Carvone
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| Carvone | ||
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| General | ||
| Systematic name | 2-methyl-5-(prop-1-en-2-yl) cyclohex-2-enone |
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| Other names | Δ6:8(9)-p-menthadien-2-one 1-methyl-4-isopropenyl- Δ6-cyclohexen-2-one carvol (obsolete) |
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| Molecular formula | C10H14O | |
| SMILES | C=C(C)C(C1)CC=C(C)C1=O | |
| Molar mass | 150.22 g/mol | |
| Appearance | Clear, colourless liquid | |
| CAS number | [6485-40-1] ((R)-Carvone) [2244-16-8] ((S)-Carvone) |
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| Properties | ||
| Density and phase | 0.958 g/cm3, | |
| Solubility in water | Insoluble (cold) Slightly soluble (hot) |
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| Solubility in Ethanol | soluble | |
| Solubility in Diethyl ether | soluble | |
| Solubility in Chloroform | soluble | |
| Melting point | 89 °C | |
| Boiling point | 231 °C | |
| Acidity (pKa) | ? | |
| Chiral rotation [α]D | -61° (R)-Carvone 61° (S)-Carvone, |
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| Hazards | ||
| MSDS | External MSDS | |
| Main hazards | flammable | |
| NFPA 704 |
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| R-phrases | 22 | |
| S-phrases | 36 | |
| RTECS number | OS8650000 (R) OS8670000 (S) |
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| Supplementary data page | ||
| Structure and properties |
n, εr, etc. | |
| Thermodynamic data |
Phase behaviour Solid, liquid, gas |
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| Spectral data | UV, IR, NMR, MS | |
| Related compounds | ||
| Related ketones | menthone dihydrocarvone carvomenthone |
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| Related compounds | limonene, menthol, p-cymene, carveol |
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| Except where noted otherwise, data are given for materials in their standard state (at 25 °C, 100 kPa) Infobox disclaimer and references |
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Carvone is a member of a family of chemicals called terpenoids. Carvone is found naturally in many essential oils, but is most abundant in the oils from seeds of caraway (Carum Carvi) and dill.
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[edit] Stereoisomerism and odour
Carvone forms two mirror image forms or enantiomers: S-(+)-carvone smells like caraway. Its mirror image, R-(–)-carvone, smells like spearmint. The fact that the two enantiomers are perceived as smelling differently is proof that olfactory receptors must contain chiral groups, allowing them to respond more strongly to one enantiomer than to the other. Not all enantiomers have distinguishable odours. Squirrel monkeys have also been found to be able to discriminate between carvone enantiomers.
The two forms are also referred to by older names, with dextro-, d- referring to S-carvone, and laevo-, l- referring to R-carvone.
[edit] Occurrence
S-(+)-Carvone is the principal constituent (50-70%) of the oil from caraway seeds (Carum carvi),, which is produced on a scale of about 10 tonnes per year. [2] It also occurs to the extent of about 40-60% in dill seed oil (from Anethum graveolens), and also in mandarin orange peel oil. R-(–)-Carvone is present at levels greater than 51% in spearmint oil (Mentha spicata), which is produced on a scale of around 1500 tonnes annually. This isomer also occurs in kuromoji oil. Some oils, like gingergrass oil, contain a mixture of both enantiomers. Many other natural oils, for example peppermint oil, contain lower concentrations of carvones.
[edit] History
Caraway was used for medicinal purposes by the ancient Romans[2], but carvone was probably not isolated as a pure compound until Varrentrapp obtained it in1841.[1] It was originally called carvol by Schweizer. Goldschmidt and Zűrrer identified it as a ketone related to limonene, and the structure was finally elucidated by Wagner in 1894.
[edit] Preparation
The dextro-form is obtained practically pure by the fractional distillation of caraway oil; the laevo-form from the oils containing it, by first forming its addition compound with hydrogen sulfide, decomposing this by potassium hydroxide in ethanol, and distilling the product in a current of steam. It may be synthetically prepared from limonene nitrosochloride, alcoholic converting this compound into 1-carvoxime, which on boiling with dilute sulfuric acid yields l-carvone.
The biosynthesis of carvone is by oxidation of limonene.
[edit] Chemical properties
[edit] Reduction
There are three double bonds in carvone capable of reduction; the product of reduction depends on the reagents and conditions used. Catalytic hydrogenation of carvone (1) can give either carvomenthol (2) or carvomenthone (3). Zinc and acetic acid reduce carvone to give dihydrocarvone (4). MPV reduction using propan-2-ol and aluminium isopropoxide effects reduction of the carbonyl group only to provide carveol (5); a combination of sodium borohydride and CeCl3 (Luche reduction) is also effective. Hydrazine and potassium hydroxide give limonene (6) via a Wolff-Kishner reduction.
[edit] Oxidation
Oxidation of carvone can also lead to a variety of products. In the presence of an alkali such as Ba(OH)2, carvone is oxidised by air or oxygen to give the diketone 7. With hydrogen peroxide the epoxide 8 is formed. Carvone may be cleaved using ozone followed by steam, giving dilactone 9, while KMnO4 gives 10.
[edit] Conjugate additions
As an α,beta;-unsaturated ketone, carvone undergoes conjugate additions of nucleophiles. For example, carvone reacts with lithium dimethylcuprate to place a methyl group trans to the isopropenyl group with good stereoselectivity. The resulting enolate can then be allylated using allyl bromide to give ketone 11.
[edit] Uses
Both carvones are used in the food and flavor industry. R-(-)-Carvone is also used for air freshening products and, like many essential oils, oils containing carvones are used in aromatherapy and alternative medicine.
[edit] Food applications
As the compound most responsible for the flavour of caraway, dill and spearmint, carvone has been used for millennia in food. Wrigley's Spearmint Gum is gum soaked in R-(–)-carvone and powdered with sugar.
[edit] Agriculture
S-(+)-Carvone is also used to prevent premature sprouting of potatoes during storage, being marketed in the Netherlands for this purpose under the name Talent.
[edit] Organic synthesis
Carvone is available inexpensively in both enantiomerically pure forms, making it an attractive starting material for the asymmetric total synthesis of natural products. For example, (S)-(+)-carvone was used to begin a 1998 synthesis of the terpenoid quassin:
[edit] Metabolism
In the body, in vivo studies indicate that both enantiomers of carvone are mainly metabolized into dihydrocarvonic acid, carvonic acid and uroterpenolone. (4R,6S)-(–)-carveol is also formed as a minor product via reduction by NADPH. (4S)-(+)-carvone is likewise converted to (4S,6S)-(+)-carveol. This mainly occurs in the liver and involves cytochrome P450 oxidase.
[edit] References
- ↑ Simonsen, J. L. (1953) The Terpenes (2nd edition) Vol. 1 Cambridge:Cambridge University Press, pp 394-408.
- ↑ De Carvalho, C. C. C. R; Da Fonseca, M. M. R. "Carvone: Why and how should one bother to produce this terpene" Food Chemistry 2006, 95, 413-422.
- ↑ Laska, M.; Liesen, A.; Teubner, P. American Journal of Physiology- Regulatory Integrative and Comparative Physiology, 1999, 277, R1098-R1103.
- ↑ Hornok, L. Cultivation and Processing of Medicinal Plants, John Wiley & Sons, Chichester, UK, 1992.
- ↑ Wagner, G. Chemische Berichte 1894, 27, 2270.
- ↑ Srikrishna, A.; Jagadeeswar Reddy, T. Tetrahedron, 1998, 54, 11517-11524.
- ↑ (a) Shing, T. K. M.; Jiang, Q; Mak, T. C. W. J. Org. Chem. 1998, 63, 2056-2057. (b) Shing, T. K. M.; Tang, Y. J. Chem. Soc. Perkin Trans. 1 1994, 1625.
- ↑ Engel, W. J. Agric. Food Chem., 2001, 49 (8), 4069-4075.
- ↑ Jager, W.; Mayer, M.; Platzer, P.; Reznicek, G.; Dietrich, H.; Buchbauer, G.; Journal of Pharmacy and Pharmacology 2000, 52, 191-197.
