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Capsaicin

February 16, 2024

Capsaicin (8-methyl-N-vanillyl-6-nonenamide) (/kæpˈssɪn/ or /kæpˈsəsɪn/) is an active component of chili peppers, which are plants belonging to the genus Capsicum. It is a chemical irritant and neurotoxin[6] for mammals, including humans, and produces a sensation of burning in any tissue with which it comes into contact. Capsaicin and several related amides (capsaicinoids) are produced as secondary metabolites by chili peppers, probably as deterrents against certain mammals and fungi.[7] Pure capsaicin is a hydrophobic, colorless, highly pungent (ie spicy) crystalline solid.[2]

Capsaicin
Names
Pronunciation /kæpˈssɪn/ or /kæpˈsəsɪn/
Preferred IUPAC name
(6E)-N-[(4-Hydroxy-3-methoxyphenyl)methyl]-8-methylnon-6-enamide
Other names
(E)-N-(4-Hydroxy-3-methoxybenzyl)-8-methylnon-6-enamide
8-Methyl-N-vanillyl-trans-6-nonenamide
trans-8-Methyl-N-vanillylnon-6-enamide
(E)-Capsaicin
Capsicine
Capsicin
CPS
Identifiers
  • 404-86-4 Y
3D model (JSmol)
  • Interactive image
2816484
ChEBI
  • CHEBI:3374 Y
ChEMBL
  • ChEMBL294199 Y
ChemSpider
  • 1265957 Y
DrugBank
  • DB06774
ECHA InfoCard 100.006.337
EC Number
  • 206-969-8
  • 2486
KEGG
  • C06866 Y
  • 1548943
UNII
  • S07O44R1ZM Y
  • DTXSID9020241
  • InChI=1S/C18H27NO3/c1-14(2)8-6-4-5-7-9-18(21)19-13-15-10-11-16(20)17(12-15)22-3/h6,8,10-12,14,20H,4-5,7,9,13H2,1-3H3,(H,19,21)/b8-6+ Y
    Key: YKPUWZUDDOIDPM-SOFGYWHQSA-N Y
  • InChI=1/C18H27NO3/c1-14(2)8-6-4-5-7-9-18(21)19-13-15-10-11-16(20)17(12-15)22-3/h6,8,10-12,14,20H,4-5,7,9,13H2,1-3H3,(H,19,21)/b8-6+
    Key: YKPUWZUDDOIDPM-SOFGYWHQBQ
  • O=C(NCc1cc(OC)c(O)cc1)CCCC/C=C/C(C)C
Properties
C18H27NO3
Molar mass 305.418 g·mol−1
Appearance Crystalline white powder[1]
Odor Highly pungent
Melting point 62 to 65 °C (144 to 149 °F; 335 to 338 K)
Boiling point 210 to 220 °C (410 to 428 °F; 483 to 493 K) 0.01 Torr
0.0013 g/100mL
Solubility
Vapor pressure 1.32×10−8 mm Hg at 25 °C[2]
UV-vismax) 280 nm
Structure
Monoclinic
Pharmacology
M02AB01 (WHO) N01BX04 (WHO)
License data
  • EU EMAby INN
Legal status
Hazards
GHS labelling:
Danger
H301, H302, H315, H318
P264, P270, P280, P301+P310, P301+P312, P302+P352, P305+P351+P338, P310, P321, P330, P332+P313, P362, P405, P501
NFPA 704 (fire diamond)
Health 2: Intense or continued but not chronic exposure could cause temporary incapacitation or possible residual injury. E.g. chloroformFlammability 1: Must be pre-heated before ignition can occur. Flash point over 93 °C (200 °F). E.g. canola oilInstability 0: Normally stable, even under fire exposure conditions, and is not reactive with water. E.g. liquid nitrogenSpecial hazards (white): no code
2
1
0
Safety data sheet (SDS) [2]
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Y verify (what is YN ?)
Capsaicin
HeatAbove peak
(pure capsaicin is toxic)[2]
Scoville scale16,000,000[5] SHU

Natural function edit

Capsaicin is present in large quantities in the placental tissue (which holds the seeds), the internal membranes and, to a lesser extent, the other fleshy parts of the fruits of plants in the genus Capsicum. The seeds themselves do not produce any capsaicin, although the highest concentration of capsaicin can be found in the white pith of the inner wall, where the seeds are attached.[8]

The seeds of Capsicum plants are dispersed predominantly by birds. In birds, the TRPV1 channel does not respond to capsaicin or related chemicals but mammalian TRPV1 is very sensitive to it. This is advantageous to the plant, as chili pepper seeds consumed by birds pass through the digestive tract and can germinate later, whereas mammals have molar teeth which destroy such seeds and prevent them from germinating. Thus, natural selection may have led to increasing capsaicin production because it makes the plant less likely to be eaten by animals that do not help it disperse.[9] There is also evidence that capsaicin may have evolved as an anti-fungal agent.[10] The fungal pathogen Fusarium, which is known to infect wild chilies and thereby reduce seed viability, is deterred by capsaicin, which thus limits this form of predispersal seed mortality.

The vanillotoxin-containing venom of a certain tarantula species (Psalmopoeus cambridgei) activates the same pathway of pain as is activated by capsaicin, an example of a shared pathway in both plant and animal anti-mammalian defense.[11]

Uses edit

Food edit

Main article: Pungency
 
Curry dishes

Because of the burning sensation caused by capsaicin when it comes in contact with mucous membranes, it is commonly used in food products to provide added spiciness or "heat" (piquancy), usually in the form of spices such as chili powder and paprika.[12] In high concentrations, capsaicin will also cause a burning effect on other sensitive areas, such as skin or eyes.[13] The degree of heat found within a food is often measured on the Scoville scale.[12]

There has long been a demand for capsaicin-spiced products like chili pepper, and hot sauces such as Tabasco sauce and Mexican salsa.[12] It is common for people to experience pleasurable and even euphoric effects from ingesting capsaicin.[12] Folklore among self-described "chiliheads" attribute this to pain-stimulated release of endorphins, a different mechanism from the local receptor overload that makes capsaicin effective as a topical analgesic.[13]

Research and pharmaceutical use edit

Capsaicin is used as an analgesic in topical ointments and dermal patches to relieve pain, typically in concentrations between 0.025% and 0.1%.[14] It may be applied in cream form for the temporary relief of minor aches and pains of muscles and joints associated with arthritis, backache, strains and sprains, often in compounds with other rubefacients.[14]

It is also used to reduce the symptoms of peripheral neuropathy, such as post-herpetic neuralgia caused by shingles.[14] A capsaicin transdermal patch (Qutenza) for the management of this particular therapeutic indication (pain due to post-herpetic neuralgia) was approved in 2009, as a therapeutic by both the U.S. Food and Drug Administration (FDA)[15][16] and the European Union.[17] A subsequent application to the FDA for Qutenza to be used as an analgesic in HIV neuralgia was refused.[18] One 2017 review of clinical studies having limited quality found that high-dose topical capsaicin (8%) compared with control (0.4% capsaicin) provided moderate to substantial pain relief from post-herpetic neuralgia, HIV-neuropathy, and diabetic neuropathy.[19]

Although capsaicin creams have been used to treat psoriasis for reduction of itching,[14][20][21] a review of six clinical trials involving topical capsaicin for treatment of pruritus concluded there was insufficient evidence of effect.[22] Oral capsaicin decreases LDL cholesterol levels moderately.[23]

There is insufficient clinical evidence to determine the role of ingested capsaicin on several human disorders, including obesity, diabetes, cancer and cardiovascular diseases.[14]

Pepper spray and pests edit

Capsaicinoids are also an active ingredient in riot control and personal defense pepper spray agents.[2] When the spray comes in contact with skin, especially eyes or mucous membranes, it produces pain and breathing difficulty in the affected individual.[2]

Capsaicin is also used to deter pests, specifically mammalian pests. Targets of capsaicin repellants include voles, deer, rabbits, squirrels, bears, insects, and attacking dogs.[24] Ground or crushed dried chili pods may be used in birdseed to deter rodents,[25] taking advantage of the insensitivity of birds to capsaicin. The Elephant Pepper Development Trust claims that using chili peppers as a barrier crop can be a sustainable means for rural African farmers to deter elephants from eating their crops.[26]

An article published in the Journal of Environmental Science and Health Part B in 2006 states that "Although hot chili pepper extract is commonly used as a component of household and garden insect-repellent formulas, it is not clear that the capsaicinoid elements of the extract are responsible for its repellency."[27]

The first pesticide product using solely capsaicin as the active ingredient was registered with the U.S. Department of Agriculture in 1962.[24]

Equestrian sports edit

Capsaicin is a banned substance in equestrian sports because of its hypersensitizing and pain-relieving properties.[28] At the show jumping events of the 2008 Summer Olympics, four horses tested positive for capsaicin, which resulted in disqualification.[28]

Irritant effects edit

Acute health effects edit

Capsaicin is a strong irritant requiring proper protective goggles, respirators, and proper hazardous material-handling procedures. Capsaicin takes effect upon skin contact (irritant, sensitizer), eye contact (irritant), ingestion, and inhalation (lung irritant, lung sensitizer). The LD50 in mice is 47.2 mg/kg.[29][30]

Painful exposures to capsaicin-containing peppers are among the most common plant-related exposures presented to poison centers.[31] They cause burning or stinging pain to the skin and, if ingested in large amounts by adults or small amounts by children, can produce nausea, vomiting, abdominal pain, and burning diarrhea. Eye exposure produces intense tearing, pain, conjunctivitis, and blepharospasm.[32]

Treatment after exposure edit

The primary treatment is removal of the offending substance. Plain water is ineffective at removing capsaicin.[29] Capsaicin is soluble in alcohol, which can be used to clean contaminated items.[29]

When capsaicin is ingested, cold milk may be an effective way to relieve the burning sensation due to caseins in milk, and the water of milk acts as a surfactant, allowing the capsaicin to form an emulsion with it.[33]

Weight loss and regain edit

As of 2007, there was no evidence showing that weight loss is directly correlated with ingesting capsaicin. Well-designed clinical research had not been performed because the pungency of capsaicin in prescribed doses under research prevented subjects from complying in the study.[34] A 2014 meta-analysis of further trials found weak evidence that consuming capsaicin before a meal might slightly reduce the amount of food consumed, and might drive food preference toward carbohydrates.[35]

Peptic ulcer edit

One 2006 review concluded that capsaicin may relieve symptoms of a peptic ulcer rather than being a cause of it.[36]

Mechanism of action edit

The burning and painful sensations associated with capsaicin result from "defunctionalization" of nociceptor nerve fibers by causing a topical hypersensitivity reaction in the skin.[2][37] As a member of the vanilloid family, capsaicin binds to a receptor on nociceptor fibers called the vanilloid receptor subtype 1 (TRPV1).[37][38][39] TRPV1, which can also be stimulated with heat, protons and physical abrasion, permits cations to pass through the cell membrane when activated.[37] The resulting depolarization of the neuron stimulates it to send impulses to the brain.[37] By binding to TRPV1 receptors, capsaicin produces similar sensations to those of excessive heat or abrasive damage, such as warming, tingling, itching, or stinging, explaining why capsaicin is described as an irritant on the skin and eyes or by ingestion.[37]

Clarifying the mechanisms of capsaicin effects on skin nociceptors was part of awarding the 2021 Nobel Prize in Physiology or Medicine, as it led to the discovery of skin sensors for temperature and touch, and identification of the single gene causing sensitivity to capsaicin.[40][41]

History edit

The compound was first extracted in impure form in 1816 by Christian Friedrich Bucholz (1770–1818).[42][a] In 1873 German pharmacologist Rudolf Buchheim[52][53][54] (1820–1879) and in 1878 the Hungarian doctor Endre Hőgyes[55][56] stated that "capsicol" (partially purified capsaicin[57]) caused the burning feeling when in contact with mucous membranes and increased secretion of gastric acid.

Capsaicinoids edit

See also: Capsinoids

The most commonly occurring capsaicinoids are capsaicin (69%), dihydrocapsaicin (22%), nordihydrocapsaicin (7%), homocapsaicin (1%), and homodihydrocapsaicin (1%).[58]

Capsaicin and dihydrocapsaicin (both 16.0 million SHU) are the most pungent capsaicinoids. Nordihydrocapsaicin (9.1 million SHU), homocapsaicin and homodihydrocapsaicin (both 8.6 million SHU) are about half as hot.[5]

There are six natural capsaicinoids (table below). Although vanillylamide of n-nonanoic acid (Nonivamide, VNA, also PAVA) is produced synthetically for most applications, it does occur naturally in Capsicum species.[59]

Capsaicinoid name Abbrev. Typical
relative
amount 		Scoville
heat units 		Chemical structure
Capsaicin C 69% 16,000,000  
Dihydrocapsaicin DHC 22% 16,000,000  
Nordihydrocapsaicin NDHC 7% 9,100,000  
Homocapsaicin HC 1% 8,600,000  
Homodihydrocapsaicin HDHC 1% 8,600,000  
Nonivamide PAVA 9,200,000  

Biosynthesis edit

 
Chili peppers
 
Vanillamine is a product of the phenylpropanoid pathway.
 
Valine enters the branched fatty acid pathway to produce 8-methyl-6-nonenoyl-CoA.
 
Capsaicin synthase condenses vanillamine and 8-methyl-6-nonenoyl-CoA to produce capsaicin.

History edit

The general biosynthetic pathway of capsaicin and other capsaicinoids was elucidated in the 1960s by Bennett and Kirby, and Leete and Louden. Radiolabeling studies identified phenylalanine and valine as the precursors to capsaicin.[60][61] Enzymes of the phenylpropanoid pathway, phenylalanine ammonia lyase (PAL), cinnamate 4-hydroxylase (C4H), caffeic acid O-methyltransferase (COMT) and their function in capsaicinoid biosynthesis were identified later by Fujiwake et al.,[62][63] and Sukrasno and Yeoman.[64] Suzuki et al. are responsible for identifying leucine as another precursor to the branched-chain fatty acid pathway.[65] It was discovered in 1999 that pungency of chili peppers is related to higher transcription levels of key enzymes of the phenylpropanoid pathway, phenylalanine ammonia lyase, cinnamate 4-hydroxylase, caffeic acid O-methyltransferase. Similar studies showed high transcription levels in the placenta of chili peppers with high pungency of genes responsible for branched-chain fatty acid pathway.[66]

Biosynthetic pathway edit

Plants exclusively of the genus Capsicum produce capsaicinoids, which are alkaloids.[67] Capsaicin is believed to be synthesized in the interlocular septum of chili peppers and depends on the gene AT3, which resides at the pun1 locus, and which encodes a putative acyltransferase.[68]

Biosynthesis of the capsaicinoids occurs in the glands of the pepper fruit where capsaicin synthase condenses vanillylamine from the phenylpropanoid pathway with an acyl-CoA moiety produced by the branched-chain fatty acid pathway.[61][69][70][71]

Capsaicin is the most abundant capsaicinoid found in the genus Capsicum, but at least ten other capsaicinoid variants exist.[72] Phenylalanine supplies the precursor to the phenylpropanoid pathway while leucine or valine provide the precursor for the branched-chain fatty acid pathway.[61][69] To produce capsaicin, 8-methyl-6-nonenoyl-CoA is produced by the branched-chain fatty acid pathway and condensed with vanillylamine. Other capsaicinoids are produced by the condensation of vanillylamine with various acyl-CoA products from the branched-chain fatty acid pathway, which is capable of producing a variety of acyl-CoA moieties of different chain length and degrees of unsaturation.[73] All condensation reactions between the products of the phenylpropanoid and branched-chain fatty acid pathway are mediated by capsaicin synthase to produce the final capsaicinoid product.[61][69]

Evolution edit

The Capsicum genus splits from Solanaceae 19.6 million years ago, 5.4 million years after the appearance of Solanaceae.[74] Chilies only started to quickly evolve in the past 2 million years into markedly different species. This evolution can be partially attributed to a key compound found in peppers, 8-methyl-N-vanillyl-6-nonenamide, otherwise known as capsaicin. Capsaicin evolved similarly across species of chilies that produce capsaicin. Its evolution over the course of centuries is due to genetic drift and natural selection, across the genus Capsicum. Despite the fact that chilies within the Capsicum genus are found throughout the world, the capsaicin found within them all exhibit similar properties that serve as defensive and adaptive features. Capsaicin evolved to preserve the fitness of peppers against fungi infections, insects, and granivorous mammals.[75]

Antifungal properties edit

Capsaicin acts as an antifungal agent in four primary ways. First, capsaicin inhibits the metabolic rate of the cells that make up the fungal biofilm.[76] This inhibits the area and growth rate of the fungus, since the biofilm creates an area where a fungus can grow and adhere to the chili in which capsaicin is present.[77] Capsaicin also inhibits fungal hyphae formation, which impacts the amount of nutrients that the rest of the fungal body can receive.[78] Thirdly, capsaicin disrupts the structure[79] of fungal cells and the fungal cell membranes. This has consequential negative impacts on the integrity of fungal cells and their ability to survive and proliferate. Additionally, the ergosterol synthesis of growing fungi decreases in relation to the amount of capsaicin present in the growth area. This impacts the fungal cell membrane, and how it is able to reproduce and adapt to stressors in its environment.[80]

Insecticidal properties edit

Capsaicin deters insects in multiple ways. The first is by deterring insects from laying their eggs on the pepper due to the effects capsaicin has on these insects.[81] Capsaicin can cause intestinal dysplasia upon ingestion, disrupting insect metabolism and causing damage to cell membranes within the insect.[82][83] This in turn disrupts the standard feeding response of insects.

Seed dispersion and deterrents against granivorous mammals edit

Granivorous mammals pose a risk to the propagation of chilies because their molars grind the seeds of chilies, rendering them unable to grow into new chili plants.[84][9] As a result, modern chilies evolved defense mechanisms to mitigate the risk of granivorous mammals. While capsaicin is present at some level in every part of the pepper, the chemical has its highest concentration in the tissue near the seeds within chilies.[8] Birds are able to eat chilies, then disperse the seeds in their excrement, enabling propagation.[85]

Adaptation to varying moisture levels edit

Capsaicin is a potent defense mechanism for chilies, but it does come at a cost. Varying levels of capsaicin in chilies currently appear to be caused by an evolutionary split between surviving in dry environments, and having defense mechanisms against fungal growth, insects, and granivorous mammals.[86] Capsaicin synthesis in chilies places a strain on their water resources.[87] This directly affects their fitness, as it has been observed that standard concentration of capsaicin of peppers in high moisture environments in the seeds and pericarps of the peppers reduced the seeds production by 50%.[88]

See also edit

References edit

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  43. ^ In a series of articles, J. C. Thresh obtained capsaicin in almost pure form:
    • Thresh JC (1876). "Isolation of capsaicin". The Pharmaceutical Journal and Transactions. 3rd Series. 6: 941–947.
    • Thresh JC (8 July 1876). "Capsaicin, the active principle in Capsicum fruits". The Pharmaceutical Journal and Transactions. 3rd Series. 7 (315): 21. [Note: This article is summarized in: "Capsaicin, the active principle in Capsicum fruits". The Analyst. 1 (8): 148–149. 1876. Bibcode:1876Ana.....1..148.. doi:10.1039/an876010148b.
    • Year Book of Pharmacy… (1876), pages 250 and 543;
    • Thresh JC (1877). "Note on Capsaicin". Year Book of Pharmacy: 24–25.
    • Thresh JC (1877). "Report on the active principle of Cayenne pepper". Year Book of Pharmacy: 485–488.
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  50. ^ Kosuge S, Inagaki Y, Okumura H (1961). "Studies on the pungent principles of red pepper. Part VIII. On the chemical constitutions of the pungent principles". Nippon Nogeikagaku Kaishi [Journal of the Agricultural Chemical Society of Japan] (in Japanese). 35: 923–927. doi:10.1271/nogeikagaku1924.35.10_923.
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Notes edit

  1. ^ History of early research on capsaicin:
    • Felter HW, Lloyd JU (1898). King's American Dispensatory. Vol. 1. Cincinnati, Ohio: Ohio Valley Co. p. 435.
    • Du Mez AG (1917). A century of the United States pharmocopoeia 1820–1920. I. The galenical oleoresins (PhD). University of Wisconsin. pp. 111–132.
    • The results of Bucholz's and Braconnot's analyses of Capsicum annuum appear in: Pereira J (1854). The Elements of Materia Medica and Therapeutics. Vol. 2 (3rd US ed.). Philadelphia, Pennsylvania: Blanchard and Lea. p. 506.
    • Biographical information about Christian Friedrich Bucholz is available in: Rose HJ (1857). Rose HJ, Wright T (eds.). A New General Biographical Dictionary. Vol. 5. London, England. p. 186.{{cite book}}: CS1 maint: location missing publisher (link)
    • Biographical information about C. F. Bucholz is also available (in German) online at: Allgemeine Deutsche Biographie.
    • Some other early investigators who also extracted the active component of peppers:
    1. Maurach B (1816). "Pharmaceutisch-chemische Untersuchung des spanischen Pfeffers" [Pharmaceutical-chemical investigation of Spanish peppers]. Berlinisches Jahrbuch für die Pharmacie (in German). 17: 63–73. Abstracts of Maurach's paper appear in: (i) Repertorium für die Pharmacie, vol. 6, page 117-119 (1819); (ii) Allgemeine Literatur-Zeitung, vol. 4, no. 18, page 146 (February 1821); (iii) "Spanischer oder indischer Pfeffer", System der Materia medica ..., vol. 6, pages 381–386 (1821) (this reference also contains an abstract of Bucholz's analysis of peppers).
    2. Henri Braconnot, French chemist Braconnot H (1817). "Examen chemique du Piment, de son principe âcre, et de celui des plantes de la famille des renonculacées" [Chemical investigation of the chili pepper, of its pungent principle [constituent, component], and of that of plants of the family Ranunculus]. Annales de Chimie et de Physique (in French). 6: 122- 131.
    3. Johann Georg Forchhammer, Danish geologist Oersted HC (1820). "Sur la découverte de deux nouveaux alcalis végétaux" [On the discovery of two new plant alkalis]. Journal de physique, de chemie, d'histoire naturelle et des arts [Journal of Physics, Chemistry, Natural History and the Arts] (in French). 90: 173–174.
    4. Ernst Witting, German apothecary Witting E (1822). "Considerations sur les bases vegetales en general, sous le point de vue pharmaceutique et descriptif de deux substances, la capsicine et la nicotianine" [Thoughts on the plant bases in general from a pharmaceutical viewpoint, and description of two substances, capsicin and nicotine]. Beiträge für die Pharmaceutische und Analytische Chemie [Contributions to Pharmaceutical and Analytical Chemistry] (in French). 3: 43. He called it "capsicin", after the genus Capsicum from which it was extracted. John Clough Thresh (1850–1932), who had isolated capsaicin in almost pure form,[43][44] gave it the name "capsaicin" in 1876.[45] Karl Micko isolated capsaicin in its pure form in 1898.[46][47] Capsaicin's chemical composition was first determined in 1919 by E. K. Nelson, who also partially elucidated capsaicin's chemical structure.[48] Capsaicin was first synthesized in 1930 by Ernst Spath and Stephen F. Darling.[49] In 1961, similar substances were isolated from chili peppers by the Japanese chemists S. Kosuge and Y. Inagaki, who named them capsaicinoids.[50][51]

Further reading edit

External links edit

 
Wikimedia Commons has media related to Capsaicin.
 
Look up capsaicin in Wiktionary, the free dictionary.
  • Capsaicin General Fact Sheet – National Pesticide Information Center
  • Fire and Spice: The molecular basis for flavor

February 16, 2024
capsaicin, methyl, vanillyl, nonenamide, active, component, chili, peppers, which, plants, belonging, genus, capsicum, chemical, irritant, neurotoxin, mammals, including, humans, produces, sensation, burning, tissue, with, which, comes, into, contact, several,. Capsaicin 8 methyl N vanillyl 6 nonenamide k ae p ˈ s eɪ s ɪ n or k ae p ˈ s eɪ e s ɪ n is an active component of chili peppers which are plants belonging to the genus Capsicum It is a chemical irritant and neurotoxin 6 for mammals including humans and produces a sensation of burning in any tissue with which it comes into contact Capsaicin and several related amides capsaicinoids are produced as secondary metabolites by chili peppers probably as deterrents against certain mammals and fungi 7 Pure capsaicin is a hydrophobic colorless highly pungent ie spicy crystalline solid 2 Capsaicin NamesPronunciation k ae p ˈ s eɪ s ɪ n or k ae p ˈ s eɪ e s ɪ n Preferred IUPAC name 6E N 4 Hydroxy 3 methoxyphenyl methyl 8 methylnon 6 enamideOther names E N 4 Hydroxy 3 methoxybenzyl 8 methylnon 6 enamide8 Methyl N vanillyl trans 6 nonenamidetrans 8 Methyl N vanillylnon 6 enamide E CapsaicinCapsicineCapsicinCPSIdentifiersCAS Number 404 86 4 Y3D model JSmol Interactive imageBeilstein Reference 2816484ChEBI CHEBI 3374 YChEMBL ChEMBL294199 YChemSpider 1265957 YDrugBank DB06774ECHA InfoCard 100 006 337EC Number 206 969 8IUPHAR BPS 2486KEGG C06866 YPubChem CID 1548943UNII S07O44R1ZM YCompTox Dashboard EPA DTXSID9020241InChI InChI 1S C18H27NO3 c1 14 2 8 6 4 5 7 9 18 21 19 13 15 10 11 16 20 17 12 15 22 3 h6 8 10 12 14 20H 4 5 7 9 13H2 1 3H3 H 19 21 b8 6 YKey YKPUWZUDDOIDPM SOFGYWHQSA N YInChI 1 C18H27NO3 c1 14 2 8 6 4 5 7 9 18 21 19 13 15 10 11 16 20 17 12 15 22 3 h6 8 10 12 14 20H 4 5 7 9 13H2 1 3H3 H 19 21 b8 6 Key YKPUWZUDDOIDPM SOFGYWHQBQSMILES O C NCc1cc OC c O cc1 CCCC C C C C CPropertiesChemical formula C 18H 27N O 3Molar mass 305 418 g mol 1Appearance Crystalline white powder 1 Odor Highly pungentMelting point 62 to 65 C 144 to 149 F 335 to 338 K Boiling point 210 to 220 C 410 to 428 F 483 to 493 K 0 01 TorrSolubility in water 0 0013 g 100 mLSolubility Soluble in alcohol ether benzeneSlightly soluble in CS2 HCl petroleumVapor pressure 1 32 10 8 mm Hg at 25 C 2 UV vis lmax 280 nmStructureCrystal structure MonoclinicPharmacologyATC code M02AB01 WHO N01BX04 WHO License data EU EMA by INNLegal status US only 3 4 HazardsGHS labelling PictogramsSignal word DangerHazard statements H301 H302 H315 H318Precautionary statements P264 P270 P280 P301 P310 P301 P312 P302 P352 P305 P351 P338 P310 P321 P330 P332 P313 P362 P405 P501NFPA 704 fire diamond 210Safety data sheet SDS 2 Except where otherwise noted data are given for materials in their standard state at 25 C 77 F 100 kPa Y verify what is Y N Infobox references CapsaicinHeatAbove peak pure capsaicin is toxic 2 Scoville scale16 000 000 5 SHU Contents 1 Natural function 2 Uses 2 1 Food 2 2 Research and pharmaceutical use 2 3 Pepper spray and pests 2 4 Equestrian sports 3 Irritant effects 3 1 Acute health effects 3 2 Treatment after exposure 3 3 Weight loss and regain 3 4 Peptic ulcer 4 Mechanism of action 5 History 6 Capsaicinoids 7 Biosynthesis 7 1 History 7 2 Biosynthetic pathway 8 Evolution 8 1 Antifungal properties 8 2 Insecticidal properties 8 3 Seed dispersion and deterrents against granivorous mammals 8 4 Adaptation to varying moisture levels 9 See also 10 References 10 1 Notes 11 Further reading 12 External linksNatural function editCapsaicin is present in large quantities in the placental tissue which holds the seeds the internal membranes and to a lesser extent the other fleshy parts of the fruits of plants in the genus Capsicum The seeds themselves do not produce any capsaicin although the highest concentration of capsaicin can be found in the white pith of the inner wall where the seeds are attached 8 The seeds of Capsicum plants are dispersed predominantly by birds In birds the TRPV1 channel does not respond to capsaicin or related chemicals but mammalian TRPV1 is very sensitive to it This is advantageous to the plant as chili pepper seeds consumed by birds pass through the digestive tract and can germinate later whereas mammals have molar teeth which destroy such seeds and prevent them from germinating Thus natural selection may have led to increasing capsaicin production because it makes the plant less likely to be eaten by animals that do not help it disperse 9 There is also evidence that capsaicin may have evolved as an anti fungal agent 10 The fungal pathogen Fusarium which is known to infect wild chilies and thereby reduce seed viability is deterred by capsaicin which thus limits this form of predispersal seed mortality The vanillotoxin containing venom of a certain tarantula species Psalmopoeus cambridgei activates the same pathway of pain as is activated by capsaicin an example of a shared pathway in both plant and animal anti mammalian defense 11 Uses editFood edit Main article Pungency nbsp Curry dishesBecause of the burning sensation caused by capsaicin when it comes in contact with mucous membranes it is commonly used in food products to provide added spiciness or heat piquancy usually in the form of spices such as chili powder and paprika 12 In high concentrations capsaicin will also cause a burning effect on other sensitive areas such as skin or eyes 13 The degree of heat found within a food is often measured on the Scoville scale 12 There has long been a demand for capsaicin spiced products like chili pepper and hot sauces such as Tabasco sauce and Mexican salsa 12 It is common for people to experience pleasurable and even euphoric effects from ingesting capsaicin 12 Folklore among self described chiliheads attribute this to pain stimulated release of endorphins a different mechanism from the local receptor overload that makes capsaicin effective as a topical analgesic 13 Research and pharmaceutical use edit Capsaicin is used as an analgesic in topical ointments and dermal patches to relieve pain typically in concentrations between 0 025 and 0 1 14 It may be applied in cream form for the temporary relief of minor aches and pains of muscles and joints associated with arthritis backache strains and sprains often in compounds with other rubefacients 14 It is also used to reduce the symptoms of peripheral neuropathy such as post herpetic neuralgia caused by shingles 14 A capsaicin transdermal patch Qutenza for the management of this particular therapeutic indication pain due to post herpetic neuralgia was approved in 2009 as a therapeutic by both the U S Food and Drug Administration FDA 15 16 and the European Union 17 A subsequent application to the FDA for Qutenza to be used as an analgesic in HIV neuralgia was refused 18 One 2017 review of clinical studies having limited quality found that high dose topical capsaicin 8 compared with control 0 4 capsaicin provided moderate to substantial pain relief from post herpetic neuralgia HIV neuropathy and diabetic neuropathy 19 Although capsaicin creams have been used to treat psoriasis for reduction of itching 14 20 21 a review of six clinical trials involving topical capsaicin for treatment of pruritus concluded there was insufficient evidence of effect 22 Oral capsaicin decreases LDL cholesterol levels moderately 23 There is insufficient clinical evidence to determine the role of ingested capsaicin on several human disorders including obesity diabetes cancer and cardiovascular diseases 14 Pepper spray and pests edit Capsaicinoids are also an active ingredient in riot control and personal defense pepper spray agents 2 When the spray comes in contact with skin especially eyes or mucous membranes it produces pain and breathing difficulty in the affected individual 2 Capsaicin is also used to deter pests specifically mammalian pests Targets of capsaicin repellants include voles deer rabbits squirrels bears insects and attacking dogs 24 Ground or crushed dried chili pods may be used in birdseed to deter rodents 25 taking advantage of the insensitivity of birds to capsaicin The Elephant Pepper Development Trust claims that using chili peppers as a barrier crop can be a sustainable means for rural African farmers to deter elephants from eating their crops 26 An article published in the Journal of Environmental Science and Health Part B in 2006 states that Although hot chili pepper extract is commonly used as a component of household and garden insect repellent formulas it is not clear that the capsaicinoid elements of the extract are responsible for its repellency 27 The first pesticide product using solely capsaicin as the active ingredient was registered with the U S Department of Agriculture in 1962 24 Equestrian sports edit Capsaicin is a banned substance in equestrian sports because of its hypersensitizing and pain relieving properties 28 At the show jumping events of the 2008 Summer Olympics four horses tested positive for capsaicin which resulted in disqualification 28 Irritant effects editAcute health effects edit Capsaicin is a strong irritant requiring proper protective goggles respirators and proper hazardous material handling procedures Capsaicin takes effect upon skin contact irritant sensitizer eye contact irritant ingestion and inhalation lung irritant lung sensitizer The LD50 in mice is 47 2 mg kg 29 30 Painful exposures to capsaicin containing peppers are among the most common plant related exposures presented to poison centers 31 They cause burning or stinging pain to the skin and if ingested in large amounts by adults or small amounts by children can produce nausea vomiting abdominal pain and burning diarrhea Eye exposure produces intense tearing pain conjunctivitis and blepharospasm 32 Treatment after exposure edit The primary treatment is removal of the offending substance Plain water is ineffective at removing capsaicin 29 Capsaicin is soluble in alcohol which can be used to clean contaminated items 29 When capsaicin is ingested cold milk may be an effective way to relieve the burning sensation due to caseins in milk and the water of milk acts as a surfactant allowing the capsaicin to form an emulsion with it 33 Weight loss and regain edit As of 2007 there was no evidence showing that weight loss is directly correlated with ingesting capsaicin Well designed clinical research had not been performed because the pungency of capsaicin in prescribed doses under research prevented subjects from complying in the study 34 A 2014 meta analysis of further trials found weak evidence that consuming capsaicin before a meal might slightly reduce the amount of food consumed and might drive food preference toward carbohydrates 35 Peptic ulcer edit One 2006 review concluded that capsaicin may relieve symptoms of a peptic ulcer rather than being a cause of it 36 Mechanism of action editThe burning and painful sensations associated with capsaicin result from defunctionalization of nociceptor nerve fibers by causing a topical hypersensitivity reaction in the skin 2 37 As a member of the vanilloid family capsaicin binds to a receptor on nociceptor fibers called the vanilloid receptor subtype 1 TRPV1 37 38 39 TRPV1 which can also be stimulated with heat protons and physical abrasion permits cations to pass through the cell membrane when activated 37 The resulting depolarization of the neuron stimulates it to send impulses to the brain 37 By binding to TRPV1 receptors capsaicin produces similar sensations to those of excessive heat or abrasive damage such as warming tingling itching or stinging explaining why capsaicin is described as an irritant on the skin and eyes or by ingestion 37 Clarifying the mechanisms of capsaicin effects on skin nociceptors was part of awarding the 2021 Nobel Prize in Physiology or Medicine as it led to the discovery of skin sensors for temperature and touch and identification of the single gene causing sensitivity to capsaicin 40 41 History editThe compound was first extracted in impure form in 1816 by Christian Friedrich Bucholz 1770 1818 42 a In 1873 German pharmacologist Rudolf Buchheim 52 53 54 1820 1879 and in 1878 the Hungarian doctor Endre Hogyes 55 56 stated that capsicol partially purified capsaicin 57 caused the burning feeling when in contact with mucous membranes and increased secretion of gastric acid Capsaicinoids editSee also Capsinoids The most commonly occurring capsaicinoids are capsaicin 69 dihydrocapsaicin 22 nordihydrocapsaicin 7 homocapsaicin 1 and homodihydrocapsaicin 1 58 Capsaicin and dihydrocapsaicin both 16 0 million SHU are the most pungent capsaicinoids Nordihydrocapsaicin 9 1 million SHU homocapsaicin and homodihydrocapsaicin both 8 6 million SHU are about half as hot 5 There are six natural capsaicinoids table below Although vanillylamide of n nonanoic acid Nonivamide VNA also PAVA is produced synthetically for most applications it does occur naturally in Capsicum species 59 Capsaicinoid name Abbrev Typical relative amount Scoville heat units Chemical structureCapsaicin C 69 16 000 000 nbsp Dihydrocapsaicin DHC 22 16 000 000 nbsp Nordihydrocapsaicin NDHC 7 9 100 000 nbsp Homocapsaicin HC 1 8 600 000 nbsp Homodihydrocapsaicin HDHC 1 8 600 000 nbsp Nonivamide PAVA 9 200 000 nbsp Biosynthesis edit nbsp Chili peppers nbsp Vanillamine is a product of the phenylpropanoid pathway nbsp Valine enters the branched fatty acid pathway to produce 8 methyl 6 nonenoyl CoA nbsp Capsaicin synthase condenses vanillamine and 8 methyl 6 nonenoyl CoA to produce capsaicin History edit The general biosynthetic pathway of capsaicin and other capsaicinoids was elucidated in the 1960s by Bennett and Kirby and Leete and Louden Radiolabeling studies identified phenylalanine and valine as the precursors to capsaicin 60 61 Enzymes of the phenylpropanoid pathway phenylalanine ammonia lyase PAL cinnamate 4 hydroxylase C4H caffeic acid O methyltransferase COMT and their function in capsaicinoid biosynthesis were identified later by Fujiwake et al 62 63 and Sukrasno and Yeoman 64 Suzuki et al are responsible for identifying leucine as another precursor to the branched chain fatty acid pathway 65 It was discovered in 1999 that pungency of chili peppers is related to higher transcription levels of key enzymes of the phenylpropanoid pathway phenylalanine ammonia lyase cinnamate 4 hydroxylase caffeic acid O methyltransferase Similar studies showed high transcription levels in the placenta of chili peppers with high pungency of genes responsible for branched chain fatty acid pathway 66 Biosynthetic pathway edit Plants exclusively of the genus Capsicum produce capsaicinoids which are alkaloids 67 Capsaicin is believed to be synthesized in the interlocular septum of chili peppers and depends on the gene AT3 which resides at the pun1 locus and which encodes a putative acyltransferase 68 Biosynthesis of the capsaicinoids occurs in the glands of the pepper fruit where capsaicin synthase condenses vanillylamine from the phenylpropanoid pathway with an acyl CoA moiety produced by the branched chain fatty acid pathway 61 69 70 71 Capsaicin is the most abundant capsaicinoid found in the genus Capsicum but at least ten other capsaicinoid variants exist 72 Phenylalanine supplies the precursor to the phenylpropanoid pathway while leucine or valine provide the precursor for the branched chain fatty acid pathway 61 69 To produce capsaicin 8 methyl 6 nonenoyl CoA is produced by the branched chain fatty acid pathway and condensed with vanillylamine Other capsaicinoids are produced by the condensation of vanillylamine with various acyl CoA products from the branched chain fatty acid pathway which is capable of producing a variety of acyl CoA moieties of different chain length and degrees of unsaturation 73 All condensation reactions between the products of the phenylpropanoid and branched chain fatty acid pathway are mediated by capsaicin synthase to produce the final capsaicinoid product 61 69 Evolution editThe Capsicum genus splits from Solanaceae 19 6 million years ago 5 4 million years after the appearance of Solanaceae 74 Chilies only started to quickly evolve in the past 2 million years into markedly different species This evolution can be partially attributed to a key compound found in peppers 8 methyl N vanillyl 6 nonenamide otherwise known as capsaicin Capsaicin evolved similarly across species of chilies that produce capsaicin Its evolution over the course of centuries is due to genetic drift and natural selection across the genus Capsicum Despite the fact that chilies within the Capsicum genus are found throughout the world the capsaicin found within them all exhibit similar properties that serve as defensive and adaptive features Capsaicin evolved to preserve the fitness of peppers against fungi infections insects and granivorous mammals 75 Antifungal properties edit Capsaicin acts as an antifungal agent in four primary ways First capsaicin inhibits the metabolic rate of the cells that make up the fungal biofilm 76 This inhibits the area and growth rate of the fungus since the biofilm creates an area where a fungus can grow and adhere to the chili in which capsaicin is present 77 Capsaicin also inhibits fungal hyphae formation which impacts the amount of nutrients that the rest of the fungal body can receive 78 Thirdly capsaicin disrupts the structure 79 of fungal cells and the fungal cell membranes This has consequential negative impacts on the integrity of fungal cells and their ability to survive and proliferate Additionally the ergosterol synthesis of growing fungi decreases in relation to the amount of capsaicin present in the growth area This impacts the fungal cell membrane and how it is able to reproduce and adapt to stressors in its environment 80 Insecticidal properties edit Capsaicin deters insects in multiple ways The first is by deterring insects from laying their eggs on the pepper due to the effects capsaicin has on these insects 81 Capsaicin can cause intestinal dysplasia upon ingestion disrupting insect metabolism and causing damage to cell membranes within the insect 82 83 This in turn disrupts the standard feeding response of insects Seed dispersion and deterrents against granivorous mammals edit Granivorous mammals pose a risk to the propagation of chilies because their molars grind the seeds of chilies rendering them unable to grow into new chili plants 84 9 As a result modern chilies evolved defense mechanisms to mitigate the risk of granivorous mammals While capsaicin is present at some level in every part of the pepper the chemical has its highest concentration in the tissue near the seeds within chilies 8 Birds are able to eat chilies then disperse the seeds in their excrement enabling propagation 85 Adaptation to varying moisture levels edit Capsaicin is a potent defense mechanism for chilies but it does come at a cost Varying levels of capsaicin in chilies currently appear to be caused by an evolutionary split between surviving in dry environments and having defense mechanisms against fungal growth insects and granivorous mammals 86 Capsaicin synthesis in chilies places a strain on their water resources 87 This directly affects their fitness as it has been observed that standard concentration of capsaicin of peppers in high moisture environments in the seeds and pericarps of the peppers reduced the seeds production by 50 88 See also editAllicin the active piquant flavor chemical in uncooked garlic and to a lesser extent onions see those articles for discussion of other chemicals in them relating to pungency and eye irritation Capsazepine capsaicin antagonist Iodoresiniferatoxin an ultrapotent capsaicin antagonist derived from Resiniferatoxin Naga Viper pepper Bhut Jolokia Pepper Carolina Reaper Trinidad Moruga Scorpion some of the world s most capsaicin rich fruits List of capsaicinoidsReferences edit Capsaicin ChemSpider Royal Society of Chemistry Cambridge UK 2018 Retrieved 9 June 2018 a b c d e f g Capsaicin PubChem US National Library of Medicine 27 May 2023 Retrieved 1 June 2023 Qutenza capsaicin kit DailyMed 10 January 2023 Retrieved 22 February 2023 Drug Approval Package Qutenza capsaicin NDA 022395 U S Food and Drug Administration FDA 3 October 2013 Retrieved 22 February 2023 a b Govindarajan VS Sathyanarayana MN 1991 Capsicum production technology chemistry and quality Part V Impact on physiology pharmacology nutrition and metabolism structure pungency pain and desensitization sequences Critical Reviews in Food Science and Nutrition 29 6 435 474 doi 10 1080 10408399109527536 PMID 2039598 Ritter S Dinh TT June 1990 Capsaicin induced neuronal degeneration in the brain and retina of preweanling rats The Journal of Comparative Neurology 296 3 447 461 doi 10 1002 cne 902960310 PMID 2358547 S2CID 5468197 What Made Chili Peppers So Spicy Talk of the Nation 15 August 2008 a b Chile Information Frequently Asked Questions New Mexico State University College of Agriculture and Home Economics 2005 Archived from the original on 4 May 2007 Retrieved 17 May 2007 a b Tewksbury JJ Nabhan GP July 2001 Seed dispersal Directed deterrence by capsaicin in chilies Nature 412 6845 403 404 doi 10 1038 35086653 PMID 11473305 S2CID 4389051 Tewksbury JJ Reagan KM Machnicki NJ Carlo TA Haak DC Penaloza AL Levey DJ August 2008 Evolutionary ecology of pungency in wild chilies Proceedings of the National Academy of Sciences of the United States of America 105 33 11808 11811 Bibcode 2008PNAS 10511808T doi 10 1073 pnas 0802691105 PMC 2575311 PMID 18695236 Siemens J Zhou S Piskorowski R Nikai T Lumpkin EA Basbaum AI et al November 2006 Spider toxins activate the capsaicin receptor to produce inflammatory pain Nature 444 7116 208 212 Bibcode 2006Natur 444 208S doi 10 1038 nature05285 PMID 17093448 S2CID 4387600 a b c d Gorman J 20 September 2010 A Perk of Our Evolution Pleasure in Pain of Chilies New York Times Retrieved 16 March 2015 a b Rollyson WD Stover CA Brown KC Perry HE Stevenson CD McNees CA et al December 2014 Bioavailability of capsaicin and its implications for drug delivery Journal of Controlled Release 196 96 105 doi 10 1016 j jconrel 2014 09 027 PMC 4267963 PMID 25307998 a b c d e Fattori V Hohmann MS Rossaneis AC Pinho Ribeiro FA Verri WA June 2016 Capsaicin Current Understanding of Its Mechanisms and Therapy of Pain and Other Pre Clinical and Clinical Uses Molecules 21 7 844 doi 10 3390 molecules21070844 PMC 6273101 PMID 27367653 FDA Approves New Drug Treatment for Long Term Pain Relief after Shingles Attacks Press release U S Food and Drug Administration 17 November 2009 Archived from the original on 23 November 2015 Retrieved 5 January 2016 Drug Approval Package Qutenza capsaicin NDA 022395 U S Food and Drug Administration FDA 29 June 2010 Retrieved 19 August 2020 Application Number 22 395 Summary Review PDF FDA Center for Drug Evaluation and Research 13 November 2009 Qutenza EPAR European Medicines Agency EMA 17 September 2018 Retrieved 19 August 2020 Hitt E 9 March 2012 FDA Turns Down Capsaicin Patch for Painful Neuropathy in HIV Medscape Medical News WebMD Retrieved 5 January 2016 Derry S Rice AS Cole P Tan T Moore RA January 2017 Topical capsaicin high concentration for chronic neuropathic pain in adults PDF The Cochrane Database of Systematic Reviews 1 1 CD007393 doi 10 1002 14651858 CD007393 pub4 hdl 10044 1 49554 PMC 6464756 PMID 28085183 Archived from the original PDF on 15 February 2021 Retrieved 27 September 2018 Glinski W Glinska Ferenz M Pierozynska Dubowska M 1991 Neurogenic inflammation induced by capsaicin in patients with psoriasis Acta Dermato Venereologica 71 1 51 54 doi 10 2340 00015555715154 PMID 1711752 S2CID 29307090 Ellis CN Berberian B Sulica VI Dodd WA Jarratt MT Katz HI et al September 1993 A double blind evaluation of topical capsaicin in pruritic psoriasis Journal of the American Academy of Dermatology 29 3 438 442 doi 10 1016 0190 9622 93 70208 B PMID 7688774 Gooding SM Canter PH Coelho HF Boddy K Ernst E August 2010 Systematic review of topical capsaicin in the treatment of pruritus International Journal of Dermatology 49 8 858 865 doi 10 1111 j 1365 4632 2010 04537 x PMID 21128913 S2CID 24484878 Kelava L Nemeth D Hegyi P Keringer P Kovacs DK Balasko M et al April 2021 Dietary supplementation of transient receptor potential vanilloid 1 channel agonists reduces serum total cholesterol level a meta analysis of controlled human trials Critical Reviews in Food Science and Nutrition 62 25 7025 7035 doi 10 1080 10408398 2021 1910138 PMID 33840333 a b R E D Facts for Capsaicin PDF United States Environmental Protection Agency Archived from the original PDF on 24 October 2012 Retrieved 13 November 2012 Jensen PG Curtis PD Dunn JA Austic RE Richmond ME September 2003 Field evaluation of capsaicin as a rodent aversion agent for poultry feed Pest Management Science 59 9 1007 1015 doi 10 1002 ps 705 PMID 12974352 Human Elephant Conflict and Chilli Pepper Elephant Pepper Retrieved 31 May 2019 Antonious GF Meyer JE Snyder JC 2006 Toxicity and repellency of hot pepper extracts to spider mite Tetranychus urticae Koch Journal of Environmental Science and Health Part B Pesticides Food Contaminants and Agricultural Wastes 41 8 1383 1391 Bibcode 2006JESHB 41 1383A doi 10 1080 0360123060096419 PMID 17090499 S2CID 19121573 a b Olympic horses fail drugs tests BBC News Online 21 August 2008 Retrieved 1 April 2010 a b c Capsaicin Material Safety Data Sheet sciencelab com 2007 Archived from the original PDF on 29 September 2007 Retrieved 13 July 2007 Johnson W 2007 Final report on the safety assessment of capsicum annuum extract capsicum annuum fruit extract capsicum annuum resin capsicum annuum fruit powder capsicum frutescens fruit capsicum frutescens fruit extract capsicum frutescens resin and capsaicin International Journal of Toxicology 26 Suppl 1 3 106 doi 10 1080 10915810601163939 PMID 17365137 S2CID 208154058 Krenzelok EP Jacobsen TD August 1997 Plant exposures a national profile of the most common plant genera Veterinary and Human Toxicology 39 4 248 249 PMID 9251180 Goldfrank LR ed 23 March 2007 Goldfrank s Toxicologic Emergencies New York New York McGraw Hill p 1167 ISBN 978 0 07 144310 4 Senese F 23 February 2018 Fire and Spice General Chemistry Online Department of Chemistry Frostburg State University Diepvens K Westerterp KR Westerterp Plantenga MS January 2007 Obesity and thermogenesis related to the consumption of caffeine ephedrine capsaicin and green tea American Journal of Physiology Regulatory Integrative and Comparative Physiology 292 1 R77 R85 doi 10 1152 ajpregu 00832 2005 PMID 16840650 S2CID 7529851 Whiting S Derbyshire EJ Tiwari B February 2014 Could capsaicinoids help to support weight management A systematic review and meta analysis of energy intake data Appetite 73 183 188 doi 10 1016 j appet 2013 11 005 PMID 24246368 S2CID 30252935 Satyanarayana MN 2006 Capsaicin and gastric ulcers Critical Reviews in Food Science and Nutrition 46 4 275 328 doi 10 1080 1040 830491379236 PMID 16621751 S2CID 40023195 a b c d e Capsaicin DrugBank 4 January 2023 Retrieved 1 June 2023 Story GM Crus Orengo L July August 2007 Feel the burn American Scientist 95 4 326 333 doi 10 1511 2007 66 326 Caterina MJ Schumacher MA Tominaga M Rosen TA Levine JD Julius D October 1997 The capsaicin receptor a heat activated ion channel in the pain pathway Nature 389 6653 816 824 Bibcode 1997Natur 389 816C doi 10 1038 39807 PMID 9349813 S2CID 7970319 The Nobel Prize in Physiology or Medicine 2021 Nobel Prize Outreach Retrieved 1 June 2023 Santora M Engelbrecht C 4 October 2021 Nobel Prize Awarded to Scientists for Research About Temperature and Touch The New York Times Bucholz CF 1816 Chemische Untersuchung der trockenen reifen spanischen Pfeffers Chemical investigation of dry ripe Spanish peppers Almanach oder Taschenbuch fur Scheidekunstler und Apotheker Almanac or Pocketbook for Analysts and Apothecaries Vol 37 Weimar pp 1 30 Note Christian Friedrich Bucholz s surname has been variously spelled as Bucholz Bucholtz or Buchholz In a series of articles J C Thresh obtained capsaicin in almost pure form Thresh JC 1876 Isolation of capsaicin The Pharmaceutical Journal and Transactions 3rd Series 6 941 947 Thresh JC 8 July 1876 Capsaicin the active principle in Capsicum fruits The Pharmaceutical Journal and Transactions 3rd Series 7 315 21 Note This article is summarized in Capsaicin the active principle in Capsicum fruits The Analyst 1 8 148 149 1876 Bibcode 1876Ana 1 148 doi 10 1039 an876010148b Year Book of Pharmacy 1876 pages 250 and 543 Thresh JC 1877 Note on Capsaicin Year Book of Pharmacy 24 25 Thresh JC 1877 Report on the active principle of Cayenne pepper Year Book of Pharmacy 485 488 Obituary notice of J C Thresh John Clough Thresh M D D Sc D P H British Medical Journal 1 3726 1057 1058 June 1932 doi 10 1136 bmj 1 3726 1057 c PMC 2521090 PMID 20776886 King J Felter HW Lloys JU 1905 A King s American Dispensatory Eclectic Medical Publications ISBN 1888483024 Micko K 1898 Zur Kenntniss des Capsaicins On our knowledge of capsaicin Zeitschrift fur Untersuchung der Nahrungs und Genussmittel in German 1 12 818 829 doi 10 1007 bf02529190 Micko K 1899 Uber den wirksamen Bestandtheil des Cayennespfeffers On the active component of Cayenne pepper Zeitschrift fur Untersuchung der Nahrungs und Genussmittel in German 2 5 411 412 doi 10 1007 bf02529197 Nelson EK 1919 The constitution of capsaicin the pungent principle of capsicum Journal of the American Chemical Society 41 7 1115 1121 doi 10 1021 ja02228a011 Spath E Darling SF 1930 Synthese des Capsaicins Chem Ber 63B 3 737 743 doi 10 1002 cber 19300630331 Kosuge S Inagaki Y Okumura H 1961 Studies on the pungent principles of red pepper Part VIII On the chemical constitutions of the pungent principles Nippon Nogeikagaku Kaishi Journal of the Agricultural Chemical Society of Japan in Japanese 35 923 927 doi 10 1271 nogeikagaku1924 35 10 923 Kosuge S Inagaki Y 1962 Studies on the pungent principles of red pepper Part XI Determination and contents of the two pungent principles Nippon Nogeikagaku Kaishi Journal of the Agricultural Chemical Society of Japan in Japanese 36 251 doi 10 1271 nogeikagaku1924 36 251 Buchheim R 1873 Uber die scharfen Stoffe On the hot substance Archiv der Heilkunde Archive of Medicine 14 Buchheim R 1872 Fructus Capsici Vierteljahresschrift fur praktische Pharmazie Quarterly Journal for Practical Pharmacy in German 4 507ff Buchheim R 1873 Fructus Capsici Proceedings of the American Pharmaceutical Association 22 106 Hogyes E 1877 Adatok a Capsicum annuum paprika alkatreszeinek elettani hatasahoz Data on the physiological effects of the pepper Capsicum annuum Orvos termeszettudumanyi tarsulatot Ertesitoje ulletin of the Medical Science Association in Hungarian Hogyes A June 1878 Mittheilungen aus dem Institute fur allgemeine Pathologie und Pharmakologie an der Universitat zu Klausenburg Archiv fur experimentelle Pathologie und Pharmakologie 9 1 2 117 130 doi 10 1007 BF02125956 S2CID 32414315 Fluckiger FA 1891 Pharmakognosie des Pflanzenreiches Berlin Germany Gaertner s Verlagsbuchhandlung Bennett DJ Kirby GW 1968 Constitution and biosynthesis of capsaicin J Chem Soc C 442 doi 10 1039 j39680000442 Constant HL Cordell GA West DP April 1996 Nonivamide a Constituent of Capsicum oleoresin Natural Products 59 4 425 426 doi 10 1021 np9600816 Bennett DJ Kirby GW 1968 Constitution and biosynthesis of capsaicin J Chem Soc C 4 442 446 a b c d Leete E Louden MC November 1968 Biosynthesis of capsaicin and dihydrocapsaicin in Capsicum frutescens Journal of the American Chemical Society 90 24 6837 6841 doi 10 1021 ja01026a049 PMID 5687710 Fujiwake H Suzuki T Iwai K November 1982 Intracellular distributions of enzymes and intermediates involved in biosynthesis of capsaicin and its analogues in Capsicum fruits Agricultural and Biological Chemistry 46 11 2685 2689 doi 10 1080 00021369 1982 10865495 Fujiwake H Suzuki T Iwai K October 1982 Capsaicinoid formation in the protoplast from the placenta of Capsicum fruits Agricultural and Biological Chemistry 46 10 2591 2592 doi 10 1080 00021369 1982 10865477 Sukrasno N Yeoman MM 1993 Phenylpropanoid metabolism during growth and development of Capsicum frutescens fruits Phytochemistry 32 4 839 844 Bibcode 1993PChem 32 839S doi 10 1016 0031 9422 93 85217 f Suzuki T Kawada T Iwai K 1981 Formation and metabolism of pungent principle of Capsicum fruits 9 Biosynthesis of acyl moieties of capsaicin and its analogs from valine and leucine in Capsicum fruits Plant amp Cell Physiology 22 23 32 doi 10 1093 oxfordjournals pcp a076142 Curry J Aluru M Mendoza M Nevarez J Melendrez M O Connell MA 1999 Transcripts for possible capsaicinoid biosynthetic genes are differentially accumulated in pungent and non pungent Capsicum spp Plant Sci 148 47 57 doi 10 1016 s0168 9452 99 00118 1 S2CID 86735106 Nelson EK Dawson LE 1923 Constitution of capsaicin the pungent principle of Capsicum III J Am Chem Soc 45 9 2179 2181 doi 10 1021 ja01662a023 Stewart C Kang BC Liu K Mazourek M Moore SL Yoo EY et al June 2005 The Pun1 gene for pungency in pepper encodes a putative acyltransferase The Plant Journal 42 5 675 688 doi 10 1111 j 1365 313X 2005 02410 x PMID 15918882 a b c Bennett DJ Kirby GW 1968 Constitution and biosynthesis of capsaicin J Chem Soc C 1968 442 446 doi 10 1039 j39680000442 Fujiwake H Suzuki T Oka S Iwai K 1980 Enzymatic formation of capsaicinoid from vanillylamine and iso type fatty acids by cell free extracts of Capsicum annuum var annuum cv Karayatsubusa Agricultural and Biological Chemistry 44 12 2907 2912 doi 10 1271 bbb1961 44 2907 Guzman I Bosland PW O Connell MA 2011 Chapter 8 Heat Color and Flavor Compounds in Capsicum Fruit In Gang DR ed Recent Advances in Phytochemistry 41 The Biological Activity of Phytochemicals New York New York Springer pp 117 118 ISBN 9781441972996 Kozukue N Han JS Kozukue E Lee SJ Kim JA Lee KR et al November 2005 Analysis of eight capsaicinoids in peppers and pepper containing foods by high performance liquid chromatography and liquid chromatography mass spectrometry Journal of Agricultural and Food Chemistry 53 23 9172 9181 doi 10 1021 jf050469j PMID 16277419 Thiele R Mueller Seitz E Petz M June 2008 Chili pepper fruits presumed precursors of fatty acids characteristic for capsaicinoids Journal of Agricultural and Food Chemistry 56 11 4219 4224 doi 10 1021 jf073420h PMID 18489121 Yang HJ Chung KR Kwon DY 1 September 2017 DNA sequence analysis tells the truth of the origin propagation and evolution of chili red pepper Journal of Ethnic Foods 4 3 154 162 doi 10 1016 j jef 2017 08 010 ISSN 2352 6181 S2CID 164335348 Tewksbury JJ Reagan KM Machnicki NJ Carlo TA Haak DC Penaloza AL Levey DJ August 2008 Evolutionary ecology of pungency in wild chilies Proceedings of the National Academy of Sciences of the United States of America 105 33 11808 11811 Bibcode 2008PNAS 10511808T doi 10 1073 pnas 0802691105 PMC 2575311 PMID 18695236 Behbehani JM Irshad M Shreaz S Karched M January 2023 Anticandidal Activity of Capsaicin and Its Effect on Ergosterol Biosynthesis and Membrane Integrity of Candida albicans International Journal of Molecular Sciences 24 2 1046 doi 10 3390 ijms24021046 PMC 9860720 PMID 36674560 Costa Orlandi CB Sardi JC Pitangui NS de Oliveira HC Scorzoni L Galeane MC et al May 2017 Fungal Biofilms and Polymicrobial Diseases Journal of Fungi 3 2 22 doi 10 3390 jof3020022 PMC 5715925 PMID 29371540 How fungi are constructed website nbm mnb ca Retrieved 5 May 2023 Yang F Zheng J March 2017 Understand spiciness mechanism of TRPV1 channel activation by capsaicin Protein amp Cell 8 3 169 177 doi 10 1007 s13238 016 0353 7 PMC 5326624 PMID 28044278 Jorda T Puig S July 2020 Regulation of Ergosterol Biosynthesis in Saccharomyces cerevisiae Genes 11 7 795 doi 10 3390 genes11070795 PMC 7397035 PMID 32679672 Li Y Bai P Wei L Kang R Chen L Zhang M et al June 2020 Capsaicin Functions as Drosophila Ovipositional Repellent and Causes Intestinal Dysplasia Scientific Reports 10 1 9963 Bibcode 2020NatSR 10 9963L doi 10 1038 s41598 020 66900 2 PMC 7305228 PMID 32561812 Capsaicin Technical Fact Sheet npic orst edu Retrieved 5 May 2023 Claros Cuadrado JL Pinillos EO Tito R Mirones CS Gamarra Mendoza NN May 2019 Insecticidal Properties of Capsaicinoids and Glucosinolates Extracted from Capsicum chinense and Tropaeolum tuberosum Insects 10 5 132 doi 10 3390 insects10050132 PMC 6572632 PMID 31064092 Levey DJ Tewksbury JJ Cipollini ML Carlo TA November 2006 A field test of the directed deterrence hypothesis in two species of wild chili Oecologia 150 1 61 68 Bibcode 2006Oecol 150 61L doi 10 1007 s00442 006 0496 y PMID 16896774 S2CID 10892233 Tewksbury JJ Nabhan GP 2001 Directed deterrence by capsaicin in chillies Nature 412 6845 403 404 doi 10 1038 35086653 ISSN 0028 0836 PMID 11473305 S2CID 4389051 Haak DC McGinnis LA Levey DJ Tewksbury JJ May 2012 Why are not all chilies hot A trade off limits pungency Proceedings Biological Sciences 279 1735 2012 2017 doi 10 1098 rspb 2011 2091 PMC 3311884 PMID 22189403 Ruiz Lau N Medina Lara F Minero Garcia Y Zamudio Moreno E Guzman Antonio A Echevarria Machado I Martinez Estevez M 1 March 2011 Water Deficit Affects the Accumulation of Capsaicinoids in Fruits of Capsicum chinense Jacq HortScience 46 3 487 492 doi 10 21273 HORTSCI 46 3 487 ISSN 0018 5345 S2CID 86280396 Mahmood T Rana RM Ahmar S Saeed S Gulzar A Khan MA et al June 2021 Effect of Drought Stress on Capsaicin and Antioxidant Contents in Pepper Genotypes at Reproductive Stage Plants 10 7 1286 doi 10 3390 plants10071286 PMC 8309139 PMID 34202853 Notes edit History of early research on capsaicin Felter HW Lloyd JU 1898 King s American Dispensatory Vol 1 Cincinnati Ohio Ohio Valley Co p 435 Du Mez AG 1917 A century of the United States pharmocopoeia 1820 1920 I The galenical oleoresins PhD University of Wisconsin pp 111 132 The results of Bucholz s and Braconnot s analyses of Capsicum annuum appear in Pereira J 1854 The Elements of Materia Medica and Therapeutics Vol 2 3rd US ed Philadelphia Pennsylvania Blanchard and Lea p 506 Biographical information about Christian Friedrich Bucholz is available in Rose HJ 1857 Rose HJ Wright T eds A New General Biographical Dictionary Vol 5 London England p 186 a href Template Cite book html title Template Cite book cite book a CS1 maint location missing publisher link Biographical information about C F Bucholz is also available in German online at Allgemeine Deutsche Biographie Some other early investigators who also extracted the active component of peppers Maurach B 1816 Pharmaceutisch chemische Untersuchung des spanischen Pfeffers Pharmaceutical chemical investigation of Spanish peppers Berlinisches Jahrbuch fur die Pharmacie in German 17 63 73 Abstracts of Maurach s paper appear in i Repertorium fur die Pharmacie vol 6 page 117 119 1819 ii Allgemeine Literatur Zeitung vol 4 no 18 page 146 February 1821 iii Spanischer oder indischer Pfeffer System der Materia medica vol 6 pages 381 386 1821 this reference also contains an abstract of Bucholz s analysis of peppers Henri Braconnot French chemist Braconnot H 1817 Examen chemique du Piment de son principe acre et de celui des plantes de la famille des renonculacees Chemical investigation of the chili pepper of its pungent principle constituent component and of that of plants of the family Ranunculus Annales de Chimie et de Physique in French 6 122 131 Johann Georg Forchhammer Danish geologist Oersted HC 1820 Sur la decouverte de deux nouveaux alcalis vegetaux On the discovery of two new plant alkalis Journal de physique de chemie d histoire naturelle et des arts Journal of Physics Chemistry Natural History and the Arts in French 90 173 174 Ernst Witting German apothecary Witting E 1822 Considerations sur les bases vegetales en general sous le point de vue pharmaceutique et descriptif de deux substances la capsicine et la nicotianine Thoughts on the plant bases in general from a pharmaceutical viewpoint and description of two substances capsicin and nicotine Beitrage fur die Pharmaceutische und Analytische Chemie Contributions to Pharmaceutical and Analytical Chemistry in French 3 43 He called it capsicin after the genus Capsicum from which it was extracted John Clough Thresh 1850 1932 who had isolated capsaicin in almost pure form 43 44 gave it the name capsaicin in 1876 45 Karl Micko isolated capsaicin in its pure form in 1898 46 47 Capsaicin s chemical composition was first determined in 1919 by E K Nelson who also partially elucidated capsaicin s chemical structure 48 Capsaicin was first synthesized in 1930 by Ernst Spath and Stephen F Darling 49 In 1961 similar substances were isolated from chili peppers by the Japanese chemists S Kosuge and Y Inagaki who named them capsaicinoids 50 51 Further reading editAbdel Salam OM 2014 Capsaicin as a Therapeutic Molecule Springer ISBN 978 3 0348 0827 9 External links edit nbsp Wikimedia Commons has media related to Capsaicin nbsp Look up capsaicin in Wiktionary the free dictionary Capsaicin General Fact Sheet National Pesticide Information Center Fire and Spice The molecular basis for flavor Portal nbsp Medicine Retrieved from https en wikipedia org w index php title Capsaicin amp oldid 1207007470, wikipedia, wiki, book, books, library,

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