Hostname: page-component-78c5997874-fbnjt Total loading time: 0 Render date: 2024-11-18T09:14:17.142Z Has data issue: false hasContentIssue false

In vitro bioavailability and cellular bioactivity studies of flavonoids and flavonoid-rich plant extracts: questions, considerations and future perspectives

Published online by Cambridge University Press:  01 December 2016

Gerard Bryan Gonzales*
Affiliation:
Laboratory of Food Analysis, Department of Bioanalysis, Faculty of Pharmaceutical Sciences, Ghent University, Ottergemsesteenweg 460 Ghent, Belgium
*
Corresponding author: G. B. Gonzales, email gerard.gonzales@ugent.be
Rights & Permissions [Opens in a new window]

Abstract

In vitro techniques are essential in elucidating biochemical mechanisms and for screening a wide range of possible bioactive candidates. The number of papers published reporting in vitro bioavailability and bioactivity of flavonoids and flavonoid-rich plant extracts is numerous and still increasing. However, even with the present knowledge on the bioavailability and metabolism of flavonoids after oral ingestion, certain inaccuracies still persist in the literature, such as the use of plant extracts to study bioactivity towards vascular cells. There is therefore a need to revisit, even question, these approaches in terms of their biological relevance. In this review, the bioavailability of flavonoid glycosides, the use of cell models for intestinal absorption and the use of flavonoid aglycones and flavonoid-rich plant extracts in in vitro bioactivity studies will be discussed. Here, we focus on the limitations of current in vitro systems and revisit the validity of some in vitro approaches, and not on the detailed mechanism of flavonoid absorption and bioactivity. Based on the results in the review, there is an apparent need for stricter guidelines on publishing data on in vitro data relating to the bioavailability and bioactivity of flavonoids and flavonoid-rich plant extracts.

Type
Conference on ‘New technology in nutrition research and practice’
Copyright
Copyright © The Author 2016 

Flavonoids belong to a large group of secondary plant metabolites called polyphenols. They typically consist of a 15-carbon skeleton consisting of two benzene rings attached via a heterocyclic pyrane ring, labelled as rings A, B and C, in a C6–C3–C6 arrangement. Flavonoids occur either as glycosides, methylated derivatives, bio-conjugates after phase I/II metabolism or aglycones (the basic structure). The position of the B ring may be at the C2-position in the case of most flavonoids or in the C3-position in the case of isoflavones. Common hydroxylation points are at positions 5, 7 (A ring), 3′, 4′, 5′ (B ring), 3 and 2 (C ring). Differences also depend on the presence of the C2 = C3 double bond, and C4-ketone moiety. Fig. 1 shows the basic structures and common classes of flavonoids( Reference Kumar and Pandey 1 , Reference Dai and Mumper 2 ). They are widely available in plant foods, such as Brassica vegetables, onions, fruits and its derivatives like wines and juices.

Fig. 1. Basic structure of the common classes of flavonoids and the common points of glycosylation. Common glycosylation points are C3 and C7 (black arrows). B ring glycosylation is also observed in some plants (hollow arrow). C-glycosides are least found in plants (arrow with dotted lines).

In nature, flavonoids, except for flavan-3-ols, generally occur as glycosides of, most commonly, single units or polymers or hexose, pentose, rhamnose, arabinose and/or their combinations( Reference Cuyckens and Claeys 3 ). These glycosidic moieties are mostly attached to free hydroxyl groups in the A and C rings via a β-glycosidic bond. For instance, flavonols, such as quercetin and kaempferol, are more commonly found as 3-O-glycosides (although 7-O, 3,7-di-O, and B-ring glycosidation also occur in some plants), while 7-O-glycosides are more common for flavones, flavanones and isoflavones( Reference Day, DuPont and Ridley 4 ). Flavonoids may also occur as C-glycosides, wherein the glycoside moiety is directly attached to the aglycone backbone via an acid-resistant C–C bond. C-glycosylation mostly occurs at the C6 and C8 positions( Reference Cuyckens and Claeys 3 ). Flavonoid-C-glycosides however are not as common as their O-glycoside counterparts and have received much less attention in the literature( Reference Xiao, Capanoglu and Jassbi 5 ).

In a survey conducted between 1999 and 2005, adults from fourteen European countries (n 30 000) consumed an average of 428 mg flavonoids/d( Reference Vogiatzoglou, Mulligan and Lentjes 6 ), while a study on US adults reported an average consumption of 345 mg/d( Reference Bai, Wang and Ren 7 ). For both populations, flavan-3-ols from tea constitute most of the flavonoid intake, followed by flavanones, flavonols and anthocyanins, flavones and isoflavones( Reference Vogiatzoglou, Mulligan and Lentjes 6 Reference Chun, Chung and Song 8 ). A survey of the 100 richest sources of polyphenols performed using the online database Phenol-Explorer ( Reference Rothwell, Perez-Jimenez and Neveu 9 ) showed that fruit and vegetables, such as berries and artichoke, contain the most polyphenols per serving and are composed of anthocyanins and flavonols( Reference Perez-Jimenez, Neveu and Vos 10 ). Food in general contains much more flavonoid glycosides compared with their aglycone counterparts( Reference Day, DuPont and Ridley 4 ). Flavonoid glycosides, especially flavonol and isoflavone glycosides, are also generally stable under cooking conditions( Reference Coward, Smith and Kirk 11 , Reference Price, Bacon and Rhodes 12 ).

Results from epidemiological studies revealed that consumption of flavonoid-rich foods has been associated with a reduced risk of death from CHD( Reference Hertog, Feskens and Hollman 13 ) and other chronic diseases such as cancer, asthma and diabetes( Reference Knekt, Kumpulainen and Jarvinen 14 ). These results attracted thousands of in vitro assays to elucidate the bioactivity of flavonoids, including anti-oxidative( Reference Pietta 15 , Reference Fiol, Adermann and Neugart 16 ), anti-hypertensive( Reference Balasuriya and Rupasinghe 17 ), anti-obesity( Reference Hsu and Yen 18 , Reference Kamiloglu, Grootaert and Capanoglu 19 ) anti-viral, hepatoprotective and immune-regulatory activities( Reference Middleton, Kandaswami and Theoharides 20 ), among many others. This has also sparked the interest of several research groups worldwide to screen for bioactive plants, which could potentially provide these health-promoting effects, based on their flavonoid contents.

Bioavailability of flavonoid glycosides

Although epidemiological studies report health-promoting benefits upon chronic consumption of flavonoid-rich foods, the underlying mechanisms behind these effects are difficult to ascertain because of their poor bioavailability in vivo ( Reference Manach, Scalbert and Morand 21 ) due to factors such as food matrix interactions, food processing, host (human)-related factors (e.g. age, occurrence of certain diseases, lifestyle), and most importantly the bioconversion (microbial, phase I/II metabolism) of flavonoids( Reference D'Archivio, Filesi and Vari 22 ). Therefore, it is essential to first ensure that flavonoids present in the plant matrices being studied survive the digestion process and are absorbed by the intestine. Once these conditions are met, only then should potential bioactivity towards enzymes, cells and tissues in the body be investigated.

For instance, while earlier studies have demonstrated that quercetin glycosides are found intact in plasma, it is now generally accepted that such compounds are in fact absent from plasma after nutritional doses( Reference Manach, Williamson and Morand 23 ). Upon reaching the epithelium, flavonoid-O-glycosides are hydrolyzed by either lactase phloridzin hydrolase (LPH), cystolic β-glucosidase, or microbial hydrolases into aglycones. This deglycosylation step has been found to be a critical step in the absorption and metabolism of flavonoid glycosides from the diet in human subjects( Reference Németh, Plumb and Berrin 24 ).

LPH is a brush-border enzyme in small intestinal cells that has a substrate specificity for flavonoid-O-β-glucosides( Reference Day, DuPont and Ridley 4 ) to release aglycones, which can then passively diffuse through epithelial cells due to their lipophilicity( Reference Crozier, Del Rio and Clifford 25 , Reference Liu and Hu 26 ). Dietary flavonoids and isoflavone glycosides are typically hydrolysed by LPH( Reference Kroon, Clifford and Crozier 27 ). Alternatively, it has been earlier suggested that cystolic β-glucosidase hydrolyses glycosides intracellularly when they are transported in the intestinal cells by sodium-dependent glucose transporter 1 (SGLT1)( Reference Day, Canada and Diaz 28 ). Both LPH and cystolic β-glucosidase are expressed by the Caco-2 cell line and ex vivo human small intestinal samples( Reference Nemeth, Plumb and Berrin 29 ). However, β-glucosidase activity in Caco-2 cells is much lower compared with actual intestinal tissue samples( Reference Day, DuPont and Ridley 4 , Reference Németh, Plumb and Berrin 24 ). Previously, flavonoid deglycosylation and metabolism has been thought to only occur via microbial metabolism. However, it has been refuted as more and more evidence suggests that flavonoid glycosides can be absorbed in the small intestine, as described earlier. Exemptions to this however are flavonoid rhamnosides, which need to be metabolised by the bacteria due to the inability to metabolise rhamnose( Reference Manach, Williamson and Morand 23 , Reference Chang, Shin and Yang 30 , Reference Williamson 31 ).

Once intracellular, phase I and II metabolism converts these aglycones into, commonly, glucuronides, sulphates and methyl-esters, which are then either excreted to the blood or effluxed back to the lumen by ATP-binding cassette transporters. The effluxed metabolites and unabsorbed flavonoids are then passed on to the large intestines, where microbial metabolism occurs that convert them back to aglycones and eventually into smaller phenolic acid metabolites( Reference D'Archivio, Filesi and Vari 22 ). Blood from the intestines is then directed to the liver, which metabolizes flavonoids that escaped the first-pass metabolism. Therefore, circulating flavonoids are almost exclusively glucuronides > sulphates > methyl-esters (in this order of abundance)( Reference Williamson 31 , Reference Walle 32 ). These biotransformations along with the role of efflux transporters significantly reduce the bioavailability of flavonoids. In fact, although flavonoid intake reaches >300 mg/d, the concentration of total flavonoid metabolites that reach systemic circulation does not exceed 5 µm after an oral dose challenge( Reference Manach, Williamson and Morand 23 ). This is very important, as this concentration is mostly insufficient to drive a physiologically relevant bioactivity.

Use of Caco-2 cells as model for intestinal transport of flavonoid glycosides

Human colorectal adenocarcinoma Caco-2 cells have been used in in vitro studies as an intestinal model for more than 30 years. The cell line was developed by the Sloan-Kettering Institute for Cancer Research( Reference Mahraoui, Rousset and Dussaulx 33 ). The use of Caco-2 cells to simulate human intestinal absorption grew as more and more evidence suggested that drug transport in human subjects in vivo is highly correlated to the apparent permeability values measured using Caco-2 cells for certain drugs, such as ranitidine HCl, metoprolol tartrate, piroxicam( Reference Polli and Ginski 34 ), minoxidil( Reference Lowenthal and Affrime 35 ), naproxen, antipyrine and metoprolol( Reference Lennernäs, Palm and Fagerholm 36 ). These drugs however are known to diffuse passively both in Caco-2 cells and human intestinal tissue, thus implying that Caco-2 permeability data are rather correlated to passive diffusion and not for actively transported drugs. Caco-2 cell permeability however was found to be 79- and 27-fold lower for the hydrophilic slowly-passively transported drugs terbutaline and atenolol, respectively. The carrier-mediated transport rates of l-dopa, l-leucine and d-glucose were also much slower in Caco-2 cells than in human jejunum. These data indicate that Caco-2 cells are useful to predict passive intestinal transport of molecules in human intestines, but is not a good model for the transport of hydrophilic and actively transported molecules, such as flavonoid glycosides. This has been attributed to the lack of transporter and enzyme expression in Caco-2 cell lines compared with the real human intestinal epithelium( Reference Lennernäs, Palm and Fagerholm 36 ). For instance, the LPH is expressed in Caco-2 cells but its expression is much lower compared with ex vivo intestinal samples( Reference Németh, Plumb and Berrin 24 ). Due to this, the metabolism of flavonoid glycosides in vitro is usually underestimated. In the previous study, kaempferol glucuronides and sulphates were not found at the basal compartment of a Caco-2 Transwell® set-up upon treatment with a kaempferol glycoside-rich cauliflower leaf extract( Reference Gonzales, Smagghe and Mackie 37 ). In vivo, consumption of kaempferol glycoside-rich endive resulted in the appearance of kaempferol glucuronide in plasma( Reference DuPont, Day and Bennett 38 ). Glucuronides and sulphates of flavonoids were also not observed after transport analysis of Xi-aochaichu-tang (a Chinese herbal remedy) using Caco-2 cells( Reference Dai, Yang and Li 39 ). Conversely, while it is now accepted that quercetin glycosides do not exist in blood, Caco-2 cell transport experiments of quercetin glucosides show basolateral transport of these glycosides( Reference Walgren, Walle and Walle 40 , Reference Boyer, Brown and Liu 41 ), which could be misinterpreted as being bioavailable. Quercetin metabolites (glucuronides, especially) were not observed when treating Caco-2 cells with quercetin-3-glucoside in contrast to treatment with quercetin aglycones. It therefore appears that pre-deglycosylation during in vitro intestinal digestion could enhance the intestinal conversion and metabolic conversion of dietary quercetin glucosides( Reference Murota, Shimizu and Chujo 42 ).

The mechanism of absorption of flavonoid glycosides in intestinal cells is controversial. Many reports claim that SGLT1 participates in the cellular uptake of quercetin glycosides from the diet. It has been previously shown that flavonoid glycosides can be transported across intestinal cells by the SGLT1 when there is no efficient uptake by passive diffusion( Reference Jin, Yi and Chen 43 ). However, contradictory results regarding the involvement of SGLT1 in flavonoid intestinal transport exist and thus require further elucidation. For instance, while it was previously reported that quercetin-3-glucoside is taken up across the intestinal cells by SGLT1 in rat small intestines( Reference Walgren, Lin and Kinne 44 ), using SGLT1-expressing Xenopus laevis oocytes showed that neither quercetin, luteolin, apigenin, naringenin, pelarginidin, daidzein, genistein, nor any of their glycosylated derivatives are substrates of this transporter( Reference Kottra and Daniel 45 ). Whether SGLT1 plays a role in flavonoid glycoside uptake or not, it is undoubtedly accepted that deglycosylation exists extracellularly in the intestines and that effective deglycosylation is a critical step for flavonoid glycoside absorption. Therefore, the passive diffusion of the liberated aglycone still remains the more efficient route of absorption, indicating that the participation of SGLT1, if present, is less important.

The lack of LPH expression was previously addressed by treating in vitro digested shallots and onions with lactase (300 units, 37°C, 20 min) before adding to Caco-2 cells. In this study, quercetin absorption of lactase-treated quercetin glycosides increased 14-fold in Caco-2 cells, indicating that lactase treatment could be a good additional step for in vitro intestinal absorption studies( Reference Boyer, Brown and Liu 46 ). Given the importance of deglycosylation on flavonoid glycoside absorption, the use of Caco-2 cell models for intestinal transport without prior deglycosylation steps should be re-evaluated. Steps for deglycosylation after in vitro digestion, i.e. addition of lactase or LPH to the digesta, should be considered prior to Caco-2 transport analysis.

Use of flavonoid aglycones in in vitro bioactivity assays

A previous study on the angiotensin-I-converting enzyme inhibitory activity of flavonoids suggested that the IC50 (concentration needed to reduce angiotensin-I-converting enzyme activity by 50 %) of flavonoids fall within the range 0·4–9·3 mm ( Reference Al Shukor, Van Camp and Gonzales 47 ), which is substantially more than the concentration of flavonoids found in the blood. Moreover, the compounds used in this study were aglycones and not phase I/II metabolites that are normally found in the blood. The use of flavonoid aglycones, without regard to their bioavailability and metabolism has been rampant and still growing rapidly. In 2002, questions on the use of flavonoid aglycones in in vitro systems to test bioactivity was raised( Reference Williamson 31 ). In this review, the validity of papers that reported in vitro bioactivity of high doses of flavonoids aglycones was questioned. Although it is accurate to say that many studies used aglycones in much higher doses than plasma concentrations, recent evidence on the in situ deglucuronidation of flavonoid glucuronides during inflammation suggest that flavonoid aglycones may indeed exist locally in some tissues at concentrations higher than found in the blood( Reference Perez-Vizcaino, Duarte and Santos-Buelga 48 ).

We have also shown previously that cells accumulate flavonoids differently under normal and stressed conditions. Methyl-quercetin was found to accumulate more in valinomycin-stressed cells than in unstressed undifferentiated Caco-2 cells treated with quercetin. More interestingly, quercetin and its methyl-ester derivative were found on the cell membrane of the unstressed cells, whereas they localised intracellularly upon exposure to valinomycin, which caused a recovery in cellular viability and reduction of intracellular reactive oxygen species( Reference Gonzales, Smagghe and Vissenaekens 49 ). These results are interesting as they point to the possibility that local/in situ concentrations of flavonoids (in the affected cells) could be much higher than the concentration of the metabolites in the blood. Unfortunately, no comparative study on the local tissue concentration of flavonoids of healthy v. unhealthy subjects has been reported. However, a previous study on the effect of quercetin supplementation on the blood pressure of stage I hypertensive men compared with normotensive men reported that quercetin supplementation significantly reduced the blood pressure of hypertensive men that is independent of changes in angiotensin-I-converting enzyme activity, endothelin-I or nitric oxide plasma levels( Reference Larson, Witman and Guo 50 ). What is most interesting in the study is that plasma concentrations of normotensive men reached 2·3 (sd 1·8) µm, whereas plasma concentration only reached 0·6 (sd 0·4) µm at 10 h post administration for hypertensive men. It could be possible that the difference in plasma concentrations is caused by local accumulation of quercetin in damaged cells (i.e. vascular cells), which caused the reduction of blood pressure in the hypertensive group.

Given the earlier arguments, it is worth asking whether the dose in in vitro bioactivity assays be limited to the concentration of flavonoid metabolites in the blood. If an average person has about 5 litres blood and if indeed deglucuronidation occurs locally, the concentration of flavonoid aglycones at the site of deglucuronidation (i.e. point of inflammation) will be more than the concentration in the blood as a whole. Further, the use of aglycones in in vitro assays may in fact be valid for some cases. Unfortunately, it is currently not established whether flavonoids are indeed accumulating selectively in damaged tissues and in what form they are present (aglycones or methyl-conjugates). Thus, studies on the concentration of flavonoids and their corresponding form in localised tissues merits further investigation.

Use of flavonoid-rich plant extracts for bioactivity assays

Even with the growing evidence on the limited (even the absence of) bioavailability of flavonoid glycosides and the present understanding of flavonoid absorption and bioactivity, the number of papers published reporting the in vitro bioactivity of flavonoid-rich plant extracts in cellular models is very high and growing.

For instance, a recent study demonstrated that supercritical CO2 extract of spent hop (Humulus lupulus L.), which is dominantly composed of flavanols (procyanidin dimers) and flavonols (quercetin and kaempferol glycosides, including rhamnosides) reduced ADP-induced platelet aggregation, in a concentration-dependent manner when the plant extract was added to both whole blood and platelet-rich plasma of both healthy volunteers and patients with coronary artery disease( Reference Luzak, Golanski and Przygodzki 51 ). In this study however, the plant extracts were directly mixed with the blood samples at a concentration ranging from 1·5–15 µg gallic acid equivalents (GAE)/ml blood. The effect was only observed in coronary artery disease patients when >7 µg GAE/ml was used. Further, human umbilical vein endothelial cells were also exposed to the plant extract to assess cellular viability and antiplatelet activity( Reference Luzak, Golanski and Przygodzki 51 ). However, the data presented would have had more relevance if the bioavailability of the identified compounds in the plant extract was tested. Although an in vivo test was performed, the authors did not analyse the concentration and form of the flavonoids that reached the blood. Based on the present knowledge on the bioavailability of flavonoid glycosides, it is clear that: (a) the total concentration of phenolic metabolites in blood after a flavonoid-rich diet would not reach 1·5 µg GAE/ml blood and (b) flavonoids in blood after consumption of flavonoid-rich foods do not occur as glucosides and definitely not rhamnosides.

In another study, lotus (Nelumbo nucifera) extract, 41·8 mg quercetin equivalents/g (flavonoid profile not reported) was applied to human umbilical vein endothelial cells at a concentration range 10–100 µg GAE/ml culture medium to study its effect against endothelial dysfunction, specifically vascular endothelial growth factor-induced angiogenesis( Reference Lee, Shukla and Kim 52 ). Also, artichoke extract (1–100 µg GAE/ml) was shown to inhibit inducible nitric oxide synthase expression when directly applied to human coronary artery smooth muscle cells( Reference Xia, Pautz and Wollscheid 53 ). Lotus and artichoke have however been previously reported to contain mostly quercetin glucoside and glucuronide( Reference Chen, Wu and Fang 54 ), and luteolin rutinoside and glucoside( Reference Negro, Montesano and Grieco 55 ), respectively. Curly kale (Brassica oleracea L. convar. acephala var. sabellica) extract was also recently reported to reduce TNF-α induced neutrophil adhesion to human umbilical vein endothelial cells via 24-h pre-incubation of the human umbilical vein endothelial cells with curly kale extract( Reference Kuntz and Kunz 56 ). Curly kale has been previously reported to contain mostly highly glycosylated kaempferol and quercetin( Reference Olsen, Aaby and Borge 57 ).

The effect of a flavonoid glycoside-rich extract of a traditional Chinese medicine, semen astragali complanati (Astragalus complanatus R.Br.) on the activation of natural killer-92 cells, a model for natural killer cells found in the blood that combats tumours, was investigated by incubating natural killer-92 cells with 12–200 µg (unspecified whether GAE or per dry weight)/ml semen astragali complanati extract for up to 72 h( Reference Han, Wu and Wu 58 ). Apart from problems relating to concentration and the type of flavonoids present in these extracts, the clearance of polyphenols in the blood was also not considered as flavonoid metabolites do not persist in circulation for 72 h when using a single dose( Reference Hollman 59 ).

It is surprising that although flavonoid glycoside metabolism and bioavailability has been described in many papers dating decades back, very recent papers still do not consider bioavailability and metabolism of flavonoid glycosides as important considerations when assessing in vitro bioactivity. There is therefore a need for stricter acceptance rules or guidelines in reporting in vitro bioactivity of flavonoid-rich plant extracts, or any plant extracts, in the literature. This does not only include research data but also papers reviewing the bioactivity of these plant extracts. For instance, a recent review( Reference Pistollato, Giampieri and Battino 60 ) reported the in vitro bioactivity of several plant extracts on various cancer stem cells. Comments on neither the identity of the active compound nor the bioavailability of these plant components were however made.

Recently, guidelines and recommendations in reporting requirements for bioactive components, such as flavonoids have been published( Reference Somoza, Molyneux and Chen 61 , Reference Balentine, Dwyer and Erdman 62 ). In both guidelines, the bioavailability of the flavonoids in question should be strictly considered when planning and reporting results from in vitro experiments. According to Somoza et al ( Reference Somoza, Molyneux and Chen 61 ), studies should address five focus areas when reporting in vitro bioactivity of plant-based bioactive components: (1) Identification of the active molecule/s using state-of-art spectrometric and spectroscopic techniques; (2) Quantitation of the active components using validated methods; (3) Demonstration of the bioavailability of the bioactive component using relevant in vitro or in/ex vivo models; (4) Unequivocal identification and quantitation of metabolites generated in the bioavailability study; (5) Mechanistic study using the relevant compound.

Many papers, both recent and old, usually pass the first two criteria but generally fail to satisfy the third and fourth. Instead, many jump to the mechanistic study of the compounds found in the plant extract; skipping the bioavailability and metabolism criteria. By following these criteria, the relevance of the data published in literature will be preserved. The implementation of this entails a consensus among scientists and publishers to increase the quality standard for publishing data.

Conclusion

In this review, we have shown that current in vitro systems and approaches need to be reevaluated. There is clearly a need to improve in vitro models for bioavailability, especially for flavonoid glycosides. The analysis of flavonoid accumulation in specific tissues during inflammation or stressed conditions offers a new line of research. Finally, the bioavailability of flavonoids from plant extracts need to be strictly considered when planning in vitro experiments and elucidating their bioactivity towards cellular models, such as vascular cells.

Acknowledgements

The author would like to thank the Belgian Nutrition Society, Prof John Van Camp, Prof Katleen Raes and Prof Guy Smagghe for the technical support. Special thanks also go to Evelien Van Rymenant and Senem Kamiloglu for proofreading the manuscript.

Financial Support

None.

Conflict of Interest

None.

Authorship

The author had sole responsibility for all aspects of preparation of this paper.

References

1. Kumar, S & Pandey, AK (2013) Chemistry and biological activities of flavonoids: an overview. Scientific World J 2013, 16.CrossRefGoogle ScholarPubMed
2. Dai, J & Mumper, RJ (2010) Plant phenolics: extraction, analysis and their antioxidant and anticancer properties. Molecules 15, 73137352.CrossRefGoogle ScholarPubMed
3. Cuyckens, F & Claeys, M (2004) Mass spectrometry in the structural analysis of flavonoids. J Mass Spectrom 39, 115.Google Scholar
4. Day, AJ, DuPont, MS, Ridley, S et al. (1998) Deglycosylation of flavonoid and isoflavonoid glycosides by human small intestine and liver β-glucosidase activity. FEBS Lett 436, 7175.Google Scholar
5. Xiao, J, Capanoglu, E, Jassbi, AR et al. (2016) Advance on the flavonoid C-glycosides and health benefits. Critical Rev Food Sci Nutr 56, S29S45.CrossRefGoogle ScholarPubMed
6. Vogiatzoglou, A, Mulligan, AA, Lentjes, MAH et al. (2015) Flavonoid intake in European adults (18 to 64 years). PLoS ONE 10, e0128132.Google Scholar
7. Bai, W, Wang, C & Ren, C (2014) Intakes of total and individual flavonoids by US adults. Int J Food Sci Nutr 65, 920.Google Scholar
8. Chun, OK, Chung, SJ & Song, WO (2007) Estimated dietary flavonoid intake and major food sources of U.S. adults. J Nutr 137, 12441252.Google Scholar
9. Rothwell, JA, Perez-Jimenez, J, Neveu, V et al. (2013) Phenol-explorer 3·0: a major update of the phenol-explorer database to incorporate data on the effects of food processing on polyphenol content. Database: J Biol Databases Curation 2013, bat070.Google Scholar
10. Perez-Jimenez, J, Neveu, V, Vos, F et al. (2010) Identification of the 100 richest dietary sources of polyphenols: an application of the Phenol-Explorer database. Eur J Clin Nutr 64, S112S120.CrossRefGoogle ScholarPubMed
11. Coward, L, Smith, M, Kirk, M et al. (1998) Chemical modification of isoflavones in soyfoods during cooking and processing. Am J Clin Nutr 68, 1486S1491S.Google Scholar
12. Price, KR, Bacon, JR & Rhodes, MJC (1997) Effect of storage and domestic processing on the content and composition of flavonol glucosides in Onion (Allium cepa). J Agric Food Chem 45, 938942.Google Scholar
13. Hertog, MGL, Feskens, EJM, Hollman, PCH et al. (1993) Dietary antioxidant flavonoids and risk of coronary heart-disease – the zutphen elderly study. Lancet 342, 10071011.CrossRefGoogle ScholarPubMed
14. Knekt, P, Kumpulainen, J, Jarvinen, R et al. (2002) Flavonoid intake and risk of chronic diseases. Am J Clinical Nutr 76, 560568.Google Scholar
15. Pietta, P-G (2000) Flavonoids as antioxidants. J Nat Products 63, 10351042.CrossRefGoogle ScholarPubMed
16. Fiol, M, Adermann, S, Neugart, S et al. (2012) Highly glycosylated and acylated flavonols isolated from kale (Brassica oleracea var. sabellica) – structure–antioxidant activity relationship. Food Res Int 47, 8089.Google Scholar
17. Balasuriya, N & Rupasinghe, HPV (2012) Antihypertensive properties of flavonoid-rich apple peel extract. Food Chem 135, 23202325.Google Scholar
18. Hsu, CL & Yen, GC (2008) Phenolic compounds: evidence for inhibitory effects against obesity and their underlying molecular signaling mechanisms. Mol Nutr Food Res 52, 5361.Google Scholar
19. Kamiloglu, S, Grootaert, C, Capanoglu, E et al. (2016) Anti-inflammatory potential of black carrot (Daucus carota L.) polyphenols in a co-culture model of intestinal Caco-2 and endothelial EA.hy926 cells. Mol Nutr Food Res (In the Press).Google Scholar
20. Middleton, E, Kandaswami, C & Theoharides, TC (2000) The effects of plant flavonoids on mammalian cells: implications for inflammation, heart disease, and cancer. Pharmacol Rev 52, 673751.Google ScholarPubMed
21. Manach, C, Scalbert, A, Morand, C et al. (2004) Polyphenols: food sources and bioavailability. Am J Clinical Nutr 79, 727747.Google Scholar
22. D'Archivio, M, Filesi, C, Vari, R et al. (2010) Bioavailability of the polyphenols: status and controversies. Int J Mol Sci 11, 13211342.Google Scholar
23. Manach, C, Williamson, G, Morand, C et al. (2005) Bioavailability and bioefficacy of polyphenols in humans. I. Review of 97 bioavailability studies. Am J Clinical Nutr 81, 230S242S.CrossRefGoogle ScholarPubMed
24. Németh, K, Plumb, GW, Berrin, J-G et al. (2003) Deglycosylation by small intestinal epithelial cell β-glucosidases is a critical step in the absorption and metabolism of dietary flavonoid glycosides in humans. Eur J Nutr 42, 2942.Google Scholar
25. Crozier, A, Del Rio, D & Clifford, MN (2010) Bioavailability of dietary flavonoids and phenolic compounds. Mol Aspects Med 31, 446467.CrossRefGoogle ScholarPubMed
26. Liu, Y & Hu, M (2002) Absorption and metabolism of flavonoids in the Caco-2 cell culture model and a perfused rat intestinal model. Drug Metab Dispos 30, 370377.Google Scholar
27. Kroon, PA, Clifford, MN, Crozier, A et al. (2004) How should we assess the effects of exposure to dietary polyphenols in vitro? Am J Clin Nutr 80, 1521.Google Scholar
28. Day, AJ, Canada, FJ, Diaz, JC et al. (2000) Dietary flavonoid and isoflavone glycosides are hydrolysed by the lactase site of lactase phlorizin hydrolase. Febs Lett 468, 166170.Google Scholar
29. Nemeth, K, Plumb, GW, Berrin, JG et al. (2003) Deglycosylation by small intestinal epithelial cell beta-glucosidases is a critical step in the absorption and metabolism of dietary flavonoid glycosides in humans. Eur J Nutr 42, 2942.Google Scholar
30. Chang, HK, Shin, MS, Yang, HY et al. (2006) Amygdalin induces apoptosis through regulation of Bax and Bcl-2 expressions in human DU145 and LNCaP prostate cancer cells. Biol Pharm Bull 29, 15971602.Google Scholar
31. Williamson, G (2002) The use of flavonoid aglycones in in vitro systems to test biological activities: based on bioavailability data, is this a valid approach? Phytochem Rev 1, 215222.Google Scholar
32. Walle, T (2004) Absorption and metabolism of flavonoids. Free Radical Biol Med 36, 829837.Google Scholar
33. Mahraoui, L, Rousset, M, Dussaulx, E et al. (1992) Expression and localization of Glut-5 in Caco-2 cells, human small-intestine, and colon. Am J Physiol 263, G312G318.Google Scholar
34. Polli, JE & Ginski, MJ (1998) Human drug absorption kinetics and comparison to Caco-2 monolayer permeabilities. Pharm Res 15, 4752.CrossRefGoogle ScholarPubMed
35. Lowenthal, DT & Affrime, MB (1980) Pharmacology and pharmacokinetics of minoxidil. J Cardiovas Pharmacol 2, Suppl. 2, S93S106.Google Scholar
36. Lennernäs, H, Palm, K, Fagerholm, U et al. (1996) Comparison between active and passive drug transport in human intestinal epithelial (caco-2) cells in vitro and human jejunum in vivo . Int J Pharm 127, 103107.Google Scholar
37. Gonzales, GB, Smagghe, G, Mackie, A et al. (2015) Use of metabolomics and fluorescence recovery after photobleaching to study the bioavailability and intestinal mucus diffusion of polyphenols from cauliflower waste. J Funct Foods 16, 403413.Google Scholar
38. DuPont, MS, Day, AJ, Bennett, RN et al. (2004) Absorption of kaempferol from endive, a source of kaempferol-3-glucuronide, in humans. Eur J Clin Nutr 58, 947954.Google Scholar
39. Dai, J-Y, Yang, J-L & Li, C (2008) Transport and metabolism of flavonoids from Chinese herbal remedy Xiaochaihu-tang across human intestinal Caco-2 cell monolayers. Acta Pharmacol Sin 29, 10861093.Google Scholar
40. Walgren, RA, Walle, UK & Walle, T (1998) Transport of quercetin and its glucosides across human intestinal epithelial caco-2 cells. Biochem Pharm 55, 17211727.CrossRefGoogle ScholarPubMed
41. Boyer, J, Brown, D & Liu, RH (2004) Uptake of quercetin and quercetin 3-glucoside from whole onion and apple peel extracts by caco-2 cell monolayers. J Agri Food Chem 52, 71727179.Google Scholar
42. Murota, K, Shimizu, S, Chujo, H et al. (2000) Efficiency of absorption and metabolic conversion of quercetin and its glucosides in human intestinal cell line Caco-2. Arch Biochem Biophys 384, 391397.Google Scholar
43. Jin, X, Yi, L, Chen, M-L et al. (2013) Delphinidin-3-glucoside protects against oxidized low-density lipoprotein-induced mitochondrial dysfunction in vascular endothelial cells via the sodium-dependent glucose transporter SGLT1. PLoS ONE 8, e68617.CrossRefGoogle ScholarPubMed
44. Walgren, RA, Lin, JT, Kinne, RKH et al. (2000) Cellular uptake of dietary flavonoid quercetin 4 ‘-beta-glucoside by sodium-dependent glucose transporter SGLT1. J Pharmacol Exp Ther 294, 837843.Google ScholarPubMed
45. Kottra, G & Daniel, H (2007) Flavonoid glycosides are not transported by the human Na+/glucose transporter when expressed in Xenopus laevis oocytes, but effectively inhibit electrogenic glucose uptake. J Pharm Exp Therap 322, 829835.Google Scholar
46. Boyer, J, Brown, D & Liu, RH (2005) In vitro digestion and lactase treatment influence uptake of quercetin and quercetin glucoside by the Caco-2 cell monolayer. Nutr J 4, 1.Google Scholar
47. Al Shukor, N, Van Camp, J, Gonzales, GB et al. (2013) Angiotensin-converting enzyme inhibitory effects by plant phenolic compounds: a study of structure activity relationships. J Agric Food Chem 61, 1183211839.Google Scholar
48. Perez-Vizcaino, F, Duarte, J & Santos-Buelga, C (2012) The flavonoid paradox: conjugation and deconjugation as key steps for the biological activity of flavonoids. J Sci Food Agric 92, 18221825.Google Scholar
49. Gonzales, GB, Smagghe, G, Vissenaekens, H et al. (2016) Quercetin mitigates valinomycin-induced cellular stress via stress-induced metabolism and cell uptake. Mol Nutr Food Res 60, 972980.Google Scholar
50. Larson, A, Witman, MAH, Guo, Y et al. (2012) Acute, quercetin-induced reductions in blood pressure in hypertensive individuals are not secondary to lower plasma angiotensin-converting enzyme activity or endothelin-1: nitric oxide. Nutr Res 32, 557564.Google Scholar
51. Luzak, B, Golanski, J, Przygodzki, T et al. (2016) Extract from spent hop (Humulus lupulus L.) reduces blood platelet aggregation and improves anticoagulant activity of human endothelial cells in vitro . J Func Foods 22, 257269.Google Scholar
52. Lee, JS, Shukla, S, Kim, J-A et al. (2015) Anti-angiogenic effect of nelumbo nucifera leaf extracts in human umbilical vein endothelial cells with antioxidant potential. PLoS ONE 10, e0118552.CrossRefGoogle ScholarPubMed
53. Xia, N, Pautz, A, Wollscheid, U et al. (2014) Artichoke, cynarin and cyanidin downregulate the expression of inducible nitric oxide synthase in human coronary smooth muscle cells. Molecules 19, 36543668.Google Scholar
54. Chen, S, Wu, B-H, Fang, J-B et al. (2012) Analysis of flavonoids from lotus (Nelumbo nucifera) leaves using high performance liquid chromatography/photodiode array detector tandem electrospray ionization mass spectrometry and an extraction method optimized by orthogonal design. J Chromatogr A 1227, 145153.CrossRefGoogle Scholar
55. Negro, D, Montesano, V, Grieco, S et al. (2012) Polyphenol compounds in artichoke plant tissues and varieties. J Food Sci 77, C244C252.Google Scholar
56. Kuntz, S & Kunz, C (2014) Extracts from Brassica oleracea L. convar. acephala var. sabellica inhibit TNF-alpha stimulated neutrophil adhesion in vitro under flow conditions. Food Func 5, 10821090.CrossRefGoogle ScholarPubMed
57. Olsen, H, Aaby, K & Borge, GIA (2009) Characterization and quantification of flavonoids and hydroxycinnamic acids in Curly Kale (Brassica oleracea L. Convar. acephala Var. sabellica) by HPLC-DAD-ESI-MSn. J Agric Food Chem 57, 28162825.Google Scholar
58. Han, R, Wu, W-Q, Wu, X-P et al. (2015) Effect of total flavonoids from the seeds of Astragali complanati on natural killer cell function. J Ethnopharmacol 173, 157165.Google Scholar
59. Hollman, PCH (2004) Absorption, bioavailability, and metabolism of flavonoids. Pharm Biol 42, 7483.Google Scholar
60. Pistollato, F, Giampieri, F & Battino, M (2015) The use of plant-derived bioactive compounds to target cancer stem cells and modulate tumor microenvironment. Food Chem Toxicol 75, 5870.Google Scholar
61. Somoza, V, Molyneux, RJ, Chen, Z-Y et al. (2015) Guidelines for research on bioactive constituents – a journal of agricultural and food chemistry perspective. J Agric Food Chem 63, 81038105.Google Scholar
62. Balentine, DA, Dwyer, JT, Erdman, JW et al. (2015) Recommendations on reporting requirements for flavonoids in research. Am J Clin Nutr 101, 11131125.Google Scholar
Figure 0

Fig. 1. Basic structure of the common classes of flavonoids and the common points of glycosylation. Common glycosylation points are C3 and C7 (black arrows). B ring glycosylation is also observed in some plants (hollow arrow). C-glycosides are least found in plants (arrow with dotted lines).