Curcumin

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Curcumin

Enol form
Keto form
Ball-and-stick model
Ball-and-stick model
Names
IUPAC name (1E,6E)-1,7-Bis(4-hydroxy-3-methoxyphenyl)-1,6-heptadiene-3,5-dione
Other names Diferuloylmethane; curcumin I; C.I. 75300; Natural Yellow 3
Identifiers
CAS Number	458-37-7 Y
ChEBI	CHEBI:3962 Y
ChEMBL	ChEMBL116438 N
ChemSpider	839564 Y
IUPHAR/BPS	7000
Jmol 3D model	Interactive image
PubChem	969516
UNII	IT942ZTH98 Y
InChI InChI=1S/C21H20O6/c1-26-20-11-14(5-9-18(20)24)3-7-16(22)13-17(23)8-4-15-6-10-19(25)21(12-15)27-2/h3-12,24-25H,13H2,1-2H3/b7-3+,8-4+ Y Key: VFLDPWHFBUODDF-FCXRPNKRSA-N Y InChI=1/C21H20O6/c1-26-20-11-14(5-9-18(20)24)3-7-16(22)13-17(23)8-4-15-6-10-19(25)21(12-15)27-2/h3-12,24-25H,13H2,1-2H3/b7-3+,8-4+ Key: VFLDPWHFBUODDF-FCXRPNKRBF
SMILES O=C(\C=C\c1ccc(O)c(OC)c1)CC(=O)\C=C\c2cc(OC)c(O)cc2
Properties
Chemical formula	C21H20O6
Molar mass	368.39 g·mol−1
Appearance	Bright yellow-orange powder
Melting point	183 °C (361 °F; 456 K)
Vapor pressure	{{{value}}}
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
N verify (what is YN ?)
Infobox references

Curcumin (/ˈkərkjuːmən/) is a diarylheptanoid. It is the principal curcuminoid of turmeric, which is a member of the ginger family (Zingiberaceae). It was first discovered about two centuries ago when Vogel and Pelletier reported the isolation of a “yellow coloring-matter” from the rhizomes of Curcuma longa (turmeric) and named it curcumin.^[1] Turmeric's other two curcuminoids are desmethoxycurcumin and bis-desmethoxycurcumin. The curcuminoids are natural phenols that are responsible for the yellow color of turmeric. Curcumin can exist in several tautomeric forms, including a 1,3-diketo form and two equivalent enol forms. The enol form is more energetically stable in the solid phase and in organic solvents, while in water the 1,3-diketo dominates.^[2]

Curcumin can be used for boron quantification in the curcumin method. It reacts with boric acid to form a red-color compound, rosocyanine.

Curcumin is a bright-yellow color and may be used as a food coloring. As a food additive, its E number is E100.^[3]

Adverse effects

Clinical studies in humans with high doses (2–12 grams) of curcumin have shown few side-effects,^[4] with some subjects reporting mild nausea or diarrhea.^[5] More recently, curcumin was found to alter iron metabolism by chelating iron and suppressing the protein hepcidin, potentially causing iron deficiency in susceptible patients.^[6]

Chemistry

Curcumin incorporates several functional groups. The aromatic ring systems, which are phenols, are connected by two α,β-unsaturated carbonyl groups. The diketones form stable enols and are readily deprotonated to form enolates; the α,β-unsaturated carbonyl group is a good Michael acceptor and undergoes nucleophilic addition. The structure was first identified in 1910 by J. Miłobędzka, Stanisław Kostanecki and Wiktor Lampe.^[7]

Curcumin is used as an indicator for boron.^[8]

Biosynthesis

The biosynthetic route of curcumin has proven to be very difficult for researchers to determine. In 1973, Roughly and Whiting proposed two mechanisms for curcumin biosynthesis. The first mechanism involved a chain extension reaction by cinnamic acid and 5 malonyl-CoA molecules that eventually arylized into a curcuminoid. The second mechanism involved two cinnamate units coupled together by malonyl-CoA. Both mechanisms use cinnamic acid as their starting point, which is derived from the amino acid phenylalanine. This is noteworthy because plant biosyntheses employing cinnamic acid as a starting point are rare compared to the more common use of p-coumaric acid.^[9] Only a few identified compounds, such as anigorufone and pinosylvin, use cinnamic acid as their starting molecule.^[10][11] An experimentally backed route was not presented until 2008. This proposed biosynthetic route follows both the first and second mechanisms suggested by Roughley and Whiting. However, the labeling data supported the first mechanism model in which 5 malonyl-CoA molecules react with cinnamic acid to form curcumin. However, the sequencing in which the functional groups, the alcohol and the methoxy, introduce themselves onto the curcuminoid seems to support more strongly the second proposed mechanism.^[9] Therefore, it was concluded the second pathway proposed by Roughly and Whiting was correct.

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malonyl-CoA (5)

Biosynthetic pathway of curcumin in Curcuma longa.^[9]

Pharmacodynamics

In vitro, curcumin has been shown to inhibit certain epigenetic enzymes (the histone deacetylases: HDAC1, HDAC3, and HDAC8) and transcriptional co-activator proteins (the p300 histone acetyltransferase).^[12][13][14] Curcumin also inhibits the arachidonate 5-lipoxygenase enzyme in vitro,^[15] as well as the enzyme cyclooxygenase.^{[citation needed]}

Pharmacokinetics

In Phase I clinical trials, dietary curcumin was shown to exhibit poor bioavailability, exhibited by rapid metabolism, low levels in plasma and tissues, and extensive rapid excretion.^[16] Potential factors that limit the bioavailability of curcumin include insolubility in water (more soluble in alkaline solutions) and poor absorption.^[16] Numerous approaches to increase curcumin bioavailability have been explored, including the use of absorption factors (such as piperine), liposomes, nanoparticles or a structural analogue.^[16]

Research

A survey of the literature shows a number of potential effects under study and that daily consumption over a 3-month period of up to 12 grams were safe.^[17] However, several studies of curcumin efficacy and safety revealed poor absorption and low bioavailability.^[18]

References

External links

• Turmeric and curcumin, from Memorial Sloan-Kettering Cancer Center
• Turmeric and curcumin, from M.D. Anderson Cancer Center
• Turmeric, from the University of Maryland Medical Center