Just as the synthetic cannabinoid(s) used differ between each synthetic cannabinoid product sold, so do the other contents of the "herbal blends." Packages of synthetic cannabinoid products can claim to contain a wide array of plants including alfalfa, blue violet, nettle leaf, marsh mallow, rosehip, white or blue water lily, honeyweed, dwarf skullcap, and others. Oftentimes, none of the listed ingredients have been detectable. It is often difficult to determine what is in these products because masking agents, such as tocopherol (vitamin E), eugenol, and fatty acids, are added to confound identification. Most products consist of synthetic cannabinoids sprayed onto inert vegetable matter, but some contain other psychoactive substances, including psychoactive herbs, e.g., "Wild Dagga" and "Indian Warrior," and psychoactive alkaloids, e.g., betonicine, aporphine, leonurine, nuciferine, and nicotine. Some synthetic cannabinoids products have also been found to contain synthetic opioids including O-desmethyltramadol and AH-7921. In 2010, nine people died due to the combination of O-desmethyltramadol, a μ-opioid agonist and analgesic drug, and Kratom, an Asiatic medicinal plant containing mitragynine, another μ-opioid agonist, in a synthetic cannabinoid product called "Krypton." In 2013, AH-7921 was detected in smoking blends in Japan. In 2018, there was an outbreak of synthetic cannabinoids contaminated with anticoagulants, mainly brodifacoum, in at least 11 states in the US that caused coagulopathy (prolonged or excessive bleeding) and resulted in the treatment of over 300 people and at least eight deaths.
One of the most common non-cannabinoid ingredients in these products is oleamide, a fatty acid derivative that acts similarly to a cannabinoid and has hypnotic properties. Other non-cannabinoid ingredients that have been found in synthetic cannabinoid blends include harmine and harmaline, reversible monoamine oxidase inhibitors, which have been found with myristicin and asarone; substituted cathinone derived stimulant drugs such as 4-methylbuphedrone and 4'-methyl-alpha-PPP; and psychedelic tryptamine derivatives such as 4-OH-DET.
Many of the early synthetic cannabinoids that were synthesized for use in research were named after either the scientist who first synthesized them or the institution or company where they originated. For example, JWH compounds are named after John W. Huffman and AM compounds are named after Alexandros Makriyannis, the scientists who first synthesized those cannabinoids. HU compounds are named after Hebrew University in Jerusalem, the institution where they were first synthesized, and CP compounds are named after Charles Pfizer, the company where they were first synthesized.
Some of the names of synthetic cannabinoids synthesized for recreational use were given names to help market the products. For example, AKB-48 (also known as APINACA) is also the name of a popular Japanese girl band; 2NE1 (also known as APICA) is also a South Korean girl band; and XLR-11 was named after the first USA-developed liquid fuel rocket for aircraft. Now many synthetic cannabinoids are assigned names derived from their four main structural components, core, tail, linker, and linked group, where the name is formatted as LinkedGroup-TailCoreLinker. For example, in 5F-MDMB-PINACA (also known as 5F-ADB), 5F stands for the terminal fluorine or Fluorine on carbon 5 of the pentyl chain; MDMB stands for Methyl-3,3-DiMethylButanoate (MDMB), the linked group; and PINACA stands for Pentyl chain (tail) INdAzole (core) CArboxamide (linker).
Use of the term "synthetic marijuana" to describe products containing synthetic cannabinoids is controversial and, according to Dr. Lewis Nelson, a medical toxicologist at the NYU School of Medicine, a misnomer. Nelson claims that relative to marijuana, products containing synthetic cannabinoids "are really quite different, and the effects are much more unpredictable. It's dangerous." Since the term synthetic does not apply to the plant, but rather to the cannabinoid that the plant contains (THC), the term synthetic cannabinoid is more appropriate.
Synthetic cannabinoids are known by a number of brand names including K2, Spice, Arizona, Black Mamba, Bombay Blue, Genie, Zohai, Banana Cream Nuke, Krypton, Lava Red, and many more. In some Spanish-speaking countries, such as Chile and Argentina, such preparations are often referred to as "cripy". They are often called "synthetic marijuana", "natural herbs", "herbal incense", or "herbal smoking blends" and often labeled "not for human consumption". They are increasingly offered in e-cigarette form as "c-liquid" with brand names such as Kronic.
According to the Psychonaut Web Mapping Research Project, synthetic cannabinoids, sold under the brand name "Spice", were first released in 2005 by the now-dormant company The Psyche Deli in London, UK. In 2006, the brand gained popularity. According to the Financial Times, the assets of The Psyche Deli rose from £65,000 in 2006 to £899,000 in 2007. The EMCDDA reported in 2009 that Spice products were identified in 21 of the 30 participating countries.
Synthetic cannabinoids were made for cannabinoid research focusing on tetrahydrocannabinol (THC), cannabinoid receptors, and the endocannabinoids that activate them in the body. Synthetic cannabinoids were needed partly due to legal restrictions on natural cannabinoids, which make them difficult to obtain for research. Many have been useful because they bind selectively to either the CB1 or CB2 receptors, whereas THC has a similar affinity for both. Tritium-labelled cannabinoids such as CP-55,940 were instrumental in discovering the cannabinoid receptors in the early 1990s.
Some early synthetic cannabinoids were also used clinically. Nabilone, a first generation synthetic THC analog, has been used as an antiemetic to combat vomiting and nausea since 1981. Synthetic THC (marinol, dronabinol) has been used as an antiemetic since 1985, and an appetite stimulant since 1991.
In the early 2000s, synthetic cannabinoids began to be used for recreational drug use in an attempt to get similar effects to cannabis. Because synthetic cannabinoid molecular structures differ from THC and other illegal cannabinoids, synthetic cannabinoids were not technically illegal. Since the discovery of the use of synthetic cannabinoids for recreational use in 2008, some synthetic cannabinoids have been made illegal, but new analogs are continually synthesized to avoid the restrictions. Synthetic cannabinoids have also been used recreationally because they are inexpensive and are typically not revealed by the standard marijuana drug tests. Unlike nabilone, the synthetic cannabinoids found being used for recreational use did not have any documented therapeutic effects.
Because they activate the cannabinoid CB1 and CB2 receptors, many of the effects of synthetic cannabinoids are similar to those of THC. These are achieved at lower doses, because many synthetic cannabinoids are more potent than marijuana, and users are often unaware of exactly what they are getting and how potent it is. For example, Δ9-THC has an EC50 of 250 nM at CB1 and 1157 nM at CB2, whereas PB-22 has an EC50 of 5.1 nM at CB1 and 37 nM at CB2. On the other hand, some adverse effects are not usually seen in marijuana at any dose, such as acute kidney injury, cardiac toxicity, seizure, stroke, tremor, hypokalemia, and rhabdomyolysis. Some negative effects of 5F-PB-22 reported by users included nausea, vomiting, confusion, poor coordination, anxiety, and seizures. Some of the negative effects of 5F-AKB-48 reported by users included palpitations, paranoia, intense anxiety, and a taste like burned plastic. In addition, while there are no fatal overdose cases linked to marijuana, there are deaths linked to synthetic cannabinoids each year. The most common mechanisms leading to death following synthetic cannabinoid use include behavioral risks, such as self-harm and suicide, falling from a height, and wandering into traffic; cardiovascular effects; and central nervous system depression.
Researchers have pointed out a few ways that synthetic cannabinoids differ from marijuana, and therefore may be more dangerous. First, they often have greater intrinsic activity. Many of the synthetic cannabinoids are full agonists of the cannabinoids receptors, CB1 and CB2, compared to THC, which is only a partial agonist. Secondly, they may have other actions in the body, in addition to activating cannabinoid receptors. Some may work on NMDA glutamate receptors. Some may also work on serotonin, either indirectly by inhibiting MAO and increasing 5-HT1A receptor expression, or by directly binding to serotonin receptors, including the 5-HT1A and 5-HT3 subtypes; some researchers speculate that this activity may be because the indole moiety that some synthetic cannabinoids possess is similar to the structure of serotonin. Third, synthetic cannabinoids may break down into metabolites, or create other by-products when heated, that may differ from marijuana. Phase 1 metabolism of JWH-018 results in at least nine monohydroxylated metabolites, three of which have been shown to be full agonists of the CB1 receptors, compared to the metabolism of THC, which only results in one psychoactive monohydroxylated metabolite. The metabolite N-(3-hydroxypentyl) JWH-018 was found to have toxic effects that its parent compound does not. Some metabolites even appear to be cannabinoid antagonists. Lastly, they may contain unwanted substances, be mislabeled, or contain different doses than advertised (in one analysis, a difference of one log unit was found).
No official studies have been conducted on the effects of synthetic cannabinoids on humans (as is often the case with illegal and potentially toxic compounds); however, user reports and the effects experienced by patients seeking medical care after taking synthetic cannabinoids have been published. Each of the many different synthetic cannabinoids can have different effects at different dosages. The CDC described synthetic cannabinoid overdoses between 2010 and 2015 and of 277 drug overdose patients who reported synthetic cannabinoid as the sole agent, 66.1% reported problems in the central nervous system (e.g., agitation, coma, toxic psychosis), 17% reported cardiovascular problems (e.g., tachycardia, bradycardia), 7.6% reported pulmonary problems (5.4% of which had respiratory depression), and 4% reported acute kidney injury. There have also been reports of a strong compulsion to re-dose, withdrawal symptoms, and persistent cravings lasting up to a week after taking synthetic cannabinoids, indicating that synthetic cannabinoids may be more addictive than marijuana.
Four postmortem cases linked to the synthetic cannabinoids 5F-PB-22 have been reviewed. The postmortem blood specimens contained a range of 1.1-1.5 ng/mL of 5F-PB-22. Three of the four cases were sudden episodes and the symptoms leading to death included acute shortness of breath; vasocongestion in the liver, spleen, and kidneys; bilateral pulmonary edema; dead inflamed tissue (necrotizing granulomatous inflammation); and congestion of most internal organs. The fourth case presented to the hospital with severe problems that deteriorated over the course of a day, ending with circulatory, respiratory, central nervous system, and renal failure.
Studies are currently available that suggest an association between synthetic cannabinoids and psychosis. The use of synthetic cannabinoids can be associated with psychosis and physicians are beginning to investigate if some patients with inexplicable psychotic symptoms may have at one point used synthetic cannabinoids. In contrast to most other recreational drugs, the dramatic psychotic state induced by use of synthetic cannabinoids has been reported, in multiple cases, to persist for several weeks, and in one case for seven months, after complete cessation of drug use. Some studies suggest that not only can synthetic cannabinoids induce psychosis, but they can worsen previously stable psychotic disorders and might trigger a chronic (long-term) psychotic disorder among vulnerable individuals such as those with a family history of mental illness. Individuals with risk factors for psychotic disorders are often counseled against using synthetic cannabinoids. Psychiatrists have suggested that the lack of an antipsychotic chemical, like CBD in natural cannabis, may make synthetic cannabinoids more likely to induce psychosis than natural cannabis.
|5||Adamantoylindoles||5F-AKB-48, APICA, STS-135|
|6||Indazole carboxamides||AB-PINACA, AB-FUBINACA|
|7||Quinolinyl ester||PB-22, 5F-PB-22|
There are five major categories for synthetic cannabinoids: classical cannabinoids, non-classical cannabinoids, hybrid cannabinoids, aminoalkylindoles, and eicosanoids. Classical cannabinoids are analogs of THC that are based on a dibenzopyran ring. They were developed starting in the 1960s, following the isolation of THC, and were originally the only cannabinoids synthesized. Classical cannabinoids include nabilone and dronabinol, and one of the best known synthetic classical cannabinoids is HU-210. HU-210 is a chiral compound first synthesized by Raphael Mechoulam at Hebrew University in the 1980s. It was discovered in herbal incense products by the U.S. Customs and Border Protection in January 2009; however, classical cannabinoids are not often seen in synthetic cannabinoid blends for recreational use, likely because they are difficult to synthesize.
Non-classical cannabinoids include cyclohexylphenols (CP), which were first synthesized in the late 1970s to 1980s by Pfizer as potential analgesics. The C8 homologue of CP-47,497 (CP-47,497-C8) was one of the first synthetic cannabinoids being used recreationally. CP-47,497-C8 is made by extending the dimethylheptyl side chain of CP-47,497 to a dimethyloctyl side chain. It was discovered by forensic scientists in an herbal blend known as "Spice" in 2008, along with JWH-018, an aminoalkylindole.
Hybrid cannabinoids have a combination of classical and non-classical cannabinoid structural features. For example, AM-4030, a derivative of HU-210, is a hybrid cannabinoid because it has the dibenzopyran ring common of classical cannabinoids and an aliphatic hydroxyl group common in the CP family of nonclassical cannabinoids.
Aminoalkylindoles are structurally dissimilar to THC and include naphthoylindoles (JWH-018), phenylacetylindoles (JWH-250), and benzoylindoles (AM-2233). Aminoalkylindoles are considered to be the most common synthetic cannabinoids found in synthetic cannabinoid blends, likely due to the fact that these molecules are easier to synthesize than classical and non-classical cannabinoids. The JWH molecules were first synthesized by Professor John William Huffman at Clemson University in the late 1990s. The FBI concluded in a 2012 memo that as a result of the publication of J.W. Huffman's research, people searching for a "marijuana-like-high" would follow his recipes and methods.
Eicosanoid synthetic cannabinoids are analogs of endocannabinoids, such as anandamide. Endocannabinoids are cannabinoids naturally occurring in the body. One of the best known synthetic analogs of anandamide is methanandamide.
The synthetic cannabinoids that have emerged recently have even greater structural diversity, possibly to subvert legal regulations on earlier generations of synthetic cannabinoids. There are a few different structural classifications of synthetic cannabinoids that include many of the new structures, some of which are shown in Table 1. The indazole carboxamide group, including APINACA (AKB-48), an adamantyl indazole carboxamide, and AB-PINACA, an aminocarbonyl indazole carboxamide, is an example of a new group of synthetic cannabinoids. Most clandestine manufacturers and producers only make small changes to the structure of a synthetic cannabinoid, such as changing an indole to indazole structure (AM-2201 to THJ-2201) or terminal fluorine replacement; however, one group that was unprecedented when discovered by forensic scientists in 2013, was the quinolinyl ester synthetic cannabinoids.
PB-22 and 5F-PB-22 were the first synthetic cannabinoids to include a quinoline substructure and an ester linkage. These compounds are thought to have been synthesized with the intention of making a synthetic cannabinoid prodrug, which might improve absorption and confound detection. Ester bonds are easily biodegradable through spontaneous or endogenous, nonspecific esterase hydrolysis, which has been commonly used in medicinal chemistry to make ester prodrugs. The reason for the change to the quinolone substructure is unknown, but it may have been found to be a suitable replacement for the naphthoyl moiety that is currently regulated by US scheduling laws.
Although most synthetic cannabinoids are not direct analogs of THC, they share many common features with THC. Most are lipid-soluble, non-polar, small molecules (usually 20-26 carbon atoms) that are fairly volatile, making them "smokable," like THC. Another common feature of most synthetic cannabinoids and THC is a side-chain of 5-9 saturated carbon atoms. It has been found that this chain of 5-9 carbons is required for optimal psychotropic activity from binding CB1 receptors. Also, most synthetic cannabinoids are agonists of both cannabinoid receptors, CB1 and CB2, like THC; however, they often have greater binding affinity and therefore greater potency than THC, as seen in Table 2. Due to the greater potency, the standard doses of many synthetic cannabinoids may be less than 1 mg.
|Name||Year Identified by Forensics||Structural Classification||Structure||CB1 Binding Affinity (nM)||CB2 Binding Affinity (nM)||CB1 EC50 (nM)||CB2 EC50 (nM)|
|Δ9-THC||Classical Cannabinoid||41 ± 2||36 ± 10||250||1157|
|HU-210||2009||Classical Cannabinoid||0.061 ± 0.007||0.52 ± 0.04|
|(C8) CP 47,497||2008||Non-Classical Cannabinoid (Cyclohexylphenol)||2.20 ± 0.47|
|JWH-018||2008||Aminoalkylindole (Naphthoylindoles)||9.0 ± 5.0||2.94 ± 2.65||102||133|
|AM-2201 (Fluorinated JWH-018)||2011||Aminoalkylindole (Naphthoylindoles)||1.0||2.6||38||58|
|UR-144||2010||Tetramethylcyclopropylindoles||29 ± 0.9||4.5 ± 1.7||421||72|
|XLR-11 (Fluorinated UR-144)||2012||Tetramethylcyclopropylindoles||24 ± 4.6||2.1 ± 0.6||98||83|
|STS-135 (Fluorinated APICA)||Adamantoylindole||51||13|
|5F-PB-22 (Fluorinated PB-22)||Quinolinyl ester||0.468||0.633||2.8||11|
Most classical, non-classical, and hybrid synthetic cannabinoids have stereospecificity (one stereoisomer is usually much more potent than the other(s)). For example, HU-210 is the (–) enantiomer of 11-OH-Δ8-THC-DMH and a full agonist of the CB1 receptor; the (+) enantiomer of 11-OH-D8-THC-DMH, known as HU-211, is a NMDA receptor antagonist and is largely inactive as a cannabinoid. On the other hand, aminoalkylindoles, eicosanoids, and the other new synthetic cannabinoid groups typically do not have an asymmetric center, so they are usually not stereospecific.
Recently there has been an increase in the emergence of terminally fluorinated synthetic cannabinoids, such as 5F-PB-22 (fluorinated version of PB-22) and XLR-11 (fluorinated version of UR-144). South Korea's National Forensic Service reported that 90% of all seized synthetic cannabinoids in 2013 were fluorinated, compared to no fluorinated synthetic cannabinoids reported in 2010. 5F-derivations (terminal fluorination) of the synthetic cannabinoids have been found to be about 2-5 times more potent at CB1 receptors than their un-fluorinated counterparts, as shown in Table 2.
Synthetic cannabinoids are typically not identified by the standard marijuana drug tests including the immunoassay test (EMIT), GC-MS screening, and multi-target screening by LC-GC/MS because those tests only detect the presence of THC and its metabolites. Although most synthetic cannabinoids are analogs of THC, they are structurally different enough that, for example, the specific antibodies in the EMIT for marijuana do not bind to them. Also, due to their high potency, a very small dose of synthetic cannabinoids is used; moreover, synthetic cannabinoids are highly metabolized by the body, so the window to detect the parent drug (the synthetic cannabinoid itself) in blood and oral fluid is very small.
Serum concentrations of synthetic cannabinoids are generally in the 1–10 μg/L range during the first few hours after recreational usage and the metabolites are usually present in urine at similar concentrations. Little to no parent drug is present in urine, so there is a lot of research to try and identify the major urinary metabolites that could be used as markers of synthetic cannabinoid intake. The major urinary metabolites in most cases are formed by oxidation of the alkyl side-chain to an alcohol and carboxylic acid followed by glucuronide conjugation and also by N-dealkylation and aromatic hydroxylation. For example, the main metabolites of JWH-018, of which there are over 20, include carboxylated, monohydroxylated, dihydroxylated, and trihydroxylated metabolites, but they are mostly excreted in urine as glucuronide conjugates. The presence of synthetic cannabinoids or their metabolites in bodily fluids may be determined using specifically-targeted commercially available immunoassay screening methods (EMIT), while liquid chromatography-mass spectrometry is most often used for confirmation and quantitation. There are commercially available EMIT kits for the screening of the synthetic cannabinoids JWH-018, JWH-073, JWH-398, JWH-200, JWH-019, JWH-122, JWH-081, JWH-250, JWH-203, CP-47,497, CP-47,497-C8, HU-210, HU-211, AM-2201, AM-694, RCS-4, and RCS-8 through companies like NMS Labs, Cayman Chemical, and Immunoanalysis Corporation.
On October 20, 2011, the Louisiana State University football program announced that it had suspended three players, including star cornerback Tyrann Mathieu, who tested positive for synthetic cannabinoids.
On July 12, 2016, 33 people were intoxicated by an herbal "incense" product called "AK-47 24 Karat Gold," and dozens overdosed, in Brooklyn. 18 people were transported to local hospitals. This mass intoxication event was referred to as a "zombie" outbreak in the press due to the description of the intoxicated persons by bystanders as "zombielike" (moved slowly, had blank stares, and occasionally groaned).[better source needed] The herbal "incense" product was determined to be a synthetic cannabinoid called AMB-FUBINACA.
Since March 2018, Illinois, Wisconsin, Maryland, and 8 other states in the United States have had an outbreak of severe bleeding caused by a synthetic cannabinoid contaminated with brodifacoum, a rat poison that causes bleeding. Illinois was hit the hardest and on April 5, 2018, the CDC issued a Clinical Action alert to health care providers across the United States advising of 89 confirmed cases of "serious unexplained bleeding" in Illinois. The cases are still being studied; however, 63 of the patients reported synthetic cannabinoid use, and laboratory analysis confirmed brodifacoum was present in at least 18 patients. As of April 24, 2018, 153 cases, including four deaths, linked to this outbreak have been reported to the Illinois Department of Public Health (IDPH) since March 7, 2018. On September 18, 2018, the Wisconsin Department of Health Services confirmed 16 more cases, bringing the total number of people affected by the outbreak in Wisconsin to 80 people since March 2018, including one death in July 2018.
In August 2018, there were almost one hundred overdose cases reported over two days in New Haven, Connecticut from a bad batch of K2. The synthetic cannabinoid was believed to have been mixed with fentanyl, although no fentanyl was identified in samples of the drug tested by the DEA.
In September 2018, at least 10 people overdosed on a synthetic cannabinoid, either AMB-FUBINACA or AB, in Christchurch, New Zealand over two days. Some of the people are in critical condition in the Intensive Care Unit.
From September 21–22, 2018, almost 50 people overdosed and two people died in the Kensington area of Philadelphia. Tests are still in progress, but officials believe the cause to be a combination of heroin or fentanyl and a synthetic cannabinoid. This same area in Philadelphia had 155 people overdose and 10 people die from a combination of heroin, fentanyl, and a synthetic cannabinoid called 5F-ADB over one weekend in July 2018. The Department of Public Health released that they believe "5F-ADB was the primary cause of the cluster of patients with these adverse drug reactions."
The Austrian Ministry of Health announced on December 18, 2008 that Spice would be controlled under Paragraph 78 of their drug law on the grounds that it contains an active substance that affects the functions of the body, and the legality of JWH-018 is under review.
JWH-018, CP 47,497 and the C6, C8 and C9 homologues of CP 47,497 have been illegal in Germany since January 22, 2009. Since November 26, 2016 about 80-90% of the substances belonging to the group of synthetic cannabinoids are illegal in Germany as the law does not cover all chemical structures.
JWH-018, JWH-073, CP 47,497 (and its homologues), and HU-210 as well as leonotis leonurus have been all banned in Latvia since 2005. After the first confirmed lethal case from the use of legal drugs in late 2013, parliament significantly increased the number of temporarily banned substances used in Spice and similar preparations. On April 3, 2014, parliament made selling of the temporarily banned substances a criminal offense.
JWH-018 and many of the herbs mentioned on the ingredient lists of Spice and similar preparations were made illegal in May 2009. The bill was passed by Polish Sejm and Polish Senat and was signed by the President.
On April 9, 2009, the Chief Medical Officer of the Russian Federation issued a resolution on reinforcing control over the sales of smoking blends. These blends, marketed under the trade names AM-HI-CO, Dream, Spice (Gold, Diamond), Zoom, Ex-ses, Yucatán Fire and others, have been declared to contain Salvia divinorum, Hawaiian wood rose, and blue lotus, and are prohibited to be sold. These substances have been found to have "psychotropic, narcotic effects, contain poisonous components and represent potential threat for humans". The resolution does not mention JWH-018 or other synthetic cannabinoids. On January 14, 2010, the Russian government issued a statement including 23 synthetic cannabinoids found in smoking blends Hawaiian Rose and Blue Lotus on the list of prohibited narcotic and psychotropic substances.
About 780 new psychoactive substances were added to the list from 2011 to 2014. The drugmakers avoided all the bans by making slight changes to the drugs. In the autumn of 2014, more than two-thousand Spice consumers in Russia sought medical attention, one-thousand were admitted to hospitals, and 40 people died On October 30, 2014, President Vladimir Putin brought in a bill that increased the penalty for selling or consuming smoking blends from a fine to up to eight years in prison.
Spice is legal in Slovakia. The National Anti-Drug Unit is considering adding it to the list of controlled substances. The latest anti-drug law version (468/2009) valid since January 2010 does not mention active compounds of Spice.
Spice is unregulated in Spain. For this reason, Spice is available in grow shop stores or cannabis related stores, and it can be bought and shipped online without any legal impediment from those kind of stores. However, as Spanish law permits growing up to two cannabis plants per household, and the possession and consumption of cannabis on private property is also legal, cannabis alternatives like Spice are largely redundant and thus remain relatively unknown in Spain.
CP 47,497-C6, CP 47,497-C7, CP 47,497-C8, CP 47,497-C9, JWH-018, JWH-073 and HU-210 were all made illegal in Sweden on September 15, 2009. The bill was accepted on July 30, 2009 and was put in effect on September 15, 2009.
Spice, which is colloquially called bonzai in Turkey, was added to the list of drugs and psychotropic substances on July 1, 2011 by the law numbered as 2011/1310 B.K.K. (February 13, 2011 and the Official Gazette No. 27845).
The UK controls synthetic cannabinoids by analog under the Misuse of Drugs Act, 1971 as Class B drugs. Until 2016, synthetic cannabinoids were legally sold in head shops, although the exact compounds available changed over time based on the legislation. The UK saw three generations of synthetic cannabinoids within five years where the second and third generations emerged in response to amendments to the Misuse of Drugs Act, 1971, Order 2009 and Order 2013, which classified many first and second generation synthetic cannabinoids as Class B drugs. There were two additional amendments in 2016 and 2019, which included in the analog controls many of the most popular synthetic cannabinoids circulating at the time. In May 2016, the Psychoactive Substances Act was enacted, which made illegal the production, distribution, sale, supply, and possession in correctional institutions of any substance for human consumption with psychoactive effects. This stopped the open sale of synthetic cannabinoids in head shops, although they are still found in use.
Spice is not specifically prohibited in Canada, but synthetic cannabis mimics are listed as a schedule II drug. Schedule II to the Controlled Drugs and Substances Act makes reference to specific synthetic compounds JWH-XXX and AM-XXXX, although is not limiting to those identified. Health Canada is debating the subject. Schedule II has consisted entirely of synthetic cannabinoids since October 2018; these remain illegal following the removal from the schedule of cannabis and its constituents derived from nature.
The case of David Mitchell Rozga, an American teenager from Indianola, Iowa, brought international attention to K2. Rozga shot himself in the head with a family-owned hunting rifle in an apparent suicide on June 6, 2010. After news of Rozga's death, it was reported by friends that they had smoked K2 with Rozga approximately one hour before his death. The nature of his death and reports from numerous family members, led investigators to suspect that Rozga was under the influence of a mind-altering substance when he died. The death of Rozga influenced political lobbying against K2, and other legal synthetic drugs such as bath salts. Following the incident, the "David Mitchell Rozga Act" to ban the use and distribution of K2 was introduced by Iowa Senator Chuck Grassley. It was passed by the United States Congress in June 2011. On July 10, 2012, President Barack Obama signed the Synthetic Drug Abuse Prevention Act of 2012 into law. It banned synthetic compounds commonly found in synthetic marijuana, placing them under Schedule I of the Controlled Substances Act.
Prior to that, some synthetic cannabis compounds (HU-210) were scheduled in the US under federal law, while others (JWH-073) were temporarily scheduled until final determination of their status could be made. The Drug Enforcement Administration (DEA) considered K2 to be a "drug of concern", citing "...a surge in emergency-room visits and calls to poison-control centers. Adverse health effects associated with its use include seizures, hallucinations, paranoid behavior, agitation, anxiety, nausea, vomiting, racing heartbeat, and elevated blood pressure."
Several states independently passed acts making it illegal under state law, including Kansas in March 2010, Georgia and Alabama in May 2010, Tennessee and Missouri in July 2010, Louisiana in August 2010, Mississippi in September 2010, and Iowa. An emergency order was passed in Arkansas in July 2010 banning the sale of synthetic cannabis mimics. In October 2010, the Oregon Board of Pharmacy listed synthetic cannabinoid chemicals on its Schedule 1 of controlled substance, which means that the sale and possession of these substances is illegal under the Oregon Uniform Controlled Substances Act. According to the National Conference of State Legislatures, several other states also considered legislation, including New Jersey, New York, Florida, and Ohio. Illinois passed a law on July 27, 2010 banning all synthetic cannabinoids as of January 1, 2011. Michigan banned synthetic cannabinoids in October 2010, and the South Dakota Legislature passed a ban on these products which was signed into law by Gov. Dennis Daugaard on February 23, 2012 (and which took immediate effect under an emergency clause of the state constitution). Indiana banned synthetic cannabinoids in a law which became effective in March 2012. North Carolina banned synthetic cannabis mimics by a unanimous vote of the state senate, due to concerns that its contents and effects are reasonably similar to cannabis, and may cause equal effects in terms of psychological dependency.
Following cases in Japan involving the use of synthetic cannabinoids by navy, army and marine corps personnel, they were officially banned. A punitive general order issued on January 4, 2010 by the Commander Marine Corps Forces, Pacific prohibits the actual or attempted possession, use, sale, distribution and manufacture of synthetic cannabis mimics as well as any derivative, analogue or variant of it. On June 8, 2010, the US Air Force issued a memorandum that banned the possession and use of Spice, or any other mood-altering substance except alcohol or tobacco, among its service members.
Usage among 8th, 10th, and 12th graders has been decreasing since 2011, while use of botanical marijuana has remained stable. There are important regional differences, with large declines in the Western and Southern US, and increases in the Northeast and Midwest.
The Chilean Ministry of Health on April 24, 2009, declared the sale of synthetic cannabis mimics to be illegal.
Japan has banned JWH-018, CP 47, 497, and homologues, and HU-210 since October 2009.
On June 17, 2011, the Western Australian government banned all of the synthetic cannabinoids found in already existing products, including brands such as Kronic, Kalma, Voodoo, Kaos, and Mango Kush. Western Australia was the first state in Australia to prohibit the sale of certain synthetic cannabinoids. On June 18, 2013, an interim ban made a large list of product brands and synthetic substances illegal to sell anywhere in Australia. This ban lapsed on October 13, 2013, and a permanent ban has not been imposed. Synthetic cannabinoids and related products remain illegal in NSW, where a bill was passed on September 18, 2013, that bans entire families of synthetic drugs instead of only banning existing compounds that have been identified. The introduction of this law makes NSW the first state in Australia to completely ban substances with psychoactive properties.
Spice is illegal in New Zealand, it is classified as a Class C controlled drug. The New Zealand Parliament passed a law in July 2013 banning the sale of legal highs in dairies and supermarkets, but allowing some "low risk" drugs to continue to be sold through speciality licensed shops. Synthetic cannabinoids, as well as all other legal highs were outlawed at midnight on 7 May 2014, after a law was passed a week prior by the New Zealand government.
An analysis of 41 different synthetic cannabis mimic blends sold commercially in New Zealand, conducted by the Institute of Environmental Science and Research and released in July 2011, found 11 different synthetic cannabinoid ingredients used, including JWH-018, JWH-073, AM-694, AM-2201, RCS-4, RCS-4 butyl homologue, JWH-210, JWH-081, JWH-250 (or possibly JWH-302, isomer not determined), JWH-203, and JWH-122—with between one and five different active ingredients, though JWH-018 was present in 37 of the 41 blends tested. In two brands, the benzodiazepine anxiolytic drug phenazepam was also found, which is classified as a prescription medicine in New Zealand, and these brands were ordered to be removed from the market by emergency recall. Since this time, a further 15 cannabinoid compounds have been detected as ingredients of synthetic cannabis mimicking blends in New Zealand and banned as temporary class drugs. In 2013, another hypnotic medication, zaleplon, was found to have been used as an active ingredient in a blend that had been sold in New Zealand during 2011 and 2012.