Synthetic Cannabinoids

doi:10.1017/9781108943246.004

Chapter 3 - Synthetic Cannabinoids

from Part I - Pharmacology of Cannabis and the Endocannabinoid System

Published online by Cambridge University Press: 12 May 2023

Liana Fattore and

Matteo Marti

Edited by

Deepak Cyril D'Souza ,

David Castle and

Sir Robin Murray

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Deepak Cyril D'Souza: Affiliation:
Staff Psychiatrist, VA Connecticut Healthcare System; Professor of Psychiatry, Yale University School of Medicine
David Castle: Affiliation:
University of Tasmania, Australia
Sir Robin Murray: Affiliation:
Honorary Consultant Psychiatrist, Psychosis Service at the South London and Maudsley NHS Trust; Professor of Psychiatric Research at the Institute of Psychiatry

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Summary

New synthetic cannabinoid agonists have been synthesized during the last decades and promoted for their psychoactive effects, mimicking those of delta-9-tetrahydrocannabinol. These newest cannabimimetic drugs show binding affinities for the cannabinoid CB1 and/or the CB2 receptors. They are manufactured by spraying the synthetic cannabinoid onto relatively inert vegetable material or by solubilizing them in ’e-liquids’ for electronic cigarettes. They are lipid soluble and non-polar and volatilize easily when smoked. However, these drugs have been associated with psychiatric and medical complications. The most typical adverse effects of synthetic cannabinoid agonists included agitation, confusion, anxiety, psychosis, nausea, and vomiting, but drowsiness, tachycardia, and hypertension are also reported frequently. Atypical effects can also manifest, including shock, seizures, fever, rhabdomyolysis, myocardial infarction, stroke, acute kidney injury, and multiple organ failure. The cardiovascular and neuropsychiatric effects, which in some cases can be severe and long-lasting, are among the most common reasons for emergency medical treatment. Due to limited knowledge about their pharmacology and toxicity, managing acute intoxications is challenging and treatment strategies are mostly limited to symptomatic and supportive care.

Keywords

novel psychoactive substances (NPS)spice drugs legal high CB1 receptor agonists acute intoxications toxicity genotoxicity

Type: Chapter
Information: Marijuana and Madness , pp. 21 - 30

DOI: https://doi.org/10.1017/9781108943246.004 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2023

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References

Akram, H., Mokrysz, C., and Curran, H. V. (2019). What are the psychological effects of using synthetic cannabinoids? A systematic review. J Psychopharmacol, 33, 271–283.CrossRef Google Scholar PubMed

Alexandre, J., Carmo, H., Carvalho, F., et al. (2020). Synthetic cannabinoids and their impact on neurodevelopmental processes. Addict Biol, 25, e12824.Google Scholar

Altintas, M., Inanc, L., Oruc, G. A., et al. (2016). Clinical characteristics of synthetic cannabinoid-induced psychosis in relation to schizophrenia: A single-center cross-sectional analysis of concurrently hospitalized patients. Neuropsychiatr Dis Treat, 12, 1893–1900.Google Scholar

Altintop, I. (2020). A 4-year retrospective analysis of patients presenting at the emergency department with synthetic cannabinoid intoxication in Turkey. J Clin Psychopharmacol, 40, 464–467.Google Scholar

van Amsterdam, J., Brunt, T., and van den Brink, W. (2015). The adverse health effects of synthetic cannabinoids with emphasis on psychosis-like effects. J Psychopharmacol, 29, 254–263.Google Scholar

Angerer, V., Franz, F., Moosmann, B., et al. (2019). 5F-Cumyl-PINACA in ‘e-liquids’ for electronic cigarettes: Comprehensive characterization of a new type of synthetic cannabinoid in a trendy product including investigations on the in vitro and in vivo phase I metabolism of 5F-Cumyl-PINACA and its non-fluorinated analog Cumyl-PINACA. Forensic Toxicol, 37, 186–196.Google Scholar

Argamany, J. R., Reveles, K. R., and Duhon, B. (2016). Synthetic cannabinoid hyperemesis resulting in rhabdomyolysis and acute renal failure. Am J Emerg Med, 34, 765.e1–2.Google Scholar

Auwärter, V., Dresen, S., Weinmann, W., et al. (2009). ‘Spice’ and other herbal blends: Harmless incense or cannabinoid designer drugs? J Mass Spectrom, 44, 832–837.Google Scholar

Barbieri, M., Ossato, A., Canazza, I., et al. (2016). Synthetic cannabinoid JWH-018 and its halogenated derivatives JWH-018-Cl and JWH-018-Br impair novel object recognition in mice: Behavioral, electrophysiological and neurochemical evidence. Neuropharmacology, 109, 254–269.Google Scholar

Basavarajappa, B. S., and Subbanna, S. (2019). Potential mechanisms underlying the deleterious effects of synthetic cannabinoids found in spice/K2 products. Brain Sci, 9, 14.Google Scholar

Benford, D. M., and Caplan, J. P. (2011). Psychiatric sequelae of spice, k2, and synthetic cannabinoid receptor agonists. Psychosomatics, 52, 295.Google Scholar

Besli, G. E., Ikiz, M. A., Yildirim, S., et al. (2015). Synthetic cannabinoid abuse in adolescents: A case series. J Emerg Med, 49, 644–650.Google Scholar

Bilel, S., Tirri, M., Arfè, R., et al. (2019). Pharmacological and behavioral effects of the synthetic cannabinoid AKB48 in rats. Front Neurosci, 13, 1163.Google Scholar

Bilel, S., Tirri, M., Arfè, R., et al. (2020). Novel halogenated synthetic cannabinoids impair sensorimotor functions in mice. Neurotoxicology, 76, 17–32.Google Scholar

Brents, L. K., Gallus-Zawada, A., Radominska-Pandya, A., et al. (2012). Monohydroxylated metabolites of the K2 synthetic cannabinoid JWH-073 retain intermediate to high cannabinoid 1 receptor (CB1R) affinity and exhibit neutral antagonist to partial agonist activity. Biochem Pharmacol, 83, 952–961.CrossRef Google Scholar PubMed

Brents, L. K., Reichard, E. E., Zimmerman, S. M., et al. (2011). Phase I hydroxylated metabolites of the K2 synthetic cannabinoid JWH-018 retain in vitro and in vivo cannabinoid 1 receptor affinity and activity. PLoS ONE, 6, e21917.Google Scholar

Canazza, I., Ossato, A., Trapella, C., et al. (2016). Effect of the novel synthetic cannabinoids AKB48 and 5F-AKB48 on ‘tetrad’, sensorimotor, neurological and neurochemical responses in mice. In vitro and in vivo pharmacological studies. Psychopharmacology, 233, 3685–3709.Google Scholar

Canazza, I., Ossato, A., Vincenzi, F., et al. (2017). Pharmaco-toxicological effects of the novel third-generation fluorinate synthetic cannabinoids, 5F-ADBINACA, AB-FUBINACA, and STS-135 in mice. In vitro and in vivo studies. Hum Psychopharmacol, 32, 3.Google Scholar

Castellanos, D., Singh, S., Thornton, G., et al. (2011). Synthetic cannabinoid use: A case series of adolescents. J Adolesc Health, 49, 347–349.Google Scholar

Caviness, C. M., Tzilos, G., Anderson, B. J., et al. (2015). Synthetic cannabinoids: Use and predictors in a community sample of young adults. Subst Abus, 36, 368–373.Google Scholar

Coccini, T., De Simone, U., Lonati, D., et al. (2021). MAM-2201, one of the most potent-naphthoyl indole derivative-synthetic cannabinoids, exerts toxic effects on human cell-based models of neurons and astrocytes. Neurotox Res, 39, 1251–1273.Google Scholar

Cohen, K., Kapitány-Fövény, M., Mama, Y., et al. (2017). The effects of synthetic cannabinoids on executive function. Psychopharmacology, 234, 1121–1134.Google Scholar

Cohen, K., and Weinstein, A. M. (2018). Synthetic and non-synthetic cannabinoid drugs and their adverse effects: A review from public health prospective. Front Public Health, 6, 162.Google Scholar

Cooper, Z. D. (2016). Adverse effects of synthetic cannabinoids: Management of acute toxicity and withdrawal. Curr Psychiatry Rep, 18, 52.Google Scholar

Cooper, Z. D., and Craft, R. M. (2018). Sex-dependent effects of cannabis and cannabinoids: A translational perspective. Neuropsychopharmacology, 43, 34–51.Google Scholar

Cooper, Z. D., Evans, S. M., and Foltin, R. W. (2021). Self-administration of inhaled delta-9-tetrahydrocannabinol and synthetic cannabinoids in non-human primates. Exp Clin Psychopharmacol, 29, 137–146.Google Scholar

DAWN. (2012). The DAWN Report: Drug-Related Emergency Department Visits Involving Synthetic Cannabinoids; Substance Abuse and Mental Health Services Administration (SAMHSA), Center for Behavioral Health Statistics and Quality: Rockville, MD.Google Scholar

De Luca, M. A., Bimpisidis, Z., Melis, M., et al. (2015). Stimulation of in vivo dopamine transmission and intravenous self-administration in rats and mice by JWH-018, a Spice cannabinoid. Neuropharmacology, 99, 705–714.Google Scholar

De Luca, M. A., and Fattore, L. (2018). Therapeutic use of synthetic cannabinoids: Still an open issue? Clin Ther, 40, 1457–1466.Google Scholar

Dresen, S., Ferreirós, N., Pütz, M., et al. (2010). Monitoring of herbal mixtures potentially containing synthetic cannabinoids as psychoactive compounds. J Mass Spectrom, 45, 1095–1232.CrossRef Google Scholar PubMed

Egan, K. L., Suerken, C. K., Reboussin, B. A., et al. (2015). K2 and spice use among a cohort of college students in southeast region of the USA. Am J Drug Alcohol Abuse, 41, 317–322.CrossRef Google Scholar PubMed

Elmore, J. S., and Baumann, M. H. (2018). Repeated exposure to the ‘spice’ cannabinoid JWH-018 induces tolerance and enhances responsiveness to 5-HT1A receptor stimulation in male rats. Front Psychiatry, 9, 55.Google Scholar

Escelsior, A., Belvederi Murri, M., Corsini, G. P., et al. (2021). Cannabinoid use and self-injurious behaviours: A systematic review and meta-analysis. J Affect Disord, 278, 85–98.CrossRef Google Scholar PubMed

Fasih, A. (2021). Lethal coagulopathy resulting from the consumption of contaminated synthetic cannabinoids: The story of a public health crisis. J Public Health (Oxf), 43, e1–e6.Google Scholar

Fattore, L. (2013). Considering gender in cannabinoid research: A step towards personalized treatment of marijuana addicts. Drug Test Anal, 5, 57–61.Google Scholar

Fattore, L. (2016). Synthetic cannabinoids: Further evidence supporting the relationship between cannabinoids and psychosis. Biol Psychiatry, 79, 539–548.Google Scholar

Fattore, L., and Fratta, W. (2010). How important are sex differences in cannabinoid action? Br J Pharmacol, 160, 544–548.Google Scholar

Fattore, L., and Fratta, W. (2011). Beyond THC: The new generation of cannabinoid designer drugs. Front Behav Neurosci, 5, 60.Google Scholar

Fattore, L., Marti, M., Mostallino, R., et al. (2020). Sex and gender differences in the effects of novel psychoactive substances. Brain Sci, 10, 606.Google Scholar

Ferk, F., Gminski, R., Al-Serori, H., et al. (2016). Genotoxic properties of XLR-11, a widely consumed synthetic cannabinoid, and of the benzoyl indole RCS-4. Arch Toxicol, 90, 3111–3123.Google Scholar

Forrester, M. B., Kleinschmidt, K., Schwarz, E., et al. (2011). Synthetic cannabinoid exposures reported to Texas poison centers. J Addict Dis, 30, 351–358.Google Scholar

Gampfer, T. M., Wagmann, L., Belkacemi, A., et al. (2021). Cytotoxicity, metabolism, and isozyme mapping of the synthetic cannabinoids JWH-200, A-796260, and 5F-EMB-PINACA studied by means of in vitro systems. Arch Toxicol, 95, 3539–3557.Google Scholar

Grafinger, K. E., Cannaert, A., Ametovski, A., et al. (2021a). Systematic evaluation of a panel of 30 synthetic cannabinoid receptor agonists structurally related to MMB-4en-PICA, MDMB-4en-PINACA, ADB-4en-PINACA, and MMB-4CN-BUTINACA using a combination of binding and different CB1 receptor activation assays-Part II: Structure activity relationship assessment via a β-arrestin recruitment assay. Drug Test Anal, 13, 1402–1411.Google Scholar

Grafinger, K. E., Vandeputte, M. M., Cannaert, A., et al. (2021b). Systematic evaluation of a panel of 30 synthetic cannabinoid receptor agonists structurally related to MMB-4en-PICA, MDMB-4en-PINACA, ADB-4en-PINACA, and MMB-4CN-BUTINACA using a combination of binding and different CB1 receptor activation assays. Part III: The G protein pathway and critical comparison of different assays. Drug Test Anal, 13, 1412–1429.Google Scholar

Guler, E. M., Bektay, M. Y., Akyildiz, A. G., et al. (2020). Investigation of DNA damage, oxidative stress, and inflammation in synthetic cannabinoid users. Hum Exp Toxicol, 39, 1454–1462.Google Scholar

Gunderson, E. W., Haughey, H. M., Ait-Daoud, N., et al. (2012). ‘Spice’ and ‘K2’ herbal highs: A case series and systematic review of the clinical effects and biopsychosocial implications of synthetic cannabinoid use in humans. Am J Addict, 21, 320–326.CrossRef Google Scholar PubMed

Gutierrez, K. M., and Cooper, T. V. (2014). Investigating correlates of synthetic marijuana and salvia use in light and intermittent smokers and college students in a predominantly Hispanic sample. Exp Clin Psychopharmacol, 22, 524–529.Google Scholar

Haden, M., Archer, J. R., Dargan, P. I., et al. (2017). MDMB-CHMICA: Availability, patterns of use, and toxicity associated with this novel psychoactive substance. Subst Use Misuse, 52, 223–232.Google Scholar

Hermanns-Clausen, M., Kneisel, S., Szabo, B., et al. (2013). Acute toxicity due to the confirmed consumption of synthetic cannabinoids: Clinical and laboratory findings. Addiction, 108, 534–544.Google Scholar

Hiranita, T. (2015). Self-administration of JWH-018 a synthetic cannabinoid in experimentally naïve rats. J Alcohol Drug Depend, 3, e128.Google Scholar

Hobbs, M., Kalk, N. J., Morrison, P. D., et al. (2018). Spicing it up: Synthetic cannabinoid receptor agonists and psychosis: A systematic review. Eur Neuropsychopharmacol, 28, 1289–1304.Google Scholar

Hurst, D., Loeffler, G., and McLay, R. (2011). Psychosis associated with synthetic cannabinoid agonists: A case series. Am J Psychiatry, 168, 1119.Google Scholar

Joseph, A. M., Manseau, M. W., Lalane, M., et al. (2017). Characteristics associated with synthetic cannabinoid use among patients treated in a public psychiatric emergency setting. Am J Drug Alcohol Abuse, 43, 117–122.Google Scholar

Kaneko, S. (2017). Motor vehicle collisions caused by the ‘super-strength’ synthetic cannabinoids, MAM-2201, 5F-PB-22, 5F-AB-PINACA, 5F-AMB and 5F-ADB in Japan experienced from 2012 to 2014. Forensic Toxicol, 35, 244–251.Google Scholar

Karinen, R., Tuv, S. S., Øiestad, E. L., et al. (2015). Concentrations of APINACA, 5F-APINACA, UR-144 and its degradant product in blood samples from six impaired drivers compared to previous reported concentrations of other synthetic cannabinoids. Forensic Sci Int, 246, 98–103.Google Scholar

Koller, V. J., Auwärter, V., Grummt, T., et al. (2014). Investigation of the in vitro toxicological properties of the synthetic cannabimimetic drug CP-47,497-C8. Toxicol Appl Pharmacol, 277, 164–171.Google Scholar

Koller, V. J., Ferk, F., Al-Serori, H., et al. (2015). Genotoxic properties of representatives of alkylindazoles and aminoalkyl-indoles which are consumed as synthetic cannabinoids. Food Chem Toxicol, 80, 130–136.Google Scholar

Langer, N., Lindigkeit, R., Schiebel, H. M., et al. (2016). Identification and quantification of synthetic cannabinoids in ‘spice-like’ herbal mixtures: Update of the German situation for the spring of 2016. Forensic Sci Int, 269, 31–41.Google Scholar

Lapoint, J., James, L. P., Moran, C. L., et al. (2011). Severe toxicity following synthetic cannabinoid ingestion. Clin Toxicol, 49, 760–764.Google Scholar

Lemos, N. P. (2014). Driving under the influence of synthetic cannabinoid receptor agonist XLR-11. J Forensic Sci, 59, 1679–1683.CrossRef Google Scholar PubMed

Lenzi, M., Cocchi, V., Cavazza, L., et al. (2020). Genotoxic properties of synthetic cannabinoids on TK6 human cells by flow cytometry. Int J Mol Sci, 21, 1150.Google Scholar

Louis, A., Peterson, B. L., and Couper, F. J. (2014). XLR-11 and UR-144 in Washington state and state of Alaska driving cases. J Anal Toxicol, 38, 563–568.CrossRef Google Scholar PubMed

Martinotti, G., Santacroce, R., Papanti, D., et al. (2017). Synthetic cannabinoids: Psychopharmacology, clinical aspects, psychotic onset. CNS Neurol Disord Drug Targets, 16, 567–575.Google Scholar

McCain, K. R., Jones, J. O., Chilbert, K. T., et al. (2018). Impaired driving associated with the synthetic cannabinoid 5F-Adb. J Forensic Sci Criminol, 6, 10.15744/2348-9804.6.105.Google Scholar

Meijer, K. A., Russo, R. R., and Adhvaryu, D. V. (2014). Smoking synthetic marijuana leads to self-mutilation requiring bilateral amputations. Orthopedics, 37, 391–394.Google Scholar

Miliano, C., Margiani, G., Fattore, L., et al. (2018). Sales and advertising channels of new psychoactive substances (NPS): Internet, social networks, and smartphone apps. Brain Sci, 8, 123.Google Scholar

Morbiato, E., Bilel, S., Tirri, M., et al. (2020). Potential of the zebrafish model for the forensic toxicology screening of NPS: A comparative study of the effects of APINAC and methiopropamine on the behavior of zebrafish larvae and mice. Neurotoxicology, 78, 36–46.Google Scholar

Münster-Müller, S., Matzenbach, I., Knepper, T., et al. (2020). Profiling of synthesis-related impurities of the synthetic cannabinoid Cumyl-5F-PINACA in seized samples of e-liquids via multivariate analysis of UHPLC-MSn data. Drug Test Anal, 12, 119–126.Google Scholar

Musshoff, F., Madea, B., Kernbach-Wighton, G., et al. (2014). Driving under the influence of synthetic cannabinoids (‘Spice’): A case series. Int J Legal Med, 128, 59–64.Google Scholar

Nia, A. B., Mann, C., Kaur, H., et al. (2018). Cannabis use: Neurobiological, behavioral, and sex/gender considerations. Curr Behav Neurosci Rep, 5, 271–280.Google Scholar

Nia, A. B., Mann, C. L., Spriggs, S., et al. (2019). The relevance of sex in the association of synthetic cannabinoid use with psychosis and agitation in an inpatient population. J Clin Psychiatry, 80, 18m12539.Google Scholar

Ossato, A., Canazza, I., Trapella, C., et al. (2016). Effect of JWH-250, JWH-073 and their interaction on ‘tetrad’, sensorimotor, neurological and neurochemical responses in mice. Prog Neuropsychopharmacol Biol Psychiatry, 67, 31–50.Google Scholar

Ossato, A., Uccelli, L., Bilel, S., et al. (2017). Psychostimulant effect of the synthetic cannabinoid JWH-018 and AKB48: Behavioral, neurochemical, and dopamine transporter scan imaging studies in mice. Front Psychiatry, 8, 130.Google Scholar

Ossato, A., Vigolo, A., Trapella, C., et al. (2015). JWH-018 impairs sensorimotor functions in mice. Neuroscience, 300, 174–188.Google Scholar

Palamar, J. J., Acosta, P., Calderón, F. F., et al. (2017). Assessing self-reported use of new psychoactive substances: The impact of gate questions. Am J Drug Alcohol Abuse, 43, 609–617.Google Scholar

Palamar, J. J., Martins, S. S., Su, M. K., et al. (2015). Self-reported use of novel psychoactive substances in a US nationally representative survey: Prevalence, correlates, and a call for new survey methods to prevent underreporting. Drug Alcohol Depend, 156, 112–119.CrossRef Google Scholar

Peglow, S., Buchner, J., and Briscoe, G. (2012). Synthetic cannabinoid induced psychosis in a previously nonpsychotic patient. Am J Addict, 21, 287–288.Google Scholar

Peterson, B. L., and Couper, F. J. (2015). Concentrations of AB-CHMINACA and AB-PINACA and driving behavior in suspected impaired driving cases. J Anal Toxicol, 39, 642–647.Google Scholar

Rajasekaran, M., Brents, L. K., Franks, L. N., et al. (2013). Human metabolites of synthetic cannabinoids JWH-018 and JWH-073 bind with high affinity and act as potent agonists at cannabinoid type-2 receptors. Toxicol Appl Pharmacol, 269, 100–108.Google Scholar

Riley, S. B., Sochat, M., Moser, K., et al. (2019). Case of brodifacoum-contaminated synthetic cannabinoid. Clin Toxicol, 57, 143–144.Google Scholar

Roberto, A. J., Lorenzo, A., Li, K. J., et al. (2016). First-episode of synthetic cannabinoid-induced psychosis in a young adult, successfully managed with hospitalization and risperidone. Case Rep Psychiatry, 2016, 7257489.Google Scholar

Schifano, F., Corazza, O., Deluca, P., et al. (2009). Psychoactive drug or mystical incense? Overview of the online available information on spice products. Int J Cult Ment Health, 2, 137–144.Google Scholar

Seely, K. A., Lapoint, J., Moran, J. H., et al. (2012). Spice drugs are more than harmless herbal blends: A review of the pharmacology and toxicology of synthetic cannabinoids. Prog Neuropsychopharmacol Biol Psychiatry, 39, 234–243.Google Scholar

Sevinc, M. M., Kinaci, E., Bayrak, S., et al. (2015). Extraordinary cause of acute gastric dilatation and hepatic portal venous gas: Chronic use of synthetic cannabinoid. World J Gastroenterol, 21, 10704–10708.Google Scholar

Sezer, Y., Jannuzzi, A. T., Huestis, M. A., et al. (2020). In vitro assessment of the cytotoxic, genotoxic and oxidative stress effects of the synthetic cannabinoid JWH-018 in human SH-SY5Y neuronal cells. Toxicol Res, 9, 734–740.Google Scholar

Solimini, R., Busardò, F. P., Rotolo, M. C., et al. (2017). Hepatotoxicity associated to synthetic cannabinoids use. Eur Rev Med Pharmacol Sci, 21, 1–6.Google Scholar

Sud, P., Gordon, M., Tortora, L., et al. (2018). Retrospective chart review of synthetic cannabinoid intoxication with toxicologic analysis. West J Emerg Med, 19, 567–572.Google Scholar

Sweeney, B., Talebi, S., Toro, D., et al. (2016). Hyperthermia and severe rhabdomyolysis from synthetic cannabinoids. Am J Emerg Med, 34, 121.e1–2.Google Scholar

Tai, S., and Fantegrossi, W. E. (2017). Pharmacological and toxicological effects of synthetic cannabinoids and their metabolites. Curr Top Behav Neurosci, 32, 249–262.Google Scholar

Theunissen, E. L., Reckweg, J. T., Hutten, N. R. P. W., et al. (2022). Psychotomimetic symptoms after a moderate dose of a synthetic cannabinoid (JWH-018): Implications for psychosis. Psychopharmacology, 239, 1251–1261.Google Scholar

Thomas, S., Bliss, S., and Malik, M. (2012). Suicidal ideation and self-harm following K2 use. J Okla State Med Assoc, 105, 430–433.Google Scholar PubMed

Tomiyama, K. I., and Funada, M. (2021). Synthetic cannabinoid CP-55,940 induces apoptosis in a human skeletal muscle model via regulation of CB1 receptors and L-type Ca²⁺ channels. Arch Toxicol, 95, 617–630.Google Scholar

Uchiyama, N., Kikura-Hanajiri, R., Ogata, J., et al. (2010). Chemical analysis of synthetic cannabinoids as designer drugs in herbal products. Forensic Sci Int, 198, 31–38.Google Scholar

Ukaigwe, A., Karmacharya, P., and Donato, A. (2014). A gut gone to pot: A case of cannabinoid hyperemesis syndrome due to K2, a synthetic cannabinoid. Case Rep Emerg Med, 167098.Google Scholar

Van der Veer, N., and Friday, J. (2011). Persistent psychosis following the use of Spice. Schizophr Res, 130, 285–286.Google Scholar

Vidourek, R. A., King, K. A., and Burbage, M. L. (2013). Reasons for synthetic THC use among college students. J Drug Educ, 43, 353–363.Google Scholar

Wang, X. F., Galaj, E., Bi, G. H., et al. (2020). Different receptor mechanisms underlying phytocannabinoid- versus synthetic cannabinoid-induced tetrad effects: Opposite roles of CB1 /CB2 versus GPR55 receptors. Br J Pharmacol, 177, 1865–1880.Google Scholar

Weinstein, A. M., Rosca, P., Fattore, L., et al. (2017). Synthetic cathinone and cannabinoid designer drugs pose a major risk for public health. Front Psychiatry, 8, 156.Google Scholar

Wells, D. L., and Ott, C. A. (2011). The ‘new’ marijuana. Ann Pharmacother, 45, 414–417.Google Scholar

Wu, N., Danoun, S., Balayssac, S., et al. (2021). Synthetic cannabinoids in e-liquids: A proton and fluorine NMR analysis from a conventional spectrometer to a compact one. Forensic Sci Int, 324, 110813.Google Scholar

Yalçın, M., Tunalı, N., Yıldız, H., et al. (2018). Sociodemographic and clinical characteristics of synthetic cannabinoid users in a large psychiatric emergency department in Turkey. J Addict Dis, 37, 259–267.Google Scholar

Zarifi, C., and Vyas, S. (2017). Spice-y kidney failure: A case report and systematic review of acute kidney injury attributable to the use of synthetic cannabis. Perm J, 21, 16–160.Google Scholar

Zimmermann, U. S., Winkelmann, P. R., Pilhatsch, M., et al. (2009). Withdrawal phenomena and dependence syndrome after the consumption of ‘spice gold’. Dtsch Artzebl Int, 106, 464–467.Google Scholar

Zorlu, N., Di Biase, A. M., Kalaycı, Ç. Ç., et al. (2016). Abnormal white matter integrity in synthetic cannabinoid users. Eur Neuropsychopharmacol, 26, 1818–1825.Google Scholar

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Chapter 3 - Synthetic Cannabinoids

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