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Harmine

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Template:Chembox new Harmine is a fluorescent harmala alkaloid belonging to the beta-carboline family of compounds. It occurs in a number of different plants, most notably the Middle Eastern plant harmal or Syrian rue (Peganum harmala) and the South American vine Banisteriopsis caapi ('yage', 'ayahuasca'). Harmine is a reversible monoamine oxidase inhibitor (MAO inhibitor or MAOI) and CNS stimulant. It inhibits MAO-A but has no effect on MAO-B.[1]

Uses

As a MAO inhibitor, harmine inhibits the breakdown of monoamines by enzymes called monoamine oxidases. Monoamines include neurotransmitters (serotonin, dopamine), hormones (melatonin) and drugs, including many hallucinogens (psilocybin, dimethyltryptamine (DMT), mescaline). By slowing the breakdown of neurotransmitters, MAOIs can help to replenish the body's supply of these chemicals, and many MAOIs are used as antidepressants. Harmine has not been the subject of much clinical research in the treatment of depression, which could be due in part to its restricted legal status in many countries, as well as the existence of synthetic MAOIs with fewer side effects.

P. harmala and B. caapi are both traditionally used for their psychoactive effects. B. caapi has a tradition of use in conjunction with plants containing the drug DMT. Traditionally, B. caapi is consumed as a drink, with or without the DMT-bearing plants (see Ayahuasca). Ordinarily, DMT is not active when taken orally, but users report very different effects when DMT is present in such beverages. Harmine and substances containing it have been used in conjunction with many other drugs by modern experimenters. Many hallucinogens appear to exhibit increased potency when used in this way.

Harmine is also a useful fluorescent pH indicator. As the pH of its local environment increases, the fluorescence emission of harmine decreases.

With the radioisotope carbon-11 harmine is used in positron emission tomography neuroimaging to examine its binding to MAO-A.[2]

Harmine found in root secretions of Oxalis tuberosa has been found to have insecticidal properties.[3]

Anticancer

"Harmine showed cytotoxicity against HL60 and K562 cell lines. This could explain the cytotoxic effect of P. harmala on these cells."[4]

Adverse effects

It is important to note that unlike synthetic pharmaceutical MAOIs such as phenelzine, harmine is reversible and selective meaning it does not have nearly as high a risk for the "cheese syndrome" caused by consuming tyramine-containing foods, which is a risk associated with pharmaceutical MAOIs sometimes (mistakenly) applied to all MAO inhibitors.[5] Harmine, and plants containing significant amounts of harmine and other harmala alkaloids are generally not considered safe treatments for depression within the medical community.[6]

Natural sources

Harmine is found in a wide variety of different organisms, most of which are plants. Shulgin's[7] list about thirty different species known to contain harmine, including seven species of butterfly in the Nymphalidae family. The harmine-containing plants listed include tobacco, two species of passion flower/passion fruit, and numerous others.

In addition to B. caapi, at least three members of the Malpighiaceae contain harmine, including two more Banisteriopsis species and the plant Callaeum antifebrile. Callaway, Brito and Neves (2005)[8] found harmine levels of 0.31-8.43% in B. caapi samples.

The Zygophyllaceae family, which harmal belongs to, contains at least two other harmine-bearing plants: Peganum nigellastrum and Zygophyllum fabago.

See also

References

  1. ^ Abstract Gerardy J, "Effect of moclobemide on rat brain monoamine oxidase A and B: comparison with harmaline and clorgyline.", Department of Pharmacology, University of Liège, Sart Tilman, Belgium.
  2. ^ Nathalie Ginovart, Jeffrey H. Meyer, Anahita Boovariwala, Doug Hussey, Eugenii A. Rabiner, Sylvain Houle and Alan A. Wilson (2006). "Positron emission tomography quantification of [11C]-harmine binding to monoamine oxidase-A in the human brain". Journal of Cerebral Blood Flow & Metabolism. 26: 330–344. doi:10.1038/sj.jcbfm.9600197.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  3. ^ Pal Bais, Harsh (18 June 2002). "Exudation of fluorescent b-carbolines from Oxalis tuberosa L. roots" (PDF). Phytochemistry. 61: 539–543. doi:10.1016/S0031-9422(02)00235-2. Retrieved 2008-02-02. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
  4. ^ Jahaniani, F. "Xanthomicrol is the main cytotoxic component of Dracocephalum kotschyii and a potential anti-cancer agent". Phytochemistry. 66: 1581. doi:10.1016/j.phytochem.2005.04.035. Retrieved 2008-01-12. {{cite journal}}: Cite has empty unknown parameter: |coauthors= (help)
  5. ^ McKenna, Callaway, & Grb. "Scientific Investigation of Ayahuasca", Scientific Investigation of Ayahuasca, retrieved 2007-06-03.
  6. ^ Eric Yarnell, Kathy Abascal (2001). "Botanical Treatments for Depression". Alternative & Complementary Therapies. 7 (3): 138–143. doi:10.1089/10762800151125056. {{cite journal}}: Unknown parameter |month= ignored (help)
  7. ^ Shulgin, Alexander and Shulgin, Ann (1997). TiHKAL: The Continuation. Transform Press. ISBN 0963009699.{{cite book}}: CS1 maint: multiple names: authors list (link) Pages 713–714
  8. ^ Callaway J. C., Brito G. S. & Neves E. S. (2005). "Phytochemical analyses of Banisteriopsis caapi and Psychotria viridis". Journal of Psychoactive Drugs. 37 (2): 145–150. PMID 16149327.

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