posted on 2016-02-19, 05:46authored byNatalia
N. Rosa, Anna-Marja Aura, Luc Saulnier, Ulla Holopainen-Mantila, Kaisa Poutanen, Valérie Micard
This
work aimed to elucidate the effect of wheat aleurone integrity
on its fermentability, i.e., the formation of short-chain fatty acids
(SCFA) and microbial phenolic metabolites, in an in vitro model using human faecal microbiota as an inoculum. The structure
of aleurone was modified by mechanical (dry grinding) or enzymatic
(xylanase with or without feruloyl esterase) treatments in order to
increase its physical accessibility and degrade its complex cell-wall
network. The ground aleurone (smaller particle size) produced slightly
more SCFA than the native aleurone during the first 8 h but a similar
amount at 24 h (102.5 and 101 mmol/L, respectively). Similar colonic
metabolism of ferulic acid (FA) was observed for native and ground
aleurone. The enzymatic treatments of aleurone allowed a high solubilization
of arabinoxylan (up to 82%) and a high release of FA in its conjugated
and free forms (up to 87%). The enzymatic disintegration of aleurone’s
structure led to a higher concentration and formation rate of the
colonic metabolites of FA (especially phenylpropionic acids) but did
not change significantly the formation of SCFA (81 mmol/L for enzyme
treated versus 101 mmol/L for the native aleurone).