Boets, E. et al. (2017) Systemic availability and metabolism of colonicderived short-chain fatty acids in healthy subjects: a stable isotope study. Journal of Physiology, 595(2), pp. 541-555. (doi:10.1113/JP272613) This is the author's final accepted version.There may be differences between this version and the published version. You are advised to consult the publisher's version if you wish to cite from it.http://eprints.gla.ac.uk/128777/ Key Point Summary SCFAs are bacterial metabolites produced during colonic fermentation of undigested carbohydrates, such as dietary fibre and prebiotics, and could mediate the interaction between diet, the microbiota and the host. We quantified the fraction of colonic administered SCFA that could be recovered in the systemic circulation, the fraction that was excreted via breath and urine and the fraction that was used as a precursor for glucose, cholesterol and fatty acids. This information is essential to understand the molecular mechanisms by which SCFA beneficially affect physiological functions such as glucose and lipid metabolism and immune function. AbstractThe short-chain fatty acids (SCFAs), acetate, propionate and butyrate are bacterial metabolites that mediate the interaction between diet, the microbiota and the host. In this study, the systemic availability of SCFAs and their incorporation into biologically relevant molecules was quantified. Known amounts of 13 C-labelled acetate, propionate and butyrate were introduced in the colon of 12 healthy subjects using colon delivery capsules and plasma levels of 13 C-SCFAs and of 13 C-glucose, 13 C-cholesterol and 13 C-fatty acids were measured.The butyrate producing capacity of the intestinal microbiota was quantified as well. Systemic availability of colonic-administered acetate, propionate and butyrate was 36%, 9% and 2%, respectively. Conversion of acetate into butyrate (24%) was the most prevalent interconversion by the colonic microbiota and was not related to the butyrate-producing capacity in the faecal samples. Less than 1% of administered acetate was incorporated into cholesterol and <15% in fatty acids. On average, 6% of colonic propionate was incorporated into glucose. The SCFAs were mainly excreted via the lungs after oxidation to 13 CO 2 whereas less than 0.05% of the SCFAs were excreted into urine. These results will allow future evaluation and quantification of SCFAs production from 13 C-labelled fibres in the human colon by measuring 13 C-labelled SCFA concentrations in blood.
In 2012, the world production of starch was 75 million tons. Maize, cassava, wheat and potato are the main botanical origins for starch production with only minor quantities of rice and other starches being produced. These starches are either used by industry as such or following some conversion. When selecting and developing starches for specific purposes, it is important to consider the differences between starches of varying botanical origin. Here, an overview is given of the production, structure, composition, morphology, swelling, gelatinisation, pasting and retrogradation, paste firmness and clarity and freeze–thaw stability of maize, cassava, wheat, potato and rice starches. Differences in properties are largely defined by differences in amylose and amylopectin structures and contents, granular organisation, presence of lipids, proteins and minerals and starch granule size.
In this paper, the current knowledge on properties of starch blends is critically reviewed. Nowadays, chemical modifications are commonly applied to modify starch properties. However, industry calls for alternatives for chemically modified starches to address the consumer's demand for natural food systems. A simple way to impact starch properties is by blending different starches. In some blends, interactions lead to unexpected gelatinization, pasting, gel texture, and retrogradation properties (non‐additive effect), while an additive effect occurs when the behavior of the blend corresponds to what can be expected based on the individual components. Analysis of different studies describing the physicochemical properties of blends brings insight into the role of botanical origin, amylose content, starch‐to‐water ratio, ratio of starches in the blend, etc. in the behavior of the blends. Gelatinization occurs mostly independently in excess water, while at intermediate water content more non‐additive behavior is recorded. Pasting, rheological, and textural properties show primarily non‐additive effects while retrogradation of starch blends occurs mainly in an additive way. Large differences in granule size and swelling power between the starches in a blend lead to uneven moisture distribution during heating of the starch suspension, which results in a different behavior of the blend than what would be expected based on the behavior of the individual starches.
Several studies have suggested that the majority of iron (Fe) and zinc (Zn) in wheat grains are associated with phytate, but a nuanced approach to unravel important tissue-level variation in element speciation within the grain is lacking. Here, we present spatially resolved Fe-speciation data obtained directly from different grain tissues using the newly developed synchrotron-based technique of X-ray absorption near-edge spectroscopy imaging, coupling this with high-definition μ-X-ray fluorescence microscopy to map the co-localization of essential elements. In the aleurone, phosphorus (P) is co-localized with Fe and Zn, and X-ray absorption near-edge structure imaging confirmed that Fe is chelated by phytate in this tissue layer. In the crease tissues, Zn is also positively related to P distribution, albeit less so than in the aleurone. Speciation analysis suggests that Fe is bound to nicotianamine rather than phytate in the nucellar projection, and that more complex Fe structures may also be present. In the embryo, high Zn concentrations are present in the root and shoot primordium, co-occurring with sulfur and presumably bound to thiol groups. Overall, Fe is mainly concentrated in the scutellum and co-localized with P. This high resolution imaging and speciation analysis reveals the complexity of the physiological processes responsible for element accumulation and bioaccessibility.
Short chain fatty acids (SCFA), including acetate, propionate, and butyrate, are produced during bacterial fermentation of undigested carbohydrates in the human colon. In this study, we applied a stable-isotope dilution method to quantify the in vivo colonic production of SCFA in healthy humans after consumption of inulin. Twelve healthy subjects performed a test day during which a primed continuous intravenous infusion with [1-13C]acetate, [1-13C]propionate and [1-13C]butyrate (12, 1.2 and 0.6 μmol·kg−1·min−1, respectively) was applied. They consumed 15 g of inulin with a standard breakfast. Breath and blood samples were collected at regular times during the day over a 12 h period. The endogenous rate of appearance of acetate, propionate, and butyrate was 13.3 ± 4.8, 0.27 ± 0.09, and 0.28 ± 0.12 μmol·kg−1·min−1, respectively. Colonic inulin fermentation was estimated to be 137 ± 75 mmol acetate, 11 ± 9 mmol propionate, and 20 ± 17 mmol butyrate over 12 h, assuming that 40%, 10%, and 5% of colonic derived acetate, propionate, and butyrate enter the systemic circulation. In conclusion, inulin is mainly fermented into acetate and, to lesser extents, into butyrate and propionate. Stable isotope technology allows quantifying the production of the three main SCFA in vivo and proved to be a practical tool to investigate the extent and pattern of SCFA production.
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