Flavan-3-ol

Flavan-3-ols (sometimes referred to as flavanols) are derivatives of flavans that possess a 2-phenyl-3,4-dihydro-2H-chromen-3-ol skeleton. These compounds include catechin, epicatechin gallate, epigallocatechin, epigallocatechin gallate, proanthocyanidins, theaflavins, thearubigins.

Chemical structure of flavan-3-ol
Epicatechin (EC)
Epigallocatechin (EGC)

Flavanols (with an "a") are not to be confused with flavonols (with an "o"), a class of flavonoids containing a ketone group.

The single-molecule (monomer) catechin, or isomer epicatechin (see diagram), adds four hydroxyls to flavan-3-ol, making building blocks for concatenated polymers (proanthocyanidins) and higher order polymers (anthocyanidins).[1]

Flavanols possess two chiral carbons, meaning four diastereoisomers occur for each of them.

Catechins are distinguished from the yellow, ketone-containing flavonoids such as quercitin and rutin, which are called flavonols. Early use of the term bioflavonoid was imprecisely applied to include the flavanols, which are distinguished by absence of ketone(s). Catechin monomers, dimers, and trimers (oligomers) are colorless. Higher order polymers, anthocyanidins, exhibit deepening reds and become tannins.[1]

Sources of catechins

The catechins are abundant in teas derived from the tea plant Camellia sinensis, as well as in some cocoas and chocolates[2] (made from the seeds of Theobroma cacao). Catechins are also present in the human diet in fruits, vegetables and wine,[3] and are found in many other plant species.[4][5]

Catechin and the gallates

Catechin and epicatechin are epimers, with (-)-epicatechin and (+)-catechin being the most common optical isomers found in nature. Catechin was first isolated from the plant extract catechu, from which it derives its name. Heating catechin past its point of decomposition releases pyrocatechol (also called catechol), which explains the common origin of the names of these compounds.

Epigallocatechin and gallocatechin contain an additional phenolic hydroxyl group when compared to epicatechin and catechin, respectively, similar to the difference in pyrogallol compared to pyrocatechol.

Catechin gallates are gallic acid esters of the catechins; an example is epigallocatechin gallate, which is commonly the most abundant catechin in tea.

Metabolism of flavan-3-ols

Biosynthesis of (-)-epicatechin

The flavonoids are products from a cinnamoyl-CoA starter unit, with chain extension using three molecules of malonyl-CoA. Reactions are catalyzed by a type III PKS enzyme. These enzyme do not use ACPSs, but instead employ coenzyme A esters and have a single active site to perform the necessary series of reactions, e.g. chain extension, condensation, and cyclization. Chain extension of 4-hydroxycinnamoyl-CoA with three molecules of malonyl-CoA gives initially a polyketide (Figure 1), which can be folded. These allow Claisen-like reactions to occur, generating aromatic rings.[6][7]

Figure 1

Figure 1:Schematic overview of the flavan-3-ol (-)-epicatechin biosynthesis in plants: Enzymes are indicated in blue, abbreviated as follows: E1, phenylalanine ammonia lyase (PAL), E2, tyrosine ammonia lyase (TAL), E3, cinnamate 4-hydroxylase, E4, 4-coumaroyl: CoA-ligase, E5, chalcone synthase (naringenin-chalcone synthase), E6, chalcone isomerase, E7, Flavonoid 3'-hydroxylase, E8, flavonone 3-hydroxylase, E9, dihydroflavanol 4-reductase, E10, anthocyanidin synthase (leucoanthocyanidin dioxygenase), E11, anthocyanidin reductase. HSCoA, Coenzyme A. L-Tyr, L-tyrosine, L-Phe, L-phenylalanine.

Metabolism in humans

Schematic representation of the flavan-3-ol (−)-epicatechin metabolism in humans as a function of time post-oral intake. SREM: structurally related (−)-epicatechin metabolites. 5C-RFM: 5-carbon ring fission metabolites. 3/1C-RFM: 3- and 1-carbon-side chain ring fission metabolites. The structures of the most abundant (−)-epicatechin metabolites present in the systemic circulation and in urine are depicted.[8]
Flavan-3-ol precursors of the microbial metabolite 5-(3′/4′-dihydroxyphenyl)-γ-valerolactone (gVL). Only compounds with intact (epi)catechin moiety result in the formation of γVL by the intestinal microbiome. ECG, (−)-epicatechin-3-O-gallate; EGCG, Epigallocatechin gallate; EGC, Epigallocatechin[9]

Most data for human metabolism of flavan-3-ols are available for monomeric compounds, especially Catechin. These compounds are taken up and metabolised upon uptake in the jejunum,[10] mainly by O-methylation and glucuronidation,[11] and then further metabolised by the liver. The colonic microbiome has also an important role in the metabolism of flavan-3-ols and they are catabolised to smaller compounds such as 5-(3′/4′-dihydroxyphenyl)-γ-valerolactones and hippuric acid.[12][8] Only flavan-3-ols with an intact (epi)catechin moiety can be metabolised 5-(3′/4′-dihydroxyphenyl)-γ-valerolactones.[9]

Potential health effects of catechins

The supposed health benefits of catechins have been studied extensively in humans and animal models, but there are no proven effects that apply to human health. Until 2013, neither the Food and Drug Administration nor the European Food Safety Authority had approved any health claim for catechins or approved any as pharmaceutical drugs.[13][14][15] Moreover, several companies have been cautioned by the FDA over misleading health claims.[16][17][18][19]

In 2014, the European Food Safety Authority approved the following health claim for cocoa products containing 200 mg of flavanols and meeting the qualification in dietary supplement products: "cocoa flavanols help maintain the elasticity of blood vessels, which contributes to normal blood flow".[20]

Possible reduced benefits

An editorial warned against increasing one's intake of dark chocolate to improve health because the beneficial compounds, suggested to be flavanols, are sometimes removed due to their bitter taste without an indication on the label.[21] Additionally, such a product is high in fat, sugar and Calories, contributing to a poor diet if consumed in large amounts.[21]

Aglycones

Flavan-3-ols
ImageNameFormulaOligomers
Catechin, C, (+)-CatechinC15H14O6Procyanidins
Epicatechin, EC, (-)-Epicatechin (cis)C15H14O6Procyanidins
Epigallocatechin, EGCC15H14O7Prodelphinidins
Epicatechin gallate, ECGC22H18O10
Epigallocatechin gallate, EGCG,
(-)-Epigallocatechin gallate
C22H18O11
EpiafzelechinC15H14O5
FisetinidolC15H14O5
GuibourtinidolC15H14O4Proguibourtinidins
MesquitolC15H14O6
RobinetinidolC15H14O6Prorobinetinidins

Analysis

Fluorescence-lifetime imaging microscopy (FLIM) can be used to detect flavanols in plant cells[22]

Other uses

Recent study tested catechins employed to coat nanoparticles of iron oxides in the blood. These particles allow visualization of vessels – and especially cancer tumors in mice – in an MRI exam. The nanoparticles would clump together without the catechin coating. [23]

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References

  1. OPC in Practice, 1995 3rd Edition, by Bert Schwitters in collaboration with Prof. Jack Masquelier.
  2. Hammerstone JF, Lazarus SA, Schmitz HH (August 2000). "Procyanidin content and variation in some commonly consumed foods". J. Nutr. 130 (8S Suppl): 2086S–92S. doi:10.1093/jn/130.8.2086S. PMID 10917927.
  3. Ruidavets J, Teissedre P, Ferrières J, Carando S, Bougard G, Cabanis J (November 2000). "Catechin in the Mediterranean diet: vegetable, fruit or wine?". Atherosclerosis. 153 (1): 107–17. doi:10.1016/S0021-9150(00)00377-4. PMID 11058705.
  4. BBC News | Health | Chocolate 'has health benefits'
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  7. Winkel-Shirley, Brenda.Flavonoid Biosynthesis. A Colorful Model for Genetics, Biochemistry, Cell Biology, and Biotechnology. Plant Physiol. Vol. 126, 2001, p. 485-493.
  8. Ottaviani, Javier I.; Borges, Gina; Momma, Tony Y.; Spencer, Jeremy P. E.; Keen, Carl L.; Crozier, Alan; Schroeter, Hagen (2016-07-01). "The metabolome of [2-14C](−)-epicatechin in humans: implications for the assessment of efficacy, safety and mechanisms of action of polyphenolic bioactives". Scientific Reports. 6 (1): 29034. doi:10.1038/srep29034. ISSN 2045-2322. PMC 4929566. PMID 27363516.
  9. Ottaviani, Javier I.; Fong, Redmond; Kimball, Jennifer; Ensunsa, Jodi L.; Britten, Abigail; Lucarelli, Debora; Luben, Robert; Grace, Philip B.; Mawson, Deborah H. (2018-06-29). "Evaluation at scale of microbiome-derived metabolites as biomarker of flavan-3-ol intake in epidemiological studies". Scientific Reports. 8 (1): 9859. doi:10.1038/s41598-018-28333-w. ISSN 2045-2322. PMC 6026136. PMID 29959422.
  10. Actis-Goretta, Lucas; Lévèques, Antoine; Rein, Maarit; Teml, Alexander; Schäfer, Christian; Hofmann, Ute; Li, Hequn; Schwab, Matthias; Eichelbaum, Michel (October 2013). "Intestinal absorption, metabolism, and excretion of (-)-epicatechin in healthy humans assessed by using an intestinal perfusion technique". The American Journal of Clinical Nutrition. 98 (4): 924–933. doi:10.3945/ajcn.113.065789. ISSN 1938-3207. PMID 23864538.
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  19. "Fruits Are Good for Your Health? Not So Fast: FDA Stops Companies From Making Health Claims About Foods". TheDailyGreen.com. Retrieved 31 October 2014.
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