Evidence-Based Reviews

Kratom: What we know, what to tell your patients

Current Psychiatry. 2020 March;19(3):37-42

Cornel N. Stanciu, MD, MRO, FASAM, FAPA

Bryan G. Hybki, MD

Thomas M. Penders, MS, MD

Educate patients about the risks of this increasingly popular but unregulated substance.

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References

1. Henningfield JE, Fant RV, Wang DW. The abuse potential of kratom according the 8 factors of the controlled substances act: implications for regulation and research. Psychopharmacology (Berl). 2018;235(2):573-589.
2. Chang-Chien GC, Odonkor CA, Amorapanth P, et al. Is kratom the new ‘legal high’ on the block?: the case of an emerging opioid receptor agonist with substance abuse potential. Pain Physician. 2017;20(1):E195-E198.
3. Penders T, Jones WB. Kratom, a substance of increasing concern [PCSS webinar]. Providers Clinical Support System. November 28, 2018. https://pcssnow.org/event/kratom-a-substance-of-increasing-concern. Accessed January 29, 2020.
4. Grundmann O. Patterns of kratom use and health impact in the US-results from an online survey. Drug Alcohol Depend. 2017;176:63-70.
5. US Drug Enforcement Administration. Drugs of concern. https://www.dea.gov/sites/default/files/sites/getsmartaboutdrugs.com/files/publications/DoA_2017Ed_Updated_6.16.17.pdf#page=84. Updated June 16, 2017. Accessed January 29, 2020.
6. Matsumoto K, Horie S, Ishikawa H, et al. Antinociceptive effect of 7-hydroxymitragynine in mice: discovery of an orally active opioid analgesic from the Thai medicinal herb Mitragyna speciosa. Life Sciences. 2004;74(17):2143-2155.
7. Takayama H. Chemistry and pharmacology of analgesic indole alkaloids from the rubiaceous plant, Mitragyna speciosa. Chem Pharm Bull (Tokyo). 2004;52(8):916-928.
8. Suhaimi FW, Yusoff NH, Hassan R, et al. Neurobiology of kratom and its main alkaloid mitragynine. Brain Res Bull. 2016;126(pt 1):29-40.
9. Prozialeck WC, Jivan JK, Andurkar SV. Pharmacology of kratom: an emerging botanical agent with stimulant, analgesic and opioid-like effects. J Am Osteopath Assoc. 2012;112(12):792-799.
10. Kruegel AC, Uprety R, Grinnell SG, et al. 7-hydroxymitragynine is an active metabolite of mitragynine and a key mediator of its analgesic effects. ACS Cent Sci. 2019;5(6):992-1001.
11. Trakulsrichai S, Sathirakul K, Auparakkitanon S, et al. Pharmacokinetics of mitragynine in man. Drug Des Devel Ther. 2015:9:2421-2429.
12. Warner ML, Kaufman NC, Grundmann O, et al. The pharmacology and toxicology of kratom: from traditional herb to drug of abuse. Intl J Legal Med. 2016;130(1):127-138.
13. Stanciu CN, Gnanasegaram SA, Ahmed S, et al. Kratom withdrawal: a systematic review with case series. J Psychoactive Drugs. 2019;51(1):12-18.
14. Kamble SH, Sharma A, King TI, et al. Metabolite profiling and identification of enzymes responsible for the metabolism of mitragynine, the major alkaloid of Mitragyna speciosa (kratom). Xenobiotica. 2019;49(11):1279-1288.
15. Smith LC, Lin L, Hwang CS, et al. Lateral flow assessment and unanticipated toxicity of kratom. Chem Res Toxicol. 2019;32(1):113-121.
16. Saingam D, Assanangkornchai S, Geater AF, et al. Factor analytical investigation of Krathom (Mitragyna speciosa Korth.) withdrawal syndrome in Thailand. J Psychoactive Drugs. 2016;48(2):76-85.
17. Vicknasingam B, Narayanan S, Beng GT, et al. The informal use of ketum (Mitragyna speciosa) for opioid withdrawal in the northern states of peninsular Malaysia and implications for drug substitution therapy. Int J Drug Policy. 2010;21(4):283-288.
18. Saingam D, Assanangkornchai S, Geater AF, et al. Pattern and consequences of krathom (Mitragyna speciosa Korth.) use among male villagers in southern Thailand: a qualitative study. Int J Drug Policy. 2013;24(4):351-358.
19. Fernandes CT, Iqbal U, Tighe SP, et al. Kratom-induced cholestatic liver injury and its conservative management. J Investig Med High Impact Case Rep. 2019;7:2324709619836138. doi: 10.1177/2324709619836138.
20. Dorman C, Wong M, Khan A. Cholestatic hepatitis from prolonged kratom use: a case report. Hepatology. 2015;61(3):1086-1087.
21. Osborne CS, Overstreet AN, Rockey DC, et al. Drug-induced liver injury caused by kratom use as an alternative pain treatment amid an ongoing opioid epidemic. J Investig Med High Impact Case Rep. 2019;7:2324709619826167. doi: 10.1177/2324709619826167.
22. Mousa MS, Sephien A, Gutierrez J, et al. N-acetylcysteine for acute hepatitis induced by kratom herbal tea. Am J Ther. 2018;25(5):e550-e551.
23. Riverso M, Chang M, Soldevila-Pico C, et al. Histologic characterization of kratom use-associated liver injury. Gastroenterology Res. 2018;11(1):79-82.
24. Kapp FG, Maurer HH, Auwärter V, et al. Intrahepatic cholestasis following abuse of powdered kratom (Mitragyna speciosa). J Med Toxicol. 2011;7(3):227-231.
25. Antony A, Lee TP. Herb-induced liver injury with cholestasis and renal injury secondary to short-term use of kratom (Mitragyna speciosa). Am J Ther. 2019;26(4):e546-e547.
26. Palasamudram Shekar S, Rojas EE, D’Angelo CC, et al. Legally lethal kratom: a herbal supplement with overdose potential. J Psychoactive Drugs. 2019;51(1):28-30.
27. Aldyab M, Ells PF, Bui R, et al. Kratom-induced cholestatic liver injury mimicking anti-mitochondrial antibody-negative primary biliary cholangitis: a case report and review of literature. Gastroenterology Res. 2019;12(4):211-215.
28. Post S, Spiller HA, Chounthirath T. Kratom exposures reported to United States poison control centers: 2011-2017. Clinical Toxicol (Phila). 2019;57(10):847-854.
29. Eggleston W, Stoppacher R, Suen K, et al. Kratom use and toxicities in the United States. Pharmacotherapy. 2019;39(7):775-777.
30. US Food & Drug Administration. Statement from FDA Commissioner Scott Gottlieb, M.D., on the agency’s scientific evidence on the presence of opioid compounds in kratom , underscoring its potential for abuse. https://www.fda.gov/news-events/press-announcements/statement-fda-commissioner-scott-gottlieb-md-agencys-scientific-evidence-presence-opioid-compounds. Published February 6, 2019. Accessed January 29, 2020.
31. Gershman K, Timm K, Frank M, et al. Deaths in Colorado attributed to kratom. N Engl J Med. 2019;380(1):97-98.
32. Kronstrand R, Roman M, Thelander G, et al. Unintentional fatal intoxications with mitragynine and O-desmethyltramadol from the herbal blend krypton. J Anal Toxicol. 2011;35(4):242-247.
33. Hughes RL. Fatal combination of mitragynine and quetiapine - a case report with discussion of a potential herb-drug interaction. Forensic Sci Med Pathol. 2019;15(1):110-113.
34. Abdullah HMA, Haq I, Lamfers R. Cardiac arrest in a young healthy male patient secondary to kratom ingestion: is this ‘legal high’ substance more dangerous than initially thought? BMJ Case Rep. 2019;12(7):pii: e229778. doi: 10.1136/bcr-2019-229778.
35. Laboratory analysis of kratom products for heavy metals. US FDA. https://www.fda.gov/news-events/public-health-focus/laboratory-analysis-kratom-products-heavy-metals. Updated April 3, 2019. Accessed January 29, 2020.
36. FDA investigated multistate outbreak of salmonella infections linked to products reported to contain kratom. US FDA. https://www.fda.gov/food/outbreaks-foodborne-illness/fda-investigated-multistate-outbreak-salmonella-infections-linked-products-reported-contain-kratom. Updated June 29, 2018. Accessed January 14, 2020.
37. Aggarwal G, Robertson E, McKinlay J, et a., Death from kratom toxicity and the possible role of intralipid. J Intensive Care Soc. 2018;19(1):61-63.
38. Drug Facts. Kratom. Confirm Biosciences. https://www.confirmbiosciences.com/knowledge/drug-facts/kratom/. Accessed January 14, 2020.
39. Grinspoon P. How long does kratom stay in the system? Addiction Resource. https://addictionresource.com/drugs/kratom/how-long-kratom-stay-in-your-system/. Updated December 18, 2019. Accessed January 29, 2020.
40. Kaewklum D, Kaewklum M, Pootrakronchai R, et al. Detection of mitragynine and its metaboilite in urine following ingestion of leaves of Mitragyna speciosa korth. Recent Advances in Doping Analysis (13). Proceedings of the Manfred Donike Workshop, 23rd Cologne Workshop on Dope Analysis. 2005:403-406.
41. Lu S, Tran BN, Nelsen JL, et al. Quantitative analysis of mitragynine in human urine by high performance liquid chromatography-tandem mass spectrometry. J Chromatogr B Analyt Technol Biomed Life Sci. 2009;877(24):2499-2505.
42. Philipp AA, Wissenbach DK, Zoerntlein SW, et al. Studies on the metabolism of mitragynine, the main alkaloid of the herbal drug kratom, in rat and human urine using liquid chromatography-linear ion trap mass spectrometry. J Mass Spectrom. 2009;44(8):1249-1261.
43. Manda VK, Bharathi A, Ali Z, et al. Evaluation of in vitro absorption, distribution, metabolism, and excretion (ADME) properties of mitragynine, 7-hydroxymitragynine, and mitraphylline. Planta Med. 2014;80(7):568-576.
44. Davidson L, Rawat M, Stojanovski S, et al. Natural drugs, not so natural effects: neonatal abstinence syndrome secondary to ‘kratom‘. J Neonatal Perinatal Med. 2019;12(1):109-112.
45. Mackay L, Abrahams R. Novel case of maternal and neonatal kratom dependence and withdrawal. Can Fam Physician. 2018;64(2):121-122.
46. McWhirter L, Morris S. A case report of inpatient detoxification after kratom (Mitragyna speciosa) dependence. Eur Addict Res. 2010;16(4):229-231.
47. Galbis-Reig David. A case report of kratom addiction and withdrawal. WMJ. 2016;115(1):49-52; quiz 53.
48. Singh D, Müller CP, Vicknasingam BK. Kratom (Mitragyna speciose) dependence, withdrawal symptoms and craving in regular users. Drug Alcohol Depend. 2014;139:132-137.
49. Singh D, Müller CP, Vicknasingam, et al. Social functioning of kratom (Mitragyna speciosa) users in Malaysia. J Psychoactive Drugs. 2015;47(2):125-131.
50. Khazaeli A, Jerry JM, Vazirian M. Treatment of kratom withdrawal and addiction with buprenorphine. J Addict Med. 2018;12(6):493-495.
51. Buresh M. Treatment of kratom dependence with buprenorphine-naloxone maintenance. J Addict Med. 2018;12(6):481-483.
52. Overbeek DL, Abraham J, Munzer BW. Kratom (mitragynine) ingestion requiring naloxone reversal. Clin Pract Cases Emerg Med. 2019;3(1):24-26.

Mitragyna speciosa, better known as kratom, is a tropical evergreen tree that is native to Southeast Asia. Botanically, it is a member of the Rubiaceae family, as is the coffee plant, and physical laborers among indigenous populations have historically chewed the leaves or brewed them as a tea to improve endurance and reduce fatigue.¹ Kratom is psychoactive; small amounts (up to 5 g of plant material) possess stimulant properties, while larger doses (>5 g) produce opioid-like, sedative, euphoric, and antinociceptive effects.²

In recent years, kratom has gained popularity in Western parts of the world due to its unique properties and perceived safety as a botanical product. Individuals may use kratom to boost their energy, relieve pain, or treat a wide range of physical or mood problems. Increasingly, kratom is being used by people who abuse opioids to self-manage opioid withdrawal, or for its euphoric effects. But kratom carries several important risks, including addiction, serious adverse effects, and possibly death. In this article, we review the epidemiology and pharmacology of kratom, and provide some guidance for educating patients about this substance.

Widely used but not FDA approved

Although kratom is not regulated or approved by the FDA, 3 to 5 million Americans use it regularly.³ According to an internet survey, kratom users are mostly college-educated, employed white men, age 31 to 50, who take the substance to manage pain or to treat general anxiety and mood disorders.⁴ Some individuals use kratom as an opioid substitute to reduce symptoms of opioid withdrawal.⁴

Kratom is available from a wide range of manufacturers in various formulations, including powders, tablets, liquids, and gum. It is sometimes sold in combination with other agents as a single product. Low-cost, over-the-counter kratom products are available as “dietary supplements” in retail stores or online. Although the product packaging sometimes recommends a specific dose, the amount of active ingredients (as well as other agents) is unknown. Kratom is illegal in several states (Box⁵).

Box

The legal status of kratom

The use and sale of kratom is illegal in several countries, including Australia, Poland, Denmark, Sweden, Malaysia, and Vietnam. In the United States, kratom was legal to grow and purchase in all 50 states until 2015, when the Drug Enforcement Administration (DEA) identified kratom as a “substance of concern.” In August 2016, the DEA submitted a notice of intent to place mitragynine and 7-hydroxymitragynine, 2 alkaloids of kratom that have opioid-like properties, into Schedule I of the Controlled Substance Act; however, due to significant public pressure, the DEA withdrew the request in October 2016.

As of February 2020, kratom was illegal to buy, sell, or use in Wisconsin, Rhode Island, Vermont, Indiana, Arkansas, Alabama, specific counties of some states, and the District of Columbia. Legislation was pending in New York, Missouri, and Louisiana.

Source: Reference 5

The 2 alkaloids of interest

More than 40 alkaloids have been isolated from kratom leaves. The proportions of these alkaloids vary significantly depending on the environment in which the plant is grown, the breeding and harvesting techniques, and the age of the plant.⁶ Two alkaloids of significant interest are mitragynine (Figure 1) and 7-hydroxymitragynine (Figure 2), both of which are unique to M. speciosa and have opioid-like properties. Administering these alkaloids to morphine-dependent rats resulted in cross-tolerance and precipitated withdrawal when the rats were given naloxone.⁷ The potency of kratom at the mu opioid receptor has been found to exceed that of morphine.

Competitive binding studies that examined the affinity of mitragynine and 7-hydroxymitragynine at the various opioid receptor subtypes found a preference for the kappa receptors (antagonism), followed by mu (partial agonism), and lastly delta. This profile of mitragynine is very similar to that of buprenorphine.⁸ The affinity of 7-hydroxymitragynine for the mu receptor (agonism) is significantly greater than that of mitragynine.⁹ Mitragynine also interacts with noradrenergic and serotonergic pathways by stimulating postsynaptic alpha-2 adrenergic receptors and inhibiting 5-HT2A receptors.⁹ These properties are responsible for kratom’s ability to manage opioid withdrawal symptoms, which are generally attributed to a hyperactive noradrenergic system. There also is evidence that the hepatic metabolite 7-hydroxymitragynine is important in mediating the analgesic component of mitragynine.¹⁰

The initial effects of kratom typically begin within 10 to 20 minutes of consumption, and the full effects are experienced in 30 to 60 minutes.¹ The half-life of mitragynine in humans has not yet been determined, but is believed to be relatively short.¹¹ In rats, the half-life of mitragynine is 2 to 3 hours.¹² Individuals who use kratom to prevent opioid withdrawal have reported taking it as often as every 6 to 12 hours.¹³

Continue to: Metabolism of mitragynine...

Kratom: What we know, what to tell your patients

References

Widely used but not FDA approved

The 2 alkaloids of interest

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