Flavones

Molecular structure of the flavone backbone with numbers

Flavones (flavus = yellow), are a class of flavonoids based on the backbone of 2-phenylchromen-4-one (2-phenyl-1-benzopyran-4-one) shown on the right.

Natural flavones include apigenin (4',5,7-trihydroxyflavone), luteolin (3',4',5,7-tetrahydroxyflavone), tangeritin (4',5,6,7,8-pentamethoxyflavone), chrysin (5,7-dihydroxyflavone), 6-hydroxyflavone, baicalein (5,6,7-trihydroxyflavone), scutellarein (5,6,7,4'-tetrahydroxyflavone), and wogonin (5,7-dihydroxy-8-methoxyflavone). Synthetic flavones include diosmin, flavoxate, and 7,8-dihydroxyflavone.

Flavone also refers to the flavone compound 2-phenyl-4H-chromen-4-one.^[1]^[2]

Intake and putative beneficial effects

Flavones are mainly found in cereals and herbs. In the West, the estimated daily intake of flavones is in the range 20–50 mg per day.^[3] In recent years, scientific and public interest in flavones has grown, but there remains insufficient evidence that flavones have any effect in the human body. As interpreted by the Linus Pauling Institute, dietary flavones, and more generally polyphenols, have little or no direct antioxidant food value following digestion.^[4] Not like controlled test tube conditions, the fate of flavones or polyphenols in vivo shows they are poorly conserved (less than 5%), with most of what is absorbed existing as metabolites modified during digestion and destined for rapid excretion.^[5]

Drug interactions

Flavones have effects on CYP (P450) activity ^[6]^[7] which are enzymes that metabolize most drugs in the body.

Organic chemistry

In organic chemistry several methods exist for the synthesis of flavones:

Another method is the dehydrative cyclization of certain 1,3-diaryl diketones ^[8]

this particular study making use of an ionic liquid solvent and microwave irradiation.

Wessely–Moser rearrangement

The Wessely–Moser rearrangement (1930)^[9] has been an important tool in structure elucidation of flavonoids. It involves the conversion of 5,7,8-trimethoxyflavone into 5,6,7-trihydroxyflavone on hydrolysis of the methoxy groups to phenol groups. It also has synthetic potential for example:^[10]

This rearrangement reaction takes place in several steps: A ring opening to the diketone, B bond rotation with formation of a favorable acetylacetone-like phenyl-ketone interaction and C hydrolysis of two methoxy groups and ring closure.

Examples of flavones

Flavones and their structure ^[11]
Name	Structure	R³	R⁵	R⁶	R⁷	R⁸	R^2'	R^3'	R^4'	R^5'	R^6'
Flavone		–	–	–	–	–	–	–	–	–	–
Primuletin		–	–OH	–	–	–	–	–	–	–	–
Chrysin		–	–OH	–	–OH	–	–	–	–	–	–
Tectochrysin		–	–OH	–	–OCH₃	–	–	–	–	–	–
Primetin		–	–OH	–	–	–OH	–	–	–	–	–
Apigenin		–	–OH	–	–OH	–	–	–	–OH	–	–
Acacetin		–	–OH	–	–OH	–	–	–	–OCH₃	–	–
Genkwanin		–	–OH	–	–OCH₃	–	–	–	–OH	–	–
Echioidinin		–	–OH	–	–OCH₃	–	–OH	–	–	–	–
Baicalein		–	–OH	–OH	–OH	–	–	–	–	–	–
Oroxylon		–	–OH	–OCH₃	–OH	–	–	–	–	–	–
Negletein		–	–OH	–OH	–OCH₃	–	–	–	–	–	–
Norwogonin		–	–OH	–	–OH	–OH	–	–	–	–	–
Wogonin		–	–OH	–	–OH	–OCH₃	–	–	–	–	–
Geraldone		–	–	–	–OH	–	–	–OCH₃	–OH	–	–
Tithonine		–	–	–	–OCH₃	–	–	–OH	–OCH₃	–	–
Luteolin		–	–OH	–	–OH	–	–	–OH	–OH	–	–
Chrysoeriol		–	–OH	–	–OH	–	–	–OCH₃	–OH	–	–
Diosmetin		–	–OH	–	–OH	–	–	–OH	–OCH₃	–	–
Pilloin		–	–OH	–	–OCH₃	–	–	–OH	–OCH₃	–	–
Velutin		–	–OH	–	–OCH₃	–	–	–OCH₃	–OH	–	–
Norartocarpetin		–	–OH	–	–OH	–	–OH	–	–OH	–	–
Artocarpetin		–	–OH	–	–OCH₃	–	–OH	–	–OH	–	–
Scutellarein		–	–OH	–OH	–OH	–	–	–	–OH	–	–
Hispidulin		–	–OH	–OCH₃	–OH	–	–	–	–OH	–	–
Sorbifolin		–	–OH	–OH	–OCH₃	–	–	–	–OH	–	–
Pectolinarigenin		–	–OH	–OCH₃	–OH	–	–	–	–OCH₃	–	–
Cirsimaritin		–	–OH	–OCH₃	–OCH₃	–	–	–	–OH	–	–
Mikanin		–	–OH	–OCH₃	–OCH₃	–	–	–	–OCH₃	–	–
Isoscutellarein		–	–OH	–	–OH	–OH	–	–	–OH	–	–
Zapotinin		–	–OH	–OCH₃	–	–	–OCH₃	–	–	–	–OCH₃
Zapotin		–	–OCH₃	–OCH₃	–	–	–OCH₃	–	–	–	–OCH₃
Cerrosillin		–	–OCH₃	–OCH₃	–	–	–	–OCH₃	–	–OCH₃	–
Alnetin		–	–OH	–OCH₃	–OCH₃	–OCH₃	–	–	–	–	–
Tricetin		–	–OH	–	–OH	–	–	–OH	–OH	–OH	–
Tricin		–	–OH	–	–OH	–	–	–OCH₃	–OH	–OCH₃	–
Corymbosin		–	–OH	–	–OCH₃	–	–	–OCH₃	–OCH₃	–OCH₃	–
Nepetin		–	–OH	–OCH₃	–OH	–	–	–OH	–OH	–	–
Pedalitin		–	–OH	–OH	–OCH₃	–	–	–OH	–OH	–	–
Nodifloretin		–	–OH	–OH	–OH	–	–	–OCH₃	–OH	–	–
Jaceosidin		–	–OH	–OCH₃	–OH	–	–	–OCH₃	–OH	–	–
Cirsiliol		–	–OH	–OCH₃	–OCH₃	–	–	–OH	–OH	–	–
Eupatilin		–	–OH	–OCH₃	–OH	–	–	–OCH₃	–OCH₃	–	–
Cirsilineol		–	–OH	–OCH₃	–OCH₃	–	–	–OCH₃	–OH	–	–
Eupatorin		–	–OH	–OCH₃	–OCH₃	–	–	–	–OCH₃	–OH	–
Sinensetin		–	–OCH₃	–OCH₃	–OCH₃	–	–	–	–OCH₃	–OCH₃	–
Hypolaetin		–	–OH	–	–OH	–OH	–	–OH	–OH	–	–
Onopordin		–	–OH	–	–OH	–OCH₃	–	–OH	–OH	–	–
Wightin		–	–OH	–	–OCH₃	–OCH₃	–OCH₃	–OH	–	–	–
Nevadensin		–	–OH	–OCH₃	–OH	–OCH₃	–	–	–OCH₃	–	–
Xanthomicrol		–	–OH	–OCH₃	–OCH₃	–OCH₃	–	–	–OH	–	–
Tangeretin		–	–OCH₃	–OCH₃	–OCH₃	–OCH₃	–	–	–OCH₃	–	–
Serpyllin		–	–OH	–	–OCH₃	–OCH₃	–OCH₃	–OCH₃	–OCH₃	–	–
Sudachitin		–	–OH	–OCH₃	–OH	–OCH₃	–	–OCH₃	–OH	–	–
Acerosin		–	–OH	–OCH₃	–OH	–OCH₃	–	–OH	–OCH₃	–	–
Hymenoxin		–	–OH	–OCH₃	–OH	–OCH₃	–	–OCH₃	–OCH₃	–	–
Gardenin D		–	–OH	–OCH₃	–OCH₃	–OCH₃	–	–OH	–OCH₃	–	–
Nobiletin		–	–OCH₃	–OCH₃	–OCH₃	–OCH₃	–	–OCH₃	–OCH₃	–	–
Scaposin		–	–OH	–OCH₃	–OH	–OCH₃	–	–OCH₃	–OCH₃	–OH	–
Name	Structure	R³	R⁵	R⁶	R⁷	R⁸	R^2'	R^3'	R^4'	R^5'	R^6'

References

↑ http://proj3.sinica.edu.tw/~chem/servxx6/files/paper_7744_1269418157.pdf
↑ http://www.chemspider.com/Chemical-Structure.10230.html
↑ Cermak R, Wolffram S (October 2006). "The potential of flavonoids to influence drug metabolism and pharmacokinetics by local gastrointestinal mechanisms". Curr. Drug Metab. 7 (7): 729–44. doi:10.2174/138920006778520570. PMID 17073577.
↑ Lotito, S; Frei, B (2006). "Consumption of flavonoid-rich foods and increased plasma antioxidant capacity in humans: Cause, consequence, or epiphenomenon?". Free Radical Biology and Medicine. 41 (12): 1727–46. doi:10.1016/j.freeradbiomed.2006.04.033. PMID 17157175.
↑ David Stauth (5 March 2007). "Studies force new view on biology of flavonoids". EurekAlert!; Adapted from a news release issued by Oregon State University.
↑ Cermak R, Wolffram S., The potential of flavonoids to influence drug metabolism and pharmacokinetics by local gastrointestinal mechanisms,Curr Drug Metab. 2006 Oct;7(7):729-44.
↑ Si D, Wang Y, Zhou YH, et al. (March 2009). "Mechanism of CYP2C9 inhibition by flavones and flavonols". Drug Metab. Dispos. 37 (3): 629–34. doi:10.1124/dmd.108.023416. PMID 19074529.
↑ Sarda SR, Pathan MY, Paike VV, Pachmase PR, Jadhav WN, Pawar RP (2006). "A facile synthesis of flavones using recyclable ionic liquid under microwave irradiation" (PDF). Arkivoc. xvi: 43–8. doi:10.3998/ark.5550190.0007.g05.
↑ Wessely F, Moser GH (December 1930). "Synthese und Konstitution des Skutellareins". Monatsh. Chem. 56 (1): 97–105. doi:10.1007/BF02716040.
↑ Larget R, Lockhart B, Renard P, Largeron M (April 2000). "A convenient extension of the Wessely-Moser rearrangement for the synthesis of substituted alkylaminoflavones as neuroprotective agents in vitro". Bioorg. Med. Chem. Lett. 10 (8): 835–8. doi:10.1016/S0960-894X(00)00110-4. PMID 10782697.
↑ The Flavonoids - Springer. doi:10.1007/978-1-4899-2909-9.

External links

Flavones at the US National Library of Medicine Medical Subject Headings (MeSH)

Types of flavonoids

Flavonoids

Anthoxanthins

Flavones	Acacetin Apigenin Chrysin Diosmetin Tangeritin Luteolin

Flavonols	Quercetin Kaempferol Myricetin Fisetin Rutin Isorhamnetin

Flavanones

Flavans

Flavan-3-ols (flavanols)	Catechins Theaflavin Theaflavin-3-gallate Thearubigins Proanthocyanidins

Other flavans	flavan-4-ols Flavan-3,4-diols

Flavanonols

Anthocyanidins
(Anthocyanins aglycone)

Isoflavonoids

Neoflavonoids

Dalbergichromene

Aurones

Other categories

Flavonoid biosynthesis

Flavones and their conjugates

Aglycones

Monohydroxyflavone	6-Hydroxyflavone

Dihydroxyflavones	Chrysin 4',7-Dihydroxyflavone 7,8-Dihydroxyflavone

Trihydroxyflavones	Apigenin Baicalein Norwogonin

Tetrahydroxyflavones	Isoscutellarein Luteolin Norartocarpetin Scutellarein

Pentahydroxyflavones	6-Hydroxyluteolin Hypolaetin Tricetin

O-methylated flavones	Acacetin Alnetin Artocarpetin Chrysoeriol Cirsilineol Cirsiliol Cirsimaritin Diosmetin Eupatilin Genkwanin Hispidulin Nepetin Nobiletin Oroxylin A Pratol Salvigenin Sinensetin Tangeritin Techtochrysin Tricin Wogonin Zapotin

Glycosides

of apigenin	Apiin Apigetrin Isovitexin Rhoifolin Saponarin Schaftoside Vicenin-2 Vitexin

of baicalein	Baicalin Tetuin

of hypolaetin	Hypolaetin 8-glucoside Hypolaetin 8-glucuronide

of luteolin	Cynaroside Isoorientin Orientin Veronicastroside Luteolin-7-O-glucuronide

Giraldiin A and B
Nepitrin
Oroxindin
Scutellarin

Acetylated

Artocarpetin A
Artoindonesianin P

Sulfated glycosides

Theograndin I and II

Polymers

Amentoflavone

Drugs

Authority control	NDL: 00563681

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