Polyphenols (/ˌpɒliˈfnl, -nɒl/) are a large family of naturally occurring organic compounds characterized by multiples of phenol units.[1] They are abundant in plants and structurally diverse.[1][2][3] Polyphenols include flavonoids, tannic acid, and ellagitannin, some of which have been used historically as dyes and for tanning garments.

Curcumin, a bright yellow component of turmeric (Curcuma longa) is a well-studied polyphenol.

Plant-derived polyphenol, tannic acid, formed by esterification of ten equivalents of the phenylpropanoid-derived gallic acid to a monosaccharide (glucose) core from primary metabolism


The name derives from the Ancient Greek word πολύς (polus, meaning "many, much") and the word ‘phenol’ which refers to a chemical structure formed by attaching to an aromatic benzenoid (phenyl) ring to a hydroxyl (-OH) group as is found in alcohols (hence the -ol suffix). The term "polyphenol" has been in use at least since 1894.[4]


Ellagic acid, a polyphenol.
Raspberry ellagitannin, a tannin composed of 14 gallic acid units around a core of three units of glucose, with two gallic acids as simple esters, and the remaining 12 appearing in 6 ellagic acid-type units. Ester, ether, and biaryl linkages are present, see below.

The term polyphenol is not well-defined, but is generally agreed that they are natural products "having a polyphenol structure (i.e., several hydroxyl groups on aromatic rings)" including four principal classes: "phenolic acids, flavonoids, stilbenes, and lignans".[5]

WBSSH definition

The White–Bate-Smith–Swain–Haslam (WBSSH) definition[6] characterized structural characteristics common to plant phenolics used in tanning (i.e., the tannins).[7]

In terms of properties, the WBSSH describes the polyphenols thusly:

  • generally moderately water-soluble compounds
  • with molecular weight of 500–4000 Da
  • with >12 phenolic hydroxyl groups
  • with 5–7 aromatic rings per 1000 Da

In terms of structures, the WBSSH recognizes two structural family that have these properties:

Quideau definition

According to Stéphane Quideau, the term "polyphenol" refers to compounds derived from the shikimate/phenylpropanoid and/or the polyketide pathway, featuring more than one phenolic unit and deprived of nitrogen-based functions.

Ellagic acid, a molecule at the core of naturally occurring phenolic compounds of varying sizes, is itself not a polyphenol by the WBSSH definition, but is by the Quideau definition. The raspberry ellagitannin,[8] on the other hand, with its 14 gallic acid moieties (most in ellagic acid-type components), and more than 40 phenolic hydroxyl groups, meets the criteria of both definitions of a polyphenol. Other examples of compounds that fall under both the WBSSH and Quideau definitions include the black tea theaflavin-3-gallate shown below, and the hydrolyzable tannin, tannic acid.

Theaflavin-3-gallate, a plant-derived polyphenol, an ester of gallic acid and a theaflavin core. There are 9 phenolic hydroxyl groups and two phenolic ether linkages.


Polyphenols are reactive species toward oxidation, hence their description as antioxidants in vitro.[9]

Structural chemistry

Polyphenols are often larger molecules (macromolecules). Their upper molecular weight limit is about 800 daltons, which allows for the possibility to rapidly diffuse across cell membranes so that they can reach intracellular sites of action or remain as pigments once the cell senesces. Hence, many larger polyphenols are biosynthesized in-situ from smaller polyphenols to non-hydrolyzable tannins and remain undiscovered in the plant matrix. Most polyphenols contain repeating phenolic moieties of pyrocatechol, resorcinol, pyrogallol, and phloroglucinol connected by esters (hydrolyzable tannins) or more stable C-C bonds (nonhydrolyzable condensed tannins). Proanthocyanidins are mostly polymeric units of catechin and epicatechin.

The C-glucoside substructure of polyphenols is exemplified by the phenol-saccharide conjugate puerarin, a midmolecular-weight plant natural product. The attachment of the phenol to the saccharide is by a carbon-carbon bond. The isoflavone and its 10-atom benzopyran "fused ring" system, also a structural feature here, is common in polyphenols.

Polyphenols often have functional groups beyond hydroxyl groups. Ether ester linkages are common, as are carboxylic acids.

An example of a synthetically achieved small ellagitannin, tellimagrandin II, derived biosynthetically and sometimes synthetically by oxidative joining of two of the galloyl moieties of 1,2,3,4,6-pentagalloyl-glucose

Analytical chemistry

The analysis techniques are those of phytochemistry: extraction, isolation, structural elucidation,[10] then quantification.


Extraction of polyphenols[11] can be performed using a solvent like water, hot water, methanol, methanol/formic acid, methanol/water/acetic or formic acid. Liquid–liquid extraction can be also performed or countercurrent chromatography. Solid phase extraction can also be made on C18 sorbent cartridges. Other techniques are ultrasonic extraction, heat reflux extraction, microwave-assisted extraction,[12] critical carbon dioxide,[13][14] high-pressure liquid extraction[15] or use of ethanol in an immersion extractor.[16] The extraction conditions (temperature, extraction time, ratio of solvent to raw material, particle size of the sample, solvent type, and solvent concentrations) for different raw materials and extraction methods have to be optimized.[17] [18]

Mainly found in the fruit skins and seeds, high levels of polyphenols may reflect only the measured extractable polyphenol (EPP) content of a fruit which may also contain non-extractable polyphenols. Black tea contains high amounts of polyphenol and makes up for 20% of its weight.[19]

Concentration can be made by ultrafiltration.[20] Purification can be achieved by preparative chromatography.

Analysis techniques

Reversed-phase HPLC plot of separation of phenolic compounds. Smaller natural phenols formed individual peaks while tannins form a hump.

Phosphomolybdic acid is used as a reagent for staining phenolics in thin layer chromatography. Polyphenols can be studied by spectroscopy, especially in the ultraviolet domain, by fractionation or paper chromatography. They can also be analysed by chemical characterisation.

Instrumental chemistry analyses include separation by high performance liquid chromatography (HPLC), and especially by reversed-phase liquid chromatography (RPLC), can be coupled to mass spectrometry.[13] Purified compounds can be identified by the means of nuclear magnetic resonance.

Microscopy analysis

The DMACA reagent is an histological dye specific to polyphenols used in microscopy analyses. The autofluorescence of polyphenols can also be used, especially for localisation of lignin and suberin. Where fluorescence of the molecules themselves is insufficient for visualization by light microscopy, DPBA (diphenylboric acid 2-aminoethyl ester, also referred to as Naturstoff reagent A) has traditionally been used, at least in plant science, to enhance the fluorescence signal.[21]


Polyphenolic content in vitro can be quantified by volumetric titration. An oxidizing agent, permanganate, is used to oxidize known concentrations of a standard tannin solution, producing a standard curve. The tannin content of the unknown is then expressed as equivalents of the appropriate hydrolyzable or condensed tannin.[22]

Some methods for quantification of total polyphenol content in vitro are based on colorimetric measurements. Some tests are relatively specific to polyphenols (for instance the Porter's assay). Total phenols (or antioxidant effect) can be measured using the Folin-Ciocalteu reaction.[13] Results are typically expressed as gallic acid equivalents. Polyphenols are seldom evaluated by antibody technologies.[23]

Other tests measure the antioxidant capacity of a fraction. Some make use of the ABTS radical cation which is reactive towards most antioxidants including phenolics, thiols and vitamin C.[24] During this reaction, the blue ABTS radical cation is converted back to its colorless neutral form. The reaction may be monitored spectrophotometrically. This assay is often referred to as the Trolox equivalent antioxidant capacity (TEAC) assay. The reactivity of the various antioxidants tested are compared to that of Trolox, which is a vitamin E analog.

Other antioxidant capacity assays which use Trolox as a standard include the diphenylpicrylhydrazyl (DPPH), oxygen radical absorbance capacity (ORAC),[25] ferric reducing ability of plasma (FRAP)[26] assays or inhibition of copper-catalyzed in vitro human low-density lipoprotein oxidation.[27]

New methods including the use of biosensors can help monitor the content of polyphenols in food.[28]

Quantitation results produced by the mean of diode array detector–coupled HPLC are generally given as relative rather than absolute values as there is a lack of commercially available standards for all polyphenolic molecules.

Industrial applications

Some polyphenols are traditionally used as dyes. For instance, in the Indian subcontinent, the pomegranate peel, high in tannins and other polyphenols, or its juice, is employed in the dyeing of non-synthetic fabrics.[29]

Polyphenols, especially tannins, were used traditionally for tanning leather and today also as precursors in green chemistry[30] notably to produce plastics or resins by polymerisation with[31] or without the use of formaldehyde[32] or adhesives for particleboards.[33] The aims are generally to make use of plant residues from grape, olive (called pomaces) or pecan shells left after processing.[13]

Pyrogallol and pyrocatechin are among the oldest photographic developers.[34][35]


Polyphenols are thought to play diverse roles in the ecology of plants. These functions include:[36]

  • Release and suppression of growth hormones such as auxin.
  • UV screens to protect against ionizing radiation and to provide coloration (plant pigments).[5]
  • Deterrence of herbivores (sensory properties).
  • Prevention of microbial infections (phytoalexins).[5][37]
  • Signaling molecules in ripening and other growth processes.

Occurrence in nature

The most abundant polyphenols are the condensed tannins, found in virtually all families of plants. Larger polyphenols are often concentrated in leaf tissue, the epidermis, bark layers, flowers and fruits but also play important roles in the decomposition of forest litter, and nutrient cycles in forest ecology. Absolute concentrations of total phenols in plant tissues differ widely depending on the literature source, type of polyphenols and assay; they are in the range of 1–25% total natural phenols and polyphenols, calculated with reference to the dry green leaf mass.[38]

High levels of polyphenols in some woods can explain their natural preservation against rot.[39]

Flax and Myriophyllum spicatum (a submerged aquatic plant) secrete polyphenols that are involved in allelopathic interactions.[40][41]

Polyphenols are also found in animals. In arthropods, such as insects,[42] and crustaceans[43] polyphenols play a role in epicuticle hardening (sclerotization). The hardening of the cuticle is due to the presence of a polyphenol oxidase.[44] In crustaceans, there is a second oxidase activity leading to cuticle pigmentation.[45] There is apparently no polyphenol tanning occurring in arachnids cuticle.[46]

Biosynthesis and metabolism

Polyphenols incorporate smaller parts and building blocks from simpler natural phenols, which originate from the phenylpropanoid pathway for the phenolic acids or the shikimic acid pathway for gallotannins and analogs. Flavonoids and caffeic acid derivatives are biosynthesized from phenylalanine and malonyl-CoA. Complex gallotannins develop through the in-vitro oxidation of 1,2,3,4,6-pentagalloylglucose or dimerization processes resulting in hydrolyzable tannins. For anthocyanidins, precursors of the condensed tannin biosynthesis, dihydroflavonol reductase and leucoanthocyanidin reductase (LAR) are crucial enzymes with subsequent addition of catechin and epicatechin moieties for larger, non-hydrolyzable tannins.[47]

The glycosylated form develops from glucosyltransferase activity and increases the solubility of polyphenols.[48]

Polyphenol oxidase (PPO) is an enzyme that catalyses the oxidation of o-diphenols to produce o-quinones. It is the rapid polymerisation of o-quinones to produce black, brown or red polyphenolic pigments that causes fruit browning. In insects, PPO is involved in cuticle hardening.[49]

Occurrence in food

Polyphenols comprise up to 0.2–0.3% fresh weight for many fruits. Consuming common servings of wine, chocolate, legumes or tea may also contribute to about one gram of intake per day.[2][50] According to a 2005 review on polyphenols:

The most important food sources are commodities widely consumed in large quantities such as fruit and vegetables, green tea, black tea, red wine, coffee, chocolate, olives, and extra virgin olive oil. Herbs and spices, nuts and algae are also potentially significant for supplying certain polyphenols. Some polyphenols are specific to particular food (flavanones in citrus fruit, isoflavones in soya, phloridzin in apples); whereas others, such as quercetin, are found in all plant products such as fruit, vegetables, cereals, leguminous plants, tea, and wine.[51]

Some polyphenols are considered antinutrients – compounds that interfere with the absorption of essential nutrients – especially iron and other metal ions, which may bind to digestive enzymes and other proteins, particularly in ruminants.[52]

In a comparison of cooking methods, phenolic and carotenoid levels in vegetables were retained better by steaming compared to frying.[53] Polyphenols in wine, beer and various nonalcoholic juice beverages can be removed using finings, substances that are usually added at or near the completion of the processing of brewing.


With respect to food and beverages, the cause of astringency is not fully understood, but it is measured chemically as the ability of a substance to precipitate proteins.[54]

A review published in 2005 found that astringency increases and bitterness decreases with the mean degree of polymerization. For water-soluble polyphenols, molecular weights between 500 and 3000 were reported to be required for protein precipitation. However, smaller molecules might still have astringent qualities likely due to the formation of unprecipitated complexes with proteins or cross-linking of proteins with simple phenols that have 1,2-dihydroxy or 1,2,3-trihydroxy groups.[55] Flavonoid configurations can also cause significant differences in sensory properties, e.g. epicatechin is more bitter and astringent than its chiral isomer catechin. In contrast, hydroxycinnamic acids do not have astringent qualities, but are bitter.[56]


Polyphenols are a large, diverse group of compounds, making it difficult to determine their biological effects.[57] They are not considered nutrients, as they are not used for growth, survival or reproduction, nor do they provide dietary energy. Therefore, they do not have recommended daily intake levels, as exist for vitamins, minerals, and fiber.[58][59][60] In the United States, the Food and Drug Administration issued guidance to manufacturers that polyphenols cannot be mentioned on food labels as antioxidant nutrients unless physiological evidence exists to verify such a qualification and a Dietary Reference Intake value has been established, characteristics which have not been determined for polyphenols.[61][62] In the European Union, two health claims were authorized between 2012 and 2015: 1) flavanols in cocoa solids at doses exceeding 200 mg per day may contribute to maintenance of vascular elasticity and normal blood flow;[63][64] 2) olive oil polyphenols (5 mg of hydroxytyrosol and its derivatives (e.g. oleuropein complex and tyrosol) may "contribute to the protection of blood lipids from oxidative damage", if consumed daily.[65][66]

As of 2022, clinical trials that assessed the effect of polyphenols on health biomarkers are limited, with results difficult to interpret due to the wide variation of intake values for both individual polyphenols and total polyphenols.[67]

Polyphenols were once considered as antioxidants, but this concept is obsolete.[68] Most polyphenols are metabolized by catechol-O-methyltransferase, and therefore do not have the chemical structure allowing antioxidant activity in vivo; they may exert biological activity as signaling molecules.[2][69] Some polyphenols are considered to be bioactive compounds[70] for which development of dietary recommendations was under consideration in 2017.[71]

Cardiovascular diseases

In the 1930s, polyphenols were considered as a factor in capillary permeability (then called vitamin P), followed by various studies through the 21st century of a possible effect on cardiovascular diseases. For most polyphenols, there is no evidence for an effect on cardiovascular regulation, although there are some reviews showing a minor effect of consuming polyphenols, such as chlorogenic acid or flavan-3-ols, on blood pressure.[72][73][74]


As of 2019, there is little evidence that dietary flavonoids lower the risk of cancer.[2]

Cognitive function

Polyphenols are under preliminary research for possible cognitive effects in healthy adults.[75][76]


Isoflavones, which are structurally related to 17β-Estradiol, are classified as phytoestrogens.[77] There is little scientific evidence that consuming isoflavones has an effect on health or disease.[78] A risk assessment by the European Food Safety Authority found no cause for concern when isoflavones are consumed in a normal diet.[79]


Phlebotonics of heterogeneous composition, consisting partly of citrus peel extracts (flavonoids, such as hesperidin) and synthetic compounds, are used to treat chronic venous insufficiency and hemorrhoids.[80] Some are non-prescription dietary supplements, such as Diosmin,[80] while one other – Vasculera (Diosmiplex) – is a prescription medical food intended for treating venous disorders.[81] Their mechanism of action is undefined,[80] and clinical evidence of benefit for using phlebotonics to treat venous diseases is limited.[80]

Gut microbiome

Polyphenols are extensively metabolized by the gut microbiota and are investigated as a potential metabolic factor in function of the gut microbiota.[82][83]

Toxicity and adverse effects

Adverse effects of polyphenol intake range from mild (e.g., gastrointestinal tract symptoms)[2] to severe (e.g., hemolytic anemia or hepatotoxicity).[84] In 1988, hemolytic anemia following polyphenol consumption was documented, resulting in the withdrawal of a catechin-containing drug.[85]

Metabolism of polyphenols can result in flavonoid-drug interactions, such as in grapefruit–drug interactions, which involves inhibition of the liver enzyme, CYP3A4, likely by grapefruit furanocoumarins, a class of polyphenol.[2][84] The European Food Safety Authority established upper limits for some polyphenol-containing supplements and additives, such as green tea extract or curcumin.[86][87] For most polyphenols found in the diet, an adverse affect beyond nutrient-drug interactions is unlikely.[2]

See also


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