10.3389/fmicb.2018.01618.s004 Hasinika K. A. H. Gamage Hasinika K. A. H. Gamage Sasha G. Tetu Sasha G. Tetu Raymond W. W. Chong Raymond W. W. Chong Daniel Bucio-Noble Daniel Bucio-Noble Carly P. Rosewarne Carly P. Rosewarne Liisa Kautto Liisa Kautto Malcolm S. Ball Malcolm S. Ball Mark P. Molloy Mark P. Molloy Nicolle H. Packer Nicolle H. Packer Ian T. Paulsen Ian T. Paulsen Table_3_Fiber Supplements Derived From Sugarcane Stem, Wheat Dextrin and Psyllium Husk Have Different In Vitro Effects on the Human Gut Microbiota.XLS Frontiers 2018 gut microbiota dietary fiber supplementation in vitro gut models 16S rRNA gene short chain fatty acids polyphenols 2018-07-19 09:52:20 Dataset https://frontiersin.figshare.com/articles/dataset/Table_3_Fiber_Supplements_Derived_From_Sugarcane_Stem_Wheat_Dextrin_and_Psyllium_Husk_Have_Different_In_Vitro_Effects_on_the_Human_Gut_Microbiota_XLS/6839558 <p>There is growing public interest in the use of fiber supplements as a way of increasing dietary fiber intake and potentially improving the gut microbiota composition and digestive health. However, currently there is limited research into the effects of commercially available fiber supplements on the gut microbiota. Here we used an in vitro human digestive and gut microbiota model system to investigate the effect of three commercial fiber products; NutriKaneā„¢, BenefiberĀ® and Psyllium husk (Macro) on the adult gut microbiota. The 16S rRNA gene amplicon sequencing results showed dramatic fiber-dependent changes in the gut microbiota structure and composition. Specific bacterial OTUs within the families Bacteroidaceae, Porphyromonadaceae, Ruminococcaceae, Lachnospiraceae, and Bifidobacteriaceae showed an increase in the relative abundances in the presence of one or more fiber product(s), while Enterobacteriaceae and Pseudomonadaceae showed a reduction in the relative abundances upon addition of all fiber treatments compared to the no added fiber control. Fiber-specific increases in SCFA concentrations showed correlation with the relative abundance of potential SCFA-producing gut bacteria. The chemical composition, antioxidant potential and polyphenolic content profiles of each fiber product were determined and found to be highly variable. Observed product-specific variations could be linked to differences in the chemical composition of the fiber products. The general nature of the fiber-dependent impact was relatively consistent across the individuals, which may demonstrate the potential of the products to alter the gut microbiota in a similar, and predictable direction, despite variability in the starting composition of the individual gut microbiota.</p>