2020
DOI: 10.3390/pr8080925
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Non-Extractable Polyphenols from Food By-Products: Current Knowledge on Recovery, Characterisation, and Potential Applications

Abstract: Non-extractable polyphenols (NEPs), or bound polyphenols, are a significant fraction of polyphenols that are retained in the extraction residues after conventional aqueous organic solvent extraction. They include both high molecular weight polymeric polyphenols and low molecular weight phenolics attached to macromolecules. Current knowledge proved that these bioactive compounds possess high antioxidant, antidiabetic, and other biological activities. Plant-based food by-products, such as peels, pomace, and seed… Show more

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Cited by 39 publications
(13 citation statements)
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References 125 publications
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“…(Poly)phenol polymers, which represent a large proportion of those ingested in the diet, are often intimately bound through hydrophobic and hydrogen bonds to plant cell wall matrix and therefore reach the colon in the form of (poly)phenolic fibers ( 235 , 236 ). A clear case of fiber-associated (poly)phenols are polymeric flavan-3-ols, whose fermentation leads to SCFA biosynthesis while releasing the so-called “non-extractable (poly)phenols” ( 237 , 238 ), thereby illustrating another example of trophic interactions in the gut environment. For instance, Mateos-Martin et al ( 239 ) studied the fate and metabolism of grape dietary fiber rich in non-extractible PAC (14.8%), in female Sprague–Dawley rats for 24 h. The grape residues obtained after extraction with 70% acetone were rich sources of non-extractible PAC polymers.…”
Section: Trophic Interactions Influencing Microbial Ecology Upon (Poly)phenol-rich Food Intakementioning
confidence: 99%
“…(Poly)phenol polymers, which represent a large proportion of those ingested in the diet, are often intimately bound through hydrophobic and hydrogen bonds to plant cell wall matrix and therefore reach the colon in the form of (poly)phenolic fibers ( 235 , 236 ). A clear case of fiber-associated (poly)phenols are polymeric flavan-3-ols, whose fermentation leads to SCFA biosynthesis while releasing the so-called “non-extractable (poly)phenols” ( 237 , 238 ), thereby illustrating another example of trophic interactions in the gut environment. For instance, Mateos-Martin et al ( 239 ) studied the fate and metabolism of grape dietary fiber rich in non-extractible PAC (14.8%), in female Sprague–Dawley rats for 24 h. The grape residues obtained after extraction with 70% acetone were rich sources of non-extractible PAC polymers.…”
Section: Trophic Interactions Influencing Microbial Ecology Upon (Poly)phenol-rich Food Intakementioning
confidence: 99%
“…Bound phenolics are also known as non-extractable polyphenols (NEP's), and alkaline hydrolysis is one of the technical modality to achieve effective recovery of bound phenolics (Dzah et al, 2020). The possible reason for higher TPC of SDF-derived bound phenolics might the possibility of induction of cleavage due to alkaline pH between ester bonds existing between cell wall and phenolic acids which further led to achieve increased mass transfer of phenolic compounds from grape pomace matrix (Ding et al, 2020). Naturally, it is evident that change in bound phenolic content may exert significant effect on antioxidant capacity measured through ABTS and FRAP assays.…”
Section: Tpc and Antioxidant Activitiesmentioning
confidence: 99%
“…Unlike extractable polyphenols, non-extractable polyphenols are not extractable by organic solvents. They are generally higher molecular weight polyphenols, with a complex structure that can form polymeric compounds or bind to carbohydrates or proteins [ 7 , 8 ]. Such interactions can modify the bioaccessibility, bioavailability and bioefficacy of polyphenols.…”
Section: Introductionmentioning
confidence: 99%