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Cannabinoids are a class of diverse chemical compounds that act on cannabinoid receptors in cells that repress neurotransmitter release in the brain. Ligands for these receptor proteins include the endocannabinoids (produced naturally in the body by humans and animals),^[1] the phytocannabinoids (found in cannabis and some other plants), and synthetic cannabinoids (manufactured artificially). The most notable cannabinoid is the phytocannabinoid tetrahydrocannabinol (THC), the primary psychoactive compound of cannabis.^[2][3] Cannabidiol (CBD) is another major constituent of the plant.^[4] There are at least 85 different cannabinoids isolated from cannabis, exhibiting varied effects.^[5]

Synthetic cannabinoids encompass a variety of distinct chemical classes: the classical cannabinoids structurally related to THC, the nonclassical cannabinoids (cannabimimetics) including the aminoalkylindoles, 1,5-diarylpyrazoles, quinolines, and arylsulfonamides, as well as eicosanoids related to the endocannabinoids.^[2]

Cannabinoid receptors

Before the 1980s, it was often speculated that cannabinoids produced their physiological and behavioral effects via nonspecific interaction with cell membranes, instead of interacting with specific membrane-bound receptors. The discovery of the first cannabinoid receptors in the 1980s helped to resolve this debate.^[6] These receptors are common in animals, and have been found in mammals, birds, fish, and reptiles. At present, there are two known types of cannabinoid receptors, termed CB₁ and CB₂,^[1] with mounting evidence of more.^[7] The human brain has more cannabinoid receptors than any other G protein-coupled receptor (GPCR) type.^[8]

Cannabinoid receptor type 1

CB₁ receptors are found primarily in the brain, more specifically in the basal ganglia and in the limbic system, including the hippocampus.^[1] They are also found in the cerebellum and in both male and female reproductive systems. CB₁ receptors are absent in the medulla oblongata, the part of the brain stem responsible for respiratory and cardiovascular functions.

Cannabinoid receptor type 2

CB₂ receptors are predominantly found in the immune system, or immune-derived cells^[9] with the greatest density in the spleen. While found only in the peripheral nervous system, a report does indicate that CB₂ is expressed by a subpopulation of microglia in the human cerebellum.^[10] CB₂ receptors appear to be responsible for the anti-inflammatory and possibly other therapeutic effects of cannabis seen in animal models.^[9]

Phytocannabinoids

Type	Skeleton	Cyclization
Cannabigerol-type CBG
Cannabichromene-type CBC
Cannabidiol-type CBD
Tetrahydrocannabinol- and Cannabinol-type THC, CBN
Cannabielsoin-type CBE
iso- Tetrahydrocannabinol- type iso-THC
Cannabicyclol-type CBL
Cannabicitran-type CBT
Main classes of natural cannabinoids

Cannabis-derived cannabinoids

The classical cannabinoids are concentrated in a viscous resin produced in structures known as glandular trichomes. At least 85 different cannabinoids have been isolated from the Cannabis plant^[5] To the right, the main classes of cannabinoids from Cannabis are shown. The best studied cannabinoids include tetrahydrocannabinol (THC), cannabidiol (CBD) and cannabinol (CBN).

Types

All classes derive from cannabigerol-type compounds and differ mainly in the way this precursor is cyclized.^[11] The classical cannabinoids are derived from their respective 2-carboxylic acids (2-COOH) by decarboxylation (catalyzed by heat, light, or alkaline conditions).^[12]

• CBG (Cannabigerol)
• CBC (Cannabichromene)
• CBL (Cannabicyclol)
• CBV (Cannabivarin)
• THCV (Tetrahydrocannabivarin)
• CBDV (Cannabidivarin)
• CBCV (Cannabichromevarin)
• CBGV (Cannabigerovarin)
• CBGM (Cannabigerol Monomethyl Ether)

Tetrahydrocannabinol

Tetrahydrocannabinol (THC) is the primary psychoactive component of the Cannabis plant. Delta-9-tetrahydrocannabinol (Δ⁹-THC, THC) and delta-8-tetrahydrocannabinol (Δ⁸-THC), mimic the action of anandamide, a neurotransmitter produced naturally in the body. These two cannabinoids produce the effects associated with cannabis by binding to the CB₁ cannabinoid receptors in the brain.

Cannabidiol

Cannabidiol (CBD) is non-psychotropic. Recent evidence shows that the compound counteracts cognitive impairment associated with the use of cannabis.^[13] Cannabidiol has little affinity for CB₁ and CB₂ receptors but acts as an indirect antagonist of cannabinoid agonists.^[14] It was found to be an antagonist at the putative new cannabinoid receptor, GPR55, a GPCR expressed in the caudate nucleus and putamen.^[15] Cannabidiol has also been shown to act as a 5-HT_1A receptor agonist.^[16]

It appears to relieve convulsion, inflammation, anxiety, and nausea in animal studies.^[14] CBD has shown antitumor activity on human breast carcinoma by inhibiting cancer cell growth. At slightly higher concentrations it is cytotoxic to normal cells^[17] CBD has a greater affinity for the CB₂ receptor than for the CB₁ receptor.^[14]

CBD shares a precursor with THC and is the main cannabinoid in low-THC Cannabis strains. CBD has been shown to play a role in preventing the short-term memory loss associated with THC.^[18]

A 2014 Cochrane review concluded that there was insufficient evidence to conclude that cannabidiol has an anti-psychotic effect.^[19] A 2015 systematic review found CBD to be effective as an antipsychotic compound, and may lower the risk for developing cannabis-related psychosis. Trials indicated it was safe and well tolerated.^[13]

Cannabinol

Cannabinol (CBN) is the primary product of THC degradation, and there is usually little of it in a fresh plant. CBN content increases as THC degrades in storage, and with exposure to light and air. It is only mildly psychoactive. Its affinity to the CB₂ receptor is higher than for the CB₁ receptor.^[20]

Cannabigerol

Cannabigerol (CBG) is non-psychoactive but still affects the overall effects of Cannabis. CBG has been shown to promote apoptosis in cancer cells and inhibit tumor growth in mice.^[21] It acts as an α₂-adrenergic receptor agonist, 5-HT_1A receptor antagonist, and CB₁ receptor antagonist.^[22] It also binds to the CB₂ receptor.^[22]

Tetrahydrocannabivarin

Tetrahydrocannabivarin (THCV) is prevalent in certain central Asian and southern African strains of Cannabis.^[23][24] It is an antagonist of THC at CB₁ receptors and attenuates the psychoactive effects of THC.^[25]

Cannabidivarin

Although cannabidivarin (CBDV) is usually a minor constituent of the cannabinoid profile, enhanced levels of CBDV have been reported in feral cannabis plants from the northwest Himalayas, and in hashish from Nepal.^[24][26]

Cannabichromene

Cannabichromene (CBC) is non-psychoactive and does not affect the psychoactivity of THC.^[27] CBC has shown antitumor effects in breast cancer xenoplants in mice.^[28] More common in tropical cannabis varieties.

Biosynthesis

Cannabinoid production starts when an enzyme causes geranyl pyrophosphate and olivetolic acid to combine and form CBGA. Next, CBGA is independently converted to either CBG, THCA, CBDA or CBCA by four separate synthase, FAD-dependent dehydrogenase enzymes. There is no evidence for enzymatic conversion of CBDA or CBD to THCA or THC. For the propyl homologues (THCVA, CBDVA and CBCVA), there is an analogous pathway that is based on CBGVA from divarinolic acid instead of olivetolic acid.

Double bond position

In addition, each of the compounds above may be in different forms depending on the position of the double bond in the alicyclic carbon ring. There is potential for confusion because there are different numbering systems used to describe the position of this double bond. Under the dibenzopyran numbering system widely used today, the major form of THC is called Δ⁹-THC, while the minor form is called Δ⁸-THC. Under the alternate terpene numbering system, these same compounds are called Δ¹-THC and Δ⁶-THC, respectively.

Length

Most classical cannabinoids are 21-carbon compounds. However, some do not follow this rule, primarily because of variation in the length of the side-chain attached to the aromatic ring. In THC, CBD, and CBN, this side-chain is a pentyl (5-carbon) chain. In the most common homologue, the pentyl chain is replaced with a propyl (3-carbon) chain. Cannabinoids with the propyl side-chain are named using the suffix varin, and are designated, for example, THCV, CBDV, or CBNV.

Cannabinoids in other plants

Phytocannabinoids are known to occur in several plant species besides cannabis. These include Echinacea purpurea, Echinacea angustifolia, Echinacea pallida, Acmella oleracea, Helichrysum umbraculigerum, and Radula marginata.^[29] The best-known cannabinoids that are not derived from Cannabis are the lipophilic alkamides (alkylamides) from Echinacea species, most notably the cis/trans isomers dodeca-2E,4E,8Z,10E/Z-tetraenoic-acid-isobutylamide.^[29] At least 25 different alkylamides have been identified, and some of them have shown affinities to the CB₂-receptor.^[30][31] In Echinacea species, cannabinoids are found throughout the plant structure, but are most concentrated in the roots and flowers.^[32][33] Yangonin found in the Kava plant a ligand to the CB1 receptor.^[34] Tea (Camellia sinensis) catechins have an affinity for human cannabinoid receptors.^[35] A widespread dietary terpene, beta-caryophyllene, a component from the essential oil of cannabis and other medicinal plants, has also been identified as a selective agonist of peripheral CB₂-receptors, in vivo.^[36] Black truffles contain anandamide.^[37]

Most of the phytocannabinoids are nearly insoluble in water but are soluble in lipids, alcohols, and other non-polar organic solvents.

Cannabis plant profile

Cannabis plants can exhibit wide variation in the quantity and type of cannabinoids they produce. The mixture of cannabinoids produced by a plant is known as the plant's cannabinoid profile. Selective breeding has been used to control the genetics of plants and modify the cannabinoid profile. For example, strains that are used as fiber (commonly called hemp) are bred such that they are low in psychoactive chemicals like THC. Strains used in medicine are often bred for high CBD content, and strains used for recreational purposes are usually bred for high THC content or for a specific chemical balance.

Quantitative analysis of a plant's cannabinoid profile is often determined by gas chromatography (GC), or more reliably by gas chromatography combined with mass spectrometry (GC/MS). Liquid chromatography (LC) techniques are also possible and, unlike GC methods, can differentiate between the acid and neutral forms of the cannabinoids. There have been systematic attempts to monitor the cannabinoid profile of cannabis over time, but their accuracy is impeded by the illegal status of the plant in many countries.

Pharmacology

Cannabinoids can be administered by smoking, vaporizing, oral ingestion, transdermal patch, intravenous injection, sublingual absorption, or rectal suppository. Once in the body, most cannabinoids are metabolized in the liver, especially by cytochrome P450 mixed-function oxidases, mainly CYP 2C9.^{[medical citation needed]} Thus supplementing with CYP 2C9 inhibitors leads to extended intoxication.^{[medical citation needed]}

Some is also stored in fat in addition to being metabolized in the liver. Δ⁹-THC is metabolized to 11-hydroxy-Δ⁹-THC, which is then metabolized to 9-carboxy-THC. Some cannabis metabolites can be detected in the body several weeks after administration. These metabolites are the chemicals recognized by common antibody-based "drug tests"; in the case of THC or others, these loads do not represent intoxication (compare to ethanol breath tests that measure instantaneous blood alcohol levels), but an integration of past consumption over an approximately month-long window. This is because they are fat-soluble, lipophilic molecules that accumulate in fatty tissues.^[38]

Separation

Cannabinoids can be separated from the plant by extraction with organic solvents. Hydrocarbons and alcohols are often used as solvents. However, these solvents are flammable and many are toxic. Butane may be used, which evaporates extremely quickly. Supercritical solvent extraction with carbon dioxide is an alternative technique. Although this process requires high pressures (73 atmospheres or more), there is minimal risk of fire or toxicity, solvent removal is simple and efficient, and extract quality can be well controlled. Once extracted, cannabinoid blends can be separated into individual components using wiped film vacuum distillation or other distillation techniques. However, to produce high-purity cannabinoids, chemical synthesis or semisynthesis is generally required.

History

Cannabinoids were first discovered in the 1940s, when CBD and CBN were identified. The structure of THC was first determined in 1964.^{[citation needed]}

Due to molecular similarity and ease of synthetic conversion, CBD was originally believed to be a natural precursor to THC. However, it is now known that CBD and THC are produced independently in the cannabis plant from the precursor CBG.^{[citation needed]}

Endocannabinoids are substances produced from within the body that activate cannabinoid receptors. After the discovery of the first cannabinoid receptor in 1988, scientists began searching for an endogenous ligand for the receptor.^[6][39]

Types of endocannabinoid ligands

Arachidonoylethanolamine (Anandamide or AEA)

In 1992, in Raphael Mechoulam's lab, the first such compound was identified as arachidonoyl ethanolamine and named anandamide, a name derived from the Sanskrit word for bliss and -amide. Anandamide is derived from arachidonic acid. It has a pharmacology similar to THC, although its chemical structure is different. Anandamide binds to the central (CB₁) and, to a lesser extent, peripheral (CB₂) cannabinoid receptors, where it acts as a partial agonist. Anandamide is about as potent as THC at the CB₁ receptor.^[40] Anandamide is found in nearly all tissues in a wide range of animals.^[41] Anandamide has also been found in plants, including small amounts in chocolate.^[42]

Two analogs of anandamide, 7,10,13,16-docosatetraenoylethanolamide and homo-γ-linolenoylethanolamine, have similar pharmacology. All of these are members of a family of signalling lipids called N-acylethanolamines, which also includes the noncannabimimetic palmitoylethanolamide and oleoylethanolamide, which possess anti-inflammatory and orexigenic effects, respectively. Many N-acylethanolamines have also been identified in plant seeds^[43] and in molluscs.^[44]

2-Arachidonoylglycerol (2-AG)

Another endocannabinoid, 2-arachidonoylglycerol, binds to both the CB₁ and CB₂ receptors with similar affinity, acting as a full agonist at both.^[40] 2-AG is present at significantly higher concentrations in the brain than anandamide,^[45] and there is some controversy over whether 2-AG rather than anandamide is chiefly responsible for endocannabinoid signalling in vivo.^[1] In particular, one in vitro study suggests that 2-AG is capable of stimulating higher G-protein activation than anandamide, although the physiological implications of this finding are not yet known.^[46]

2-Arachidonyl glyceryl ether (noladin ether)

In 2001, a third, ether-type endocannabinoid, 2-arachidonyl glyceryl ether (noladin ether), was isolated from porcine brain.^[47] Prior to this discovery, it had been synthesized as a stable analog of 2-AG; indeed, some controversy remains over its classification as an endocannabinoid, as another group failed to detect the substance at "any appreciable amount" in the brains of several different mammalian species.^[48] It binds to the CB₁ cannabinoid receptor (K_i = 21.2 nmol/L) and causes sedation, hypothermia, intestinal immobility, and mild antinociception in mice. It binds primarily to the CB₁ receptor, and only weakly to the CB₂ receptor.^[40]

N-Arachidonoyl dopamine (NADA)

Discovered in 2000, NADA preferentially binds to the CB₁ receptor.^[49] Like anandamide, NADA is also an agonist for the vanilloid receptor subtype 1 (TRPV1), a member of the vanilloid receptor family.^[50][51]

Virodhamine (OAE)

A fifth endocannabinoid, virodhamine, or O-arachidonoyl-ethanolamine (OAE), was discovered in June 2002. Although it is a full agonist at CB₂ and a partial agonist at CB₁, it behaves as a CB₁ antagonist in vivo. In rats, virodhamine was found to be present at comparable or slightly lower concentrations than anandamide in the brain, but 2- to 9-fold higher concentrations peripherally.^[52]

Lysophosphatidylinositol (LPI)

Recent evidence has highlighted lysophosphatidylinositol as the endogenous ligand to novel endocannabinoid receptor GPR55, making it a strong contender as the sixth endocannabinoid.^[53]

Function

Endocannabinoids serve as intercellular 'lipid messengers', signaling molecules that are released from one cell and activating the cannabinoid receptors present on other nearby cells. Although in this intercellular signaling role they are similar to the well-known monoamine neurotransmitters, such as acetylcholine and dopamine, endocannabinoids differ in numerous ways from them. For instance, they are used in retrograde signaling between neurons. Furthermore, endocannabinoids are lipophilic molecules that are not very soluble in water. They are not stored in vesicles, and exist as integral constituents of the membrane bilayers that make up cells. They are believed to be synthesized 'on-demand' rather than made and stored for later use. The mechanisms and enzymes underlying the biosynthesis of endocannabinoids remain elusive and continue to be an area of active research.

The endocannabinoid 2-AG has been found in bovine and human maternal milk.^[54]

Retrograde signal

Conventional neurotransmitters are released from a ‘presynaptic’ cell and activate appropriate receptors on a ‘postsynaptic’ cell, where presynaptic and postsynaptic designate the sending and receiving sides of a synapse, respectively. Endocannabinoids, on the other hand, are described as retrograde transmitters because they most commonly travel ‘backward’ against the usual synaptic transmitter flow. They are, in effect, released from the postsynaptic cell and act on the presynaptic cell, where the target receptors are densely concentrated on axonal terminals in the zones from which conventional neurotransmitters are released. Activation of cannabinoid receptors temporarily reduces the amount of conventional neurotransmitter released. This endocannabinoid mediated system permits the postsynaptic cell to control its own incoming synaptic traffic. The ultimate effect on the endocannabinoid-releasing cell depends on the nature of the conventional transmitter being controlled. For instance, when the release of the inhibitory transmitter GABA is reduced, the net effect is an increase in the excitability of the endocannabinoid-releasing cell. On the converse, when release of the excitatory neurotransmitter glutamate is reduced, the net effect is a decrease in the excitability of the endocannabinoid-releasing cell.^{[citation needed]}

Range

Endocannabinoids are hydrophobic molecules. They cannot travel unaided for long distances in the aqueous medium surrounding the cells from which they are released, and therefore act locally on nearby target cells. Hence, although emanating diffusely from their source cells, they have much more restricted spheres of influence than do hormones, which can affect cells throughout the body.^{[citation needed]}

Synthetic cannabinoids

Historically, laboratory synthesis of cannabinoids were often based on the structure of herbal cannabinoids, and a large number of analogs have been produced and tested, especially in a group led by Roger Adams as early as 1941 and later in a group led by Raphael Mechoulam. Newer compounds are no longer related to natural cannabinoids or are based on the structure of the endogenous cannabinoids.^{[citation needed]}

Synthetic cannabinoids are particularly useful in experiments to determine the relationship between the structure and activity of cannabinoid compounds, by making systematic, incremental modifications of cannabinoid molecules.^{[citation needed]}

When synthetic cannabinoids are used recreationally, they present significant health dangers to users.^[55] In the period of 2012 through 2014, over 10,000 contacts to poison control centers in the United States were related to use of synthetic cannabinoids.^[55]

Medications containing natural or synthetic cannabinoids or cannabinoid analogs:

• Dronabinol (Marinol), is Δ⁹-tetrahydrocannabinol (THC), used as an appetite stimulant, anti-emetic, and analgesic
• Nabilone (Cesamet, Canemes), a synthetic cannabinoid and an analog of Marinol. It is Schedule II unlike Marinol, which is Schedule III
• Rimonabant (SR141716), a selective cannabinoid (CB₁) receptor inverse agonist once used as an anti-obesity drug under the proprietary name Acomplia. It was also used for smoking cessation

Other notable^[why?] synthetic cannabinoids include:

• JWH-018, a potent synthetic cannabinoid agonist discovered by John W. Huffman at Clemson University. It is being increasingly sold in legal smoke blends collectively known as "spice". Several countries and states have moved to ban it legally.
• JWH-073
• CP-55940, produced in 1974, this synthetic cannabinoid receptor agonist is many times more potent than THC.
• Dimethylheptylpyran
• HU-210, about 100 times as potent as THC^[56]
• HU-331 a potential anti-cancer drug derived from cannabidiol that specifically inhibits topoisomerase II.
• SR144528, a CB₂ receptor antagonist
• WIN 55,212-2, a potent cannabinoid receptor agonist
• JWH-133, a potent selective CB₂ receptor agonist
• Levonantradol (Nantrodolum), an anti-emetic and analgesic but not currently in use in medicine
• AM-2201, a potent cannabinoid receptor agonist

Table of plant cannabinoids

Table of plant cannabinoids

Cannabigerol-type (CBG)
Cannabigerol (E)-CBG-C5	Cannabigerol monomethyl ether (E)-CBGM-C5 A	Cannabinerolic acid A (Z)-CBGA-C5 A	Cannabigerovarin (E)-CBGV-C3
Cannabigerolic acid A (E)-CBGA-C5 A	Cannabigerolic acid A monomethyl ether (E)-CBGAM-C5 A		Cannabigerovarinic acid A (E)-CBGVA-C3 A
Cannabichromene-type (CBC)
(±)-Cannabichromene CBC-C5	(±)-Cannabichromenic acid A CBCA-C5 A	(±)-Cannabivarichromene, (±)-Cannabichromevarin CBCV-C3	(±)-Cannabichromevarinic acid A CBCVA-C3 A
Cannabidiol-type (CBD)
(−)-Cannabidiol CBD-C5	Cannabidiol momomethyl ether CBDM-C5	Cannabidiol-C4 CBD-C4	(−)-Cannabidivarin CBDV-C3	Cannabidiorcol CBD-C1
Cannabidiolic acid CBDA-C5			Cannabidivarinic acid CBDVA-C3
Cannabinodiol-type (CBND)
Cannabinodiol CBND-C5	Cannabinodivarin CBND-C3
Tetrahydrocannabinol-type (THC)
Δ9-Tetrahydrocannabinol Δ9-THC-C5		Δ9-Tetrahydrocannabinol-C4 Δ9-THC-C4	Δ9-Tetrahydrocannabivarin Δ9-THCV-C3	Δ9-Tetrahydrocannabiorcol Δ9-THCO-C1
Δ9-Tetrahydro- cannabinolic acid A Δ9-THCA-C5 A	Δ9-Tetrahydro- cannabinolic acid B Δ9-THCA-C5 B	Δ9-Tetrahydro- cannabinolic acid-C4 A and/or B Δ9-THCA-C4 A and/or B	Δ9-Tetrahydro- cannabivarinic acid A Δ9-THCVA-C3 A	Δ9-Tetrahydro- cannabiorcolic acid A and/or B Δ9-THCOA-C1 A and/or B
(−)-Δ8-trans-(6aR,10aR)- Δ8-Tetrahydrocannabinol Δ8-THC-C5	(−)-Δ8-trans-(6aR,10aR)- Tetrahydrocannabinolic acid A Δ8-THCA-C5 A	(−)-(6aS,10aR)-Δ9- Tetrahydrocannabinol (−)-cis-Δ9-THC-C5
Cannabinol-type (CBN)
Cannabinol CBN-C5	Cannabinol-C4 CBN-C4	Cannabivarin CBN-C3	Cannabinol-C2 CBN-C2	Cannabiorcol CBN-C1
Cannabinolic acid A CBNA-C5 A	Cannabinol methyl ether CBNM-C5
Cannabitriol-type (CBT)
(−)-(9R,10R)-trans- Cannabitriol (−)-trans-CBT-C5	(+)-(9S,10S)-Cannabitriol (+)-trans-CBT-C5	(±)-(9R,10S/9S,10R)- Cannabitriol (±)-cis-CBT-C5	(−)-(9R,10R)-trans- 10-O-Ethyl-cannabitriol (−)-trans-CBT-OEt-C5	(±)-(9R,10R/9S,10S)- Cannabitriol-C3 (±)-trans-CBT-C3
8,9-Dihydroxy-Δ6a(10a)- tetrahydrocannabinol 8,9-Di-OH-CBT-C5	Cannabidiolic acid A cannabitriol ester CBDA-C5 9-OH-CBT-C5 ester	(−)-(6aR,9S,10S,10aR)- 9,10-Dihydroxy- hexahydrocannabinol, Cannabiripsol Cannabiripsol-C5	(−)-6a,7,10a-Trihydroxy- Δ9-tetrahydrocannabinol (−)-Cannabitetrol	10-Oxo-Δ6a(10a)- tetrahydrocannabinol OTHC
Cannabielsoin-type (CBE)
(5aS,6S,9R,9aR)- Cannabielsoin CBE-C5		(5aS,6S,9R,9aR)- C3-Cannabielsoin CBE-C3
(5aS,6S,9R,9aR)- Cannabielsoic acid A CBEA-C5 A	(5aS,6S,9R,9aR)- Cannabielsoic acid B CBEA-C5 B	(5aS,6S,9R,9aR)- C3-Cannabielsoic acid B CBEA-C3 B
Cannabiglendol-C3 OH-iso-HHCV-C3	Dehydrocannabifuran DCBF-C5	Cannabifuran CBF-C5
Isocannabinoids
(−)-Δ7-trans-(1R,3R,6R)- Isotetrahydrocannabinol	(±)-Δ7-1,2-cis- (1R,3R,6S/1S,3S,6R)- Isotetrahydro- cannabivarin	(−)-Δ7-trans-(1R,3R,6R)- Isotetrahydrocannabivarin
Cannabicyclol-type (CBL)
(±)-(1aS,3aR,8bR,8cR)- Cannabicyclol CBL-C5	(±)-(1aS,3aR,8bR,8cR)- Cannabicyclolic acid A CBLA-C5 A	(±)-(1aS,3aR,8bR,8cR)- Cannabicyclovarin CBLV-C3
Cannabicitran-type (CBT)
Cannabicitran CBT-C5
Cannabichromanone-type (CBCN)
Cannabichromanone CBCN-C5	Cannabichromanone-C3 CBCN-C3	Cannabicoumaronone CBCON-C5

See also

• Cannabinoid receptor antagonist
• Cancer and nausea

References

Further reading

This article's further reading may not follow Wikipedia's content policies or guidelines. Please improve this article by removing excessive, less relevant or many publications with the same point of view; or by incorporating the relevant publications into the body of the article through appropriate citations. (January 2014)

• De Meijer, EP; Bagatta, M; Carboni, A; Crucitti, P; Moliterni, VM; Ranalli, P; et al. (2003). "The inheritance of chemical phenotype in Cannabis sativa L". Genetics 163 (1): 335–46. PMC 1462421. PMID 12586720. 
• Devane, W.; Hanus, L; Breuer, A; Pertwee, R.; Stevenson, L.; Griffin, G; et al. (1992). "Isolation and structure of a brain constituent that binds to the cannabinoid receptor". Science 258 (5090): 1946–9. Bibcode:1992Sci...258.1946D. doi:10.1126/science.1470919. PMID 1470919. 
• Elsohly, Mahmoud A.; Slade, Desmond (2005). "Chemical constituents of marijuana: The complex mixture of natural cannabinoids". Life Sciences 78 (5): 539–48. doi:10.1016/j.lfs.2005.09.011. PMID 16199061. 
• Hanus, Lumir; Gopher, Asher; Almog, Shlomo; Mechoulam, Raphael (1993). "Two new unsaturated fatty acid ethanolamides in brain that bind to the cannabinoid receptor". Journal of Medicinal Chemistry 36 (20): 3032–4. doi:10.1021/jm00072a026. PMID 8411021. 
• Hanus, L (1987). "Biogenesis of cannabinoid substances in the plant". Acta Universitatis Palackianae Olomucensis Facultatis Medicae 116: 47–53. PMID 2962461. 
• Hanuš, L.; Krejčí, Z. (1975). "Isolation of two new cannabinoid acids from Cannabis sativa L. of Czechoslovak origin". Acta Univ. Olomuc., Fac. Med 74: 161–166. 
• Hanuš, L.; Krejčí, Z.; Hruban, L. (1975). "Isolation of cannabidiolic acid from Turkish variety of cannabis cultivated for fibre". Acta Univ. Olomuc., Fac. Med 74: 167–172. 
• Köfalvi, Attila, ed. (2008). "Cannabinoids and the Brain". doi:10.1007/978-0-387-74349-3. ISBN 978-0-387-74348-6. 
• Mechoulam, Raphael; Ben-Shabat, Shimon; Hanus, Lumir; Ligumsky, Moshe; Kaminski, Norbert E.; Schatz, Anthony R.; et al. (1995). "Identification of an endogenous 2-monoglyceride, present in canine gut, that binds to cannabinoid receptors". Biochemical Pharmacology 50 (1): 83–90. doi:10.1016/0006-2952(95)00109-D. PMID 7605349. 
• Nicoll, Roger A.; Alger, Bradley E. (2004). "The Brain's Own Marijuana". Scientific American 291 (6): 68–75. doi:10.1038/scientificamerican1204-68. PMID 15597982. 
• Racz, I.; Nadal, X.; Alferink, J.; Baños, J. E.; Rehnelt, J.; Martín, M.; et al. (2008). "Interferon-  is a Critical Modulator of CB2 Cannabinoid Receptor Signaling during Neuropathic Pain". Journal of Neuroscience 28 (46): 12136–45. doi:10.1523/JNEUROSCI.3402-08.2008. PMC 3844840. PMID 19005078. 
• Racz, I.; Nadal, X.; Alferink, J.; Baños, J. E.; Rehnelt, J.; Martín, M.; et al. (2008). "Crucial Role of CB2 Cannabinoid Receptor in the Regulation of Central Immune Responses during Neuropathic Pain". Journal of Neuroscience 28 (46): 12125–35. doi:10.1523/JNEUROSCI.3400-08.2008. PMC 3844839. PMID 19005077. 
• Turner, C. E.; Mole, M. L.; Hanus, L.; Elsohly, H. N. (1981). "Constituents of Cannabis sativa. XIX. Isolation and Structure Elucidation of Cannabiglendol, A Novel Cannabinoid from an Indian Variant". Journal of Natural Products 44 (1): 27–33. doi:10.1021/np50013a005. 

v t e Cannabinoids Phytocannabinoids Alkylamides Caryophyllene CBC CBCV CBD CBDV CBG CBGM CBGV CBL CBN CBV Epigallocatechin gallate Gallocatechol Perrottetinene Serinolamide A THC THC-C4 THCA THCV Yangonin Cannabinoid metabolites 8,11-DiOH-THC 11-COOH-THC 11-OH-THC Endogenous cannabinoids Arachidonoyl ethanolamide (Anandamide or AEA) 2-Arachidonoylglycerol (2-AG) 2-Arachidonyl glyceryl ether (noladin ether) N-Arachidonoyl dopamine (NADA) Oleamide RVD-Hpα Virodhamine Synthetic cannabinoid receptor agonists Classical cannabinoids (Dibenzopyrans) A-40174 A-41988 A-42574 Ajulemic acid AM-087 AM-411 AM-855 AM-905 AM-906 AM-919 AM-926 AM-938 AM-2389 AM-4030 AMG-1 AMG-3 AMG-36 AMG-41 Dexanabinol (HU-211) DMHP Dronabinol HHC HU-210 HU-243 JWH-051 JWH-133 JWH-139 JWH-161 JWH-229 JWH-359 KM-233 L-759,633 L-759,656 Levonantradol (CP 50,5561) Menabitan Nabazenil Nabidrox (Canbisol) Nabilone Nabitan Naboctate O-224 O-581 O-774 O-806 O-823 O-1057 O-1125 O-1191 O-1238 O-2048 O-2113 O-2365 O-2372 O-2373 O-2383 O-2426 O-2484 O-2545 O-2694 O-2715 O-2716 O-3223 O-3226 Parahexyl Pirnabine THC-O-acetate THC-O-phosphate Nonclassical cannabinoids Cannabicyclohexanol CP 47,497 (C6)-CP 47,497 (C9)-CP 47,497 CP 55,244 CP 55,940 HU-308 HU-320 HU-331 HU-336 HU-345 HU-910 Nonabine O-1376 O-1422 O-1601 O-1656 O-1657 O-1660 O-1871 SPA-229 Tinabinol 2-Isopropyl-5-methyl-1- (2,6-dihydroxy-4-nonylphenyl)cyclohex-1-ene Benzoylindoles 1-Butyl-3-(2-methoxybenzoyl)indole 1-Butyl-3-(4-methoxybenzoyl)indole 1-Pentyl-3-(2-methoxybenzoyl)indole AM-630 AM-679 AM-694 AM-1241 AM-2233 GW-405,833 (L-768,242) Pravadoline RCS-4 WIN 54,461 Naphthoylindoles AM-1220 AM-1221 AM-1235 AM-2201 AM-2232 EAM-2201 FUB-JWH-018 JWH-007 JWH-015 JWH-018 JWH-019 JWH-073 JWH-081 JWH-098 JWH-116 JWH-122 JWH-149 JWH-164 JWH-182 JWH-193 JWH-198 JWH-200 JWH-210 JWH-398 JWH-424 MAM-2201 NM-2201 Naphthoylindazoles THJ-018 THJ-2201 Pyrrolobenzoxazines WIN 55,212-2 Naphthylmethylindoles JWH-175 JWH-176 JWH-184 JWH-185 JWH-192 JWH-194 JWH-195 JWH-196 JWH-197 JWH-199 Phenylacetylindoles Cannabipiperidiethanone JWH-167 JWH-203 JWH-249 JWH-250 JWH-251 JWH-302 RCS-8 Indole-3-carboxamides 5F-ADBICA 5F-NNE1 5F-PCN 5F-SDB-006 AB-FUBICA AB-PICA ADBICA ADB-FUBICA APICA CUMYL-BICA CUMYL-PICA CUMYL-5F-PICA FDU-NNE1 MDMB-CHMICA MMB-2201 NNE1 PX-1 Org 28312 Org 28611 SDB-006 STS-135 UR-12 (MN-25) Indole-3-carboxylates 5F-PB-22 FDU-PB-22 FUB-PB-22 QUCHIC (BB-22) QUPIC (PB-22) Tetramethylcyclopropanoylindoles 5Br-UR-144 5Cl-UR-144 A-796,260 A-834,735 FUB-144 UR-144 XLR-11 XLR-12 Indazole-3-carboxamides 5Cl-APINACA 5F-ADB 5F-ADB-PINACA 5F-AMB 5F-APINACA 5F-CUMYL-PINACA 5F-EMB-PINACA AB-CHMINACA AB-FUBINACA AB-FUBINACA 2-fluorobenzyl isomer AB-PINACA ADB-CHMINACA ADB-FUBINACA ADB-PINACA ADAMANTYL-THPINACA ADSB-FUB-187 AMB-CHMINACA AMB-FUBINACA APINACA (AKB48) APP-FUBINACA CUMYL-PINACA CUMYL-THPINACA EMB-FUBINACA FUB-APINACA MDMB-FUBINACA MDMB-CHMINACA MN-18 PX-2 PX-3 Tetramethylcyclopropanoylindazoles FAB-144 Naphthoylpyrroles JWH-030 JWH-147 JWH-307 JWH-369 JWH-370 Eicosanoids AM-883 AM-1346 ACEA ACPA Methanandamide (AM-356) O-585 O-689 O-1812 O-1860 O-1861 Pyrazolecarboxamides 5F-AB-FUPPYCA AB-CHFUPYCA AB-CHMFUPPYCA Others 4-HTMPIPO 5F-PY-PICA 5F-PY-PINACA 5F-3-pyridinoylindole A-836,339 A-955,840 Abnormal cannabidiol AB-001 BzODZ-EPyr AM-1248 AM-1714 AZ-11713908 BAY 38-7271 BAY 59-3074 BIM-018 CB-13 CB-86 CBS-0550 FUBIMINA GW-842,166X JTE 7-31 LASSBio-881 LBP-1 Leelamine MDA-7 MDA-19 MEPIRAPIM NESS-040C5 NMP-7 O-889 O-1269 O-1270 O-1399 O-1602 O-2220 PF-03550096 PSB-SB-1202 PTI-1 PTI-2 S-444,823 SER-601 Tedalinab URB-447 VSN-16 WIN 56,098 Allosteric modulators of cannabinoid receptors Org 27569 Org 27759 Org 29647 RTI-371 Pregnenolone Endocannabinoid activity enhancers 4-Nonylphenylboronic acid AM-404 Arachidonoyl serotonin Arvanil Biochanin A CAY-10401 CAY-10429 Genistein IDFP JNJ 1661010 JZL184 JZL195 Kaempferol LY-2183240 O-1624 O-2093 Oleoylethanolamide (OEA) Olvanil Palmitoylethanolamide (PEA) PF-04457845 PF-622 PF-750 PF-3845 PHOP URB-447 URB-597 URB-602 URB-754 VDM-11 Cannabinoid receptor antagonists and inverse agonists AM-251 AM-281 AM-630 AM-1387 AM-4113 AM-6527 AM-6545 BML-190 CAY-10508 CB-25 CB-52 CB-86 Drinabant (AVE1625) Hemopressin Ibipinabant (SLV319) JTE-907 LH-21 LY-320,135 MDA-77 MJ-15 MK-9470 NESS-0327 NIDA-41020 O-606 O-1184 O-1248 O-1918 O-2050 O-2654 Otenabant (CP-945,598) PF-514273 PipISB PSB-SB-487 Rimonabant (SR141716) Rosonabant (E-6776) SR-144,528 Surinabant (SR147778) Taranabant (MK-0364) TM-38837 VCHSR

v t e Cannabinoidergics Receptor (ligands) CB1 Agonists: 2-AG 2-AGE (noladin ether) 11-Hydroxy-THC AB-CHMINACA AM-1220 AM-1235 AM-2201 AM-2232 Arvanil AZ-11713908 Cannabinol CP 47,497 CP 55,940 Dimethylheptylpyran DEA Epicatechin gallate Epigallocatechin gallate Gallocatechol (gallocatechin) Honokiol HU-210 JWH-007 JWH-018 JWH-073 Kavain L-759,633 Levonantradol Menabitan Nabilone Nabitan NADA O-1812 Oleamide Serinolamide A THC (dronabinol) WIN 55,212-2 Yangonin Note: The above list contains only some known CB1R agonists, as too many exist to list here completely. Refer here instead for more. Antagonists: AM-251 AM-6545 Cannabidiol Cannabigerol Drinabant Falcarinol Hemopressin Ibipinabant LY-320,135 MK-9470 NADA NESS-0327 O-2050 Otenabant PF-514273 PipISB Rimonabant Rosonabant Surinabant Taranabant THCV TM-38837 VCHSR Virodhamine CB2 Agonists: 2-AG 2-AGE (noladin ether) 4-O-Methylhonokiol A-796,260 A-834,735 A-836,339 AM-1221 AM-1235 AM-1241 AM-2232 Anandamide AZ-11713908 Cannabinol Caryophyllene CBS-0550 CP-55,940 GW-405,833 (L-768,242) GW-842,166X HU-308 JTE 7-31 JWH-007 JWH-015 JWH-018 JWH-73 JWH-133 L-759,633 L-759,656 Magnolol MDA-19 Nabitan PF-03550096 S-444,823 SER-601 Serinolamide A UR-144 Tedalinab THC (dronabinol) THCV Tetrahydromagnolol Virodhamine Antagonists: 4-O-Methylhonokiol AM-630 BML-190 Cannabidiol Honokiol JTE-907 SR-144,528 WIN 54,461 WIN 56,098 GPR55 Agonists: 2-AGE (noladin ether) 2-ALPI Abnormal cannabidiol AM-251 CP 55,940 GSK-494581A Lysophosphatidylinositol ML-184 ML-185 ML-186 O-1602 Oleoylethanolamide Palmitoylethanolamide THC (dronabinol) Antagonists: Cannabidiol CID-16020046 ML-191 ML-192 ML-193 O-1918 PSB-SB-487 PSB-SB-1202 PSB-SB-1203 Tetrahydromagnolol GPR18 Agonists: Abnormal cannabidiol ACPA AM251 Anandamide Cannabidiol NADGly THC (dronabinol) O-1602 Antagonists: CID-85469571 O-1918 GPR119 Agonists: 2-Oleoylglycerol Anandamide APD668 AR-231,453 AS-1269574 MBX-2982 N-Oleoyldopamine Oleoylethanolamide Olvanil PSN-375,963 PSN-632,408 Transporter (inhibitors) eCBTs 5'-DMH-CBD AM-404 AM-1172 Arachidonoyl serotonin Arvanil Cannabidiol LY-2183240 O-2093 OMDM-2 Paracetamol (acetaminophen) SB-FI-26 UCM-707 URB-597 VDM-11 Enzyme (inhibitors) FAAH 4-Nonylphenylboronic acid AACOCF3 AM-1172 AM-404 Arachidonoyl serotonin Biochanin A Genistein IDFP JNJ-1661010 JNJ-42165279 JZL-195 Kaempferol LY-2183240 MAFP Palmitoylisopropylamide Paracetamol (acetaminophen) PF-3845 PF-04457845 PF-750 SA-47 SA-57 TC-F 2 URB-597 MAGL IDFP JZL-184 JZL-195 URB-602 ABHD6 WWL-70