetum glaucum
rRNA 16S
Substrates
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Summary:Insoluble dietary fibers are typically known to be poorly fermented in the large intestine. However, their value may be high as evidence shows that important butyrogenic bacteria preferentially utilize insoluble substrates to support their energy needs. The objective of this study was to increase fermentability of an insoluble bran fiber (pearl millet) while keeping it mostly insoluble to promote bacteria in the community that rely on fermentable insoluble dietary fibers. Following pretests with different processing methods, a combination of microwave and enzymatic treatments were applied to isolated pearl millet fiber to increase its accessibility of gut bacteria. In vitro human fecal fermentation was conducted and analyses were made for short chain fatty acids and microbiota changes. Combined microwave and enzymatic processing increased the amount of insoluble fiber fermented in vitro from 36 to 59% of total dietary fiber, with a minor increase in soluble fiber (8%). Microwave/enzymatic processing doubled butyrate production and almost tripled acetate production at 6 h fermentation compared to the native millet fiber. 16S rRNA gene sequencing showed that the processing promoted a significant increase in Firmicutes/Bacteroidetes ratio compared to the native fiber with relative abundance increases in Blautia and Copprococcus genera and a decrease in Bacteroidetes. Overall, these data show that processing techniques can be used to increase the value of insoluble fiber, presumably by increasing accessibility of the fiber to degrading bacteria, and to support Firmicutes that preferentially compete on insoluble fibers. Processing can increase the fermentability of insoluble dietary fibers by the human gut microbiota.
ISSN:2042-6496
2042-650X
DOI:10.1039/d1fo02146j