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Anethole

Anethole
Skeletal formula of anethole
Ball-and-stick model of the anethole molecule
Names
Preferred IUPAC name
1-Methoxy-4-[(1E)-prop-1-en-1-yl]benzene
Other names
(E)-1-Methoxy-4-(prop-1-en-1-yl)benzene
(E)-1-Methoxy-4-(1-propenyl)benzene
para-Methoxyphenylpropene
p-Propenylanisole
Isoestragole
trans-1-Methoxy-4-(prop-1-enyl)benzene
Identifiers
3D model (JSmol)
ChEBI
ChEMBL
ChemSpider
ECHA InfoCard 100.002.914
KEGG
UNII
Properties
C10H12O
Molar mass 148.205 g·mol−1
Density 0.998 g/cm3
Melting point 20 to 21 °C (68 to 70 °F; 293 to 294 K)
Boiling point 234 °C (453 °F; 507 K) (81 °C at 2 mmHg)
−9.60×10−5 cm3/mol
Hazards
Safety data sheet External MSDS[dead link]
Related compounds
Related compounds
 anisole
estragole
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Infobox references

Anethole (also known as anise camphor[citation needed]) is an organic compound that is widely used as a flavoring substance. It is a derivative of phenylpropene, a type of aromatic compound that occurs widely in nature, in essential oils. It contributes a large component of the odor and flavor of anise and fennel (both in the botanical family Apiaceae), anise myrtle (Myrtaceae), liquorice (Fabaceae), camphor, magnolia blossoms, and star anise (Illiciaceae). Closely related to anethole is its isomer estragole, abundant in tarragon (Asteraceae) and basil (Lamiaceae), that has a flavor reminiscent of anise. It is a colorless, fragrant, mildly volatile liquid.[1] Anethole is only slightly soluble in water but exhibits high solubility in ethanol. This trait causes certain anise-flavored liqueurs to become opaque when diluted with water, the ouzo effect.

Structure and production

Anethole is an aromatic, unsaturated ether related to lignols. It exists as both cistrans isomers (see also EZ notation), involving the double bond outside the ring. The more abundant isomer, and the one preferred for use, is the trans or E isomer.

Like related compounds, anethole is poorly soluble in water. Historically, this property was used to detect adulteration in samples.[2]

Most anethole is obtained from turpentine-like extracts from trees.[1][3] Of only minor commercial significance, anethole can also be isolated from essential oils.[4][5][6]

Essential oil World production trans-Anethole
Anise 8 tonnes (1999) 95%
Star anise 400 tonnes (1999), mostly from China 87%
Fennel 25 tonnes (1999), mostly from Spain 70%

It is prepared commercially from 4-methoxypropiophenone, which is prepared from anisole.[1]

Uses

Flavoring

Anethole is distinctly sweet, measuring 13 times sweeter than sugar. It is perceived as being pleasant to the taste even at higher concentrations. It is used in alcoholic drinks ouzo, rakı, anisette and absinthe, among others. It is also used in seasoning and confectionery applications, oral hygiene products, and in small quantities in natural berry flavors.[5]

Precursor to other compounds

Because they metabolize anethole into several aromatic chemical compounds, some bacteria are candidates for use in commercial bioconversion of anethole to more valuable materials.[7] Bacterial strains capable of using trans-anethole as the sole carbon source include JYR-1 (Pseudomonas putida)[8] and TA13 (Arthrobacter aurescens).[7]

Research

Antimicrobial and antifungal activity

Anethole has potent antimicrobial properties, against bacteria, yeasts, and fungi.[9] Reported antibacterial properties include both bacteriostatic and bactericidal action against Salmonella enterica[10] but not when used against Salmonella via a fumigation method.[11] Antifungal activity includes increasing the effectiveness of some other phytochemicals (such as polygodial) against Saccharomyces cerevisiae and Candida albicans;[12]

In vitro, anethole has antihelmintic action on eggs and larvae of the sheep gastrointestinal nematode Haemonchus contortus.[13] Anethole also has nematicidal activity against the plant nematode Meloidogyne javanica in vitro and in pots of cucumber seedlings.[14]

Insecticidal activity

Anethole also is a promising insecticide. Several essential oils consisting mostly of anethole have insecticidal action against larvae of the mosquito Ochlerotatus caspius[15] and Aedes aegypti.[16][17] In a similar manner, anethole itself is effective against the fungus gnat Lycoriella ingenua (Sciaridae)[18] and the mold mite Tyrophagus putrescentiae.[19] Against the mite, anethole is a slightly more effective pesticide than DEET, but anisaldehyde, a related natural compound that occurs with anethole in many essential oils, is 14 times more effective.[19] The insecticidal action of anethole is greater as a fumigant than as a contact agent. trans-Anethole is highly effective as a fumigant against the cockroach Blattella germanica[20] and against adults of the weevils Sitophilus oryzae, Callosobruchus chinensis and beetle Lasioderma serricorne.[21]

As well as an insect pesticide, anethole is an effective insect repellent against mosquitos.[22]

Ouzo effect

Diluting absinthe with water produces a spontaneous microemulsion (ouzo effect)

Anethole is responsible for the "ouzo effect" (also "louche effect"), the spontaneous formation of a microemulsion[23][24] that gives many alcoholic beverages containing anethole and water their cloudy appearance.[25] Such a spontaneous microemulsion has many potential commercial applications in the food and pharmaceutical industries.[26]

Precursor to illicit drugs

Anethole is an inexpensive chemical precursor for paramethoxyamphetamine (PMA),[27] and is used in its clandestine manufacture.[28] Anethole is present in the essential oil from guarana, which is alleged to have a psychoactive effect. The absence of PMA or any other known psychoactive derivative of anethole in human urine after ingestion of guarana leads to the conclusion that any purported psychoactive effect of guarana is not due to aminated anethole metabolites.[29]

Anethole is also present in absinthe, a liquor with a reputation for psychoactive effects; these effects, however, are attributed to ethanol.[30] (See also thujone, anethole dithione (ADT), and anethole trithione (ATT).)

Estrogen and prolactin

Anethole has estrogenic activity.[31] It has been found to significantly increase uterine weight in immature female rats.[32]

Fennel, which contains anethole, has been found to have a galactagogue effect in animals. Anethole bears a structural resemblance to catecholamines like dopamine and may displace dopamine from its receptors and thereby disinhibit prolactin secretion, which in turn may be responsible for the galactagogue effects.[33]

Safety

Formerly generally recognized as safe (GRAS), after a hiatus anethole was reaffirmed by Flavor and Extract Manufacturers Association (FEMA) as GRAS.[34] The hiatus was due to concerns about liver toxicity and possible carcinogenic activity, reported in rats.[35] Anethole is associated with a slight increase in liver cancer in rats,[35] although the evidence is scant and generally regarded as evidence that anethole is not a carcinogen.[35][36] An evaluation of anethole by the Joint FAO/WHO Expert Committee on Food Additives (JECFA) found its notable pharmacologic properties to be reduction in motor activity, lowering of body temperature, and hypnotic, analgesic, and anticonvulsant effects.[37] A subsequent evaluation by JECFA found some reason for concern regarding carcinogenicity, but there is currently insufficient data to support this.[38] At this time, the JECFA summary of these evaluations is that anethole has no safety concern at current levels of intake when used as a flavoring agent.[39]

In large quantities, anethole is slightly toxic and may act as an irritant.[40]

History

That an oil could be extracted from anise and fennel had been known since the Renaissance by the German alchemist Hieronymus Brunschwig (c. 1450 – c. 1512), the German botanist Adam Lonicer (1528–1586), and the German physician Valerius Cordus (1515–1544), among others.[41] Anethole was first investigated chemically by the Swiss chemist Nicolas-Théodore de Saussure in 1820.[42] In 1832 the French chemist Jean Baptiste Dumas determined that the crystallizable components of anise oil and fennel oil were identical, and he determined anethole's empirical formula.[43] In 1845, the French chemist Charles Gerhardt coined the term anethol — from the Latin anethum (anise) + oleum (oil) — for the fundamental compound from which a family of related compounds was derived.[44] Although the German chemist Emil Erlenmeyer proposed the correct molecular structure for anethole in 1866,[45] it was not until 1872 that the structure was accepted as correct.[41]

See also

References

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  2. ^ Waldbott, S. (1920). "Essential oils". Chemical Abstracts. 14 (17): 3753–3755.
  3. ^ US 4902850, Davis, Curry B., "Purification of anethole by crystallization", issued 1990-02-20 
  4. ^ Chopra, R. N.; Chopra, I. C.; Handa, K. L.; Kapur, L. D. (1958). Chopra's Indigenous Drugs of India (2nd ed.). Academic Publishers. pp. 178–179. ISBN 978-81-85086-80-4.
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  6. ^ Bodsgard, B. R.; Lien, N. R.; Waulters, Q. T. (2016). "Liquid CO2 Extraction and NMR Characterization of Anethole from Fennel Seed: A General Chemistry Laboratory". Journal of Chemical Education. 93 (2): 397–400. doi:10.1021/acs.jchemed.5b00689.
  7. ^ a b Shimoni, E; Baasov, T.; Ravid, U.; Shoham, Y. (2002). "The trans-anethole degradation pathway in an Arthrobacter sp". Journal of Biological Chemistry. 277 (14): 11866–11872. doi:10.1074/jbc.M109593200. PMID 11805095.
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  20. ^ Chang, K. S.; Ahn, Y. J. (2002). "Fumigant activity of (E)-anethole identified in Illicium verum fruit against Blattella germanica". Pest Management Science. 58 (2): 161–166. doi:10.1002/ps.435. PMID 11852640.
  21. ^ Kim, D. H.; Ahn, Y. J. (2001). "Contact and fumigant activities of constituents of Foeniculum vulgare fruit against three coleopteran stored-product insects". Pest Management Science. 57 (3): 301–306. doi:10.1002/ps.274. PMID 11455661.
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  23. ^ Sitnikova, Natalia L.; Sprik, Rudolf; Wegdam, Gerard; Eiser, Erika (2005). "Spontaneously formed trans-anethol/water/alcohol emulsions: Mechanism of formation and stability" (PDF). Langmuir. 21 (16): 7083–7089. doi:10.1021/la046816l. PMID 16042427. Archived from the original (PDF) on 2009-03-18. Retrieved 2009-03-15.
  24. ^ Carteau, David; Bassani, Dario; Pianet, Isabelle (2008). "The "Ouzo effect": Following the spontaneous emulsification of trans-anethole in water by NMR". Comptes Rendus Chimie. 11 (4–5): 493–498. doi:10.1016/j.crci.2007.11.003.
  25. ^ Sánchez Domínguez, M.; Rodríguez Abreu, C. (2016). Nanocolloids: A Meeting Point for Scientists and Technologists. Elsevier Science. p. 369. ISBN 978-0-12-801758-6. Retrieved 2018-08-02. O/W and W/O nano-emulsions can also be formed without a surfactant by self-emulsification, using the so-called Ouzo effect. The major components of Ouzo (a Greek drink) are trans-anethole, ethanol, and water. Anethole is almost insoluble ...
  26. ^ Spernath, A.; Aserin, A. (2006). "Microemulsions as carriers for drugs and nutraceuticals". Advances in Colloid and Interface Science. 128–130: 47–64. doi:10.1016/j.cis.2006.11.016. PMID 17229398.
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  30. ^ Lachenmeier, D. W. (2008). "Thujon-Wirkungen von Absinth sind nur eine Legende—Toxikologie entlarvt Alkohol als eigentliche Absinthismus-Ursache" [Thujone-attributable effects of absinthe are only an urban legend—toxicology uncovers alcohol as real cause of absinthism]. Medizinische Monatsschrift für Pharmazeuten (in German). 31 (3): 101–106. PMID 18429531.
  31. ^ Jordan, Virgil Craig (1986). Estrogen/Antiestrogen Action and Breast Cancer Therapy. University of Wisconsin Press. pp. 21–22. ISBN 978-0-299-10480-1.
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  34. ^ Newberne, P.; Smith, R. L.; Doull, J.; Goodman, J. I.; Munro, I. C.; Portoghese, P. S.; Wagner, B. M.; Weil, C. S.; Woods, L. A.; Adams, T. B.; Lucas, C. D.; Ford, R. A. (1999). "The FEMA GRAS assessment of trans-anethole used as a flavouring substance. Flavour and Extract Manufacturers' Association". Food and Chemical Toxicology. 37 (7): 789–811. doi:10.1016/S0278-6915(99)00037-X. PMID 10496381.
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  37. ^ Joint FAO/WHO Expert Committee on Food Additives. "trans-Anethole". WHO Food Additives Series. 14 (466). International Program on Chemical Safety (IPCS). Cite journal requires |journal= (help)
  38. ^ Joint FAO/WHO Expert Committee on Food Additives (1998). "trans-Anethole". WHO Food Additives Series. 28 (717). International Program on Chemical Safety (IPCS). Cite journal requires |journal= (help)
  39. ^ "Summary of Evaluations Performed by the Joint FAO/WHO Expert Committee on Food Additives: trans-Anethole". International Program on Chemical Safety (IPCS). 2001-11-12. Archived from the original on 2009-03-11. Retrieved 2009-03-10.
  40. ^ "Safety data for anethole". Physical & Theoretical Chemistry Laboratory Safety, Oxford University. Retrieved 2009-03-10.
  41. ^ a b See:
  42. ^ De Saussure, N.-T. (1820). "Observations sur la combinaison de l'essence de citron avec l'acide muriatique, et sur quelques substances huileuses" [Observations on the combination of lemon essence with muriatic acid, and on several oily substances]. Annales de Chimie et de Physique. Série 2. 13: 259–284. See especially pp. 280–284.
  43. ^ See:
    • Dumas, J. (1832). "Mémoire sur les substances végétales qui se rapprochent du camphre, et sur quelques huiles essentielles" [Memoir on plant substances that resemble camphor, and on several essential oils]. Annales de Chimie et de Physique. Série 2. 50: 225–240. On p. 234, Dumas provides an empirical formula C10H6O1/2 for anethol. If the subscripts are doubled and if the subscript for carbon is then halved (because Dumas, like many of his contemporaries, used the wrong atomic mass for carbon, 6 instead of 12), then Dumas' empirical formula is correct.
    • Dumas' finding that the crystallizable components of anise oil and fennel oil were identical was confirmed in 1833 by the team of Rodolphe Blanchet (1807–1864) and Ernst Sell (1808–1854). See: Blanchet, Sell (1833). "Ueber die Zusammensetzung einiger organischer Substanzen" [On the composition of some organic substances]. Annalen der Pharmacie. 6 (3): 259–313. doi:10.1002/jlac.18330060304. See especially pp. 287–288.
    • Dumas' empirical formula for anethole was confirmed in 1841 by the French chemist Auguste Cahours. See: Cahours, A. A. T. (1841). "Sur les essences de fenouil, de badiane et d'anis" [On the essential oils of fennel, star anise, and anise]. Annales de Chimie et de Physique. Série 3. 2: 274–308. See pp. 278–279. Note that the subscripts of Cahours' empirical formula (C40H24O2) must be divided by 2 and then the subscript for carbon must be divided again by 2 (because, like many chemists of his time, Cahours used the wrong atomic mass for carbon, 6 instead of 12). If these changes are made, the resulting empirical formula is correct.
  44. ^ Gerhardt, Charles (1845). "Ueber die Identität des Dragonöls und des Anisöls" [On the identity of dragon oil and anise oil]. Journal für praktische Chemie. 36: 267–276. doi:10.1002/prac.18450360159. From p. 269: "Ich werde keinen neuen Namen für jede einzelne Art der folgenden physisch verschiedenen Arten annehmen. In meinem Werke bezeichne ich sie als Varietäten der Gattung „Anethol“." (I will adopt no new name for any individual species of the following physically different species. In my work, I designate them as varieties of the genus anethol.)
  45. ^ Erlenmeyer, Emil (1866). "Ueber die Constitution des Anisols (Anethols)" [On the constitution of anisol (anethol)]. Zeitschrift für Chemie. 2nd Series. 2: 472–474.

External links

  • Media related to Anethole at Wikimedia Commons