Atipamezole Explained

Atipamezole, sold under the brand name Antisedan among others, is a synthetic α₂ adrenergic receptor antagonist used for the reversal of the sedative and analgesic effects of dexmedetomidine and medetomidine in dogs. Its reversal effect works by competing with the sedative for α₂-adrenergic receptors and displacing them. It is mainly used in veterinary medicine, and while it is only licensed for dogs and for intramuscular use, it has been used intravenously, as well as in cats and other animals(intravenous use in cats and dogs is not recommended due to the potential for cardiovascular collapse. This occurs due to profound hypotension caused by reversal of the alpha 1 effects while the reflex bradycardia is still in effect.). There is a low rate of side effects, largely due to atipamezole's high specificity for the α₂-adrenergic receptor. Atipamezole has a very quick onset, usually waking an animal up within 5 to 10 minutes.

It was originally released in 1996.^[7] It is available in as a generic medication.^[8]

Veterinary use

Atipamezole is a veterinary drug whose prime purpose is to reverse the effects of the sedative dexmedetomidine (as well as its racemic mixture, medetomidine).^{[9] [10]} It can also be used to reverse the related sedative xylazine.^[11] While it reverses both the sedative and analgesic (pain-relieving) effects of dexmedetomidine, atipamezole may not entirely reverse the cardiovascular depression that dexmedetomidine causes.^[12]

Atipamezole is licensed in the United States for intramuscular injection (IM) in dogs; it is, however, used off-label in cats, rabbits,^[13] and farm animals such as horses and cows,^[14] as well as in zoo medicine for reptiles (including tortoises, turtles, and alligators), armadillos, hippopotamuses, giraffes, okapi, and others.^{[15] [16]} It has been given intravenously (IV), subcutaneously, intraperitoneally and, in red-eared sliders, intranasally.^{[17] [18]}

Atipamezole has also been used as an antidote for various toxicities in dogs. For example, the anti-tick medication amitraz is commonly ingested by dogs who eat their anti-tick collars.^[19] Amitraz works by the same mechanism as dexmedetomidine and is thus easily reversed by atipamezole.^{[20] [21]} Atipamezole also reverses the hypotension caused by tizanidine (a muscle relaxant) toxicity, and relieves toxicity from decongestants such as ephedrine and pseudoephedrine.

Available forms

Atipamezole is sold at 5 mg/mL for ease of use: 5 times as much atipamezole as medetomidine is needed for full reversal, and because medetomidine is sold as 1 mg/mL, 1 mL of atipamezole reverses 1 mL of medetomidine.^[22] When the enantiomerically pure version of medetomidine (dexmedetomidine) was released, it was sold at 0.5 mg/mL, because it was twice as strong as medetomidine. As such, 1 mL of atipamezole also reverses 1 mL of dexmedetomidine.

Specific populations

Atipamezole is not recommended for animals that are pregnant, lactating, or slated for breeding.^[23]

Contraindications

While there are no absolute contraindications to atipamezole, it is recommended against being given with anticholinergics, as both can cause dramatic increases in heart rate. Atipamezole should also not be given too soon after an animal has been given dexmedetomidine mixed with ketamine or telazol(tiletamine); because it reverses only the dexmedetomidine, the ketamine or telazol will still be active, and the animal can wake up excited, delirious, and with muscle contractions. Some recommend not using it in dogs sedated with ketamine at all, since they can convulse due to the excitement effect.

Side effects

Atipamezole's low rate of side effects is due to its high specificity for ɑ₂-adrenergic receptors; it has very little affinity for ɑ₁-adrenergic receptors and no affinity for most serotonin, muscarinic, and dopamine receptors.^{[24] [25]} There is occasional vomiting, hypersalivation, and diarrhea. It can potentially cause CNS excitement, which can lead to tremors, tachycardia (increased heart rate), and vasodilation. The vasodilation leads to a transient decrease in blood pressure, which (in dogs) increases to normal within 10 minutes. There have been reports of transient hypoxemia.^[26] The chance of side effect can be minimized by administering atipamezole slowly.There is a possibility of the sedation reversing abruptly, leading to nervous, aggressive, or delirious dogs. Such cases are more associated with intravenous administration (which has a faster onset than IM administration). The rapid administration of atipamezole leads to sudden displacement of dexmedetomidine from peripheral ɑ₂-adrenergic receptors; this can cause a sudden drop in blood pressure, which is followed by a reflex tachycardia and hypertension.^{[27] [28]}

There have been some cases where intravenous administration of atipamezole lead to death via cardiovascular collapse. This is thought to be combination of sudden hypotension added onto the low heart rate caused by sedatives.

There is some possibility of the animal relapsing into sedation after being given atipamezole, made more likely if the original sedative was given intravenously.

Rats and monkeys have experienced increased sexual activity after being given atipamezole.^[29]

Overdose

The LD₅₀ of atipamezole for rats is 44 mg/kg when given subcutaneously. The minimum lethal dose in dogs is over 5 mg/m²; dogs have tolerated getting ten times the standard dose.^[30] Signs of overdose include panting, trembling, vomiting, and diarrhea, as well as increased blood levels of creatine kinase, aspartate transaminase, and alanine transaminase. Dogs who received atipamezole without first receiving dexmedetomidine have shown no clinical signs other than mild muscle tremors.

Pharmacology

Mechanism of action

Atipamezole is a competitive antagonist at ɑ₂-adrenergic receptors that competes with dexmedetomidine, an ɑ₂-adrenergic receptors agonist. It does not directly interact with dexmedetomidine;^[31] rather, their structural similarity allows atipamezole to easily compete for receptor binding sites.

Atipamezole reverses analgesia by blocking norepinephrine feedback inhibition on nociceptors.

Site	Ki (nM)	Species	Ref
α1	3160	Human	[32]
α2A	1.9	Human	[33]
α2B	2.2	Human
α2C	4.2	Human
The Ki refers to a drug's affinity for a receptor. The smallerthe Ki, the higher the affinity for that receptor.

Pharmacokinetics

Out of the three ɑ₂-antagonists commonly used in veterinary medicine (atipamezole, yohimbine, and tolazine), atipamezole shows the highest preference for ɑ₂- over ɑ₁-receptors, binding to them with a ratio of 8526:1. It shows no preference for a particular ɑ₂-receptor subtype.

Atipamezole has a rapid onset: it reverses the decreased heart rate caused by sedation within three minutes. The animal usually begins waking up within 5–10 minutes. In a study of over 100 dogs, more than half could stand up within 5 minutes, and 96% could stand up within 15. Atipamezole reaches maximum serum concentration within 10 minutes of IM administration. Atipamezole is distributed extensively to the tissues; at a particular time, concentrations in the brain reach two to three times the concentration in the plasma.

Atipamezole undergoes heavy first-pass metabolism in the liver, which includes the glucuronidation at nitrogen during.^[34] Metabolites are mostly excreted in the urine.^[35]

The elimination half-life is 2.6 hours in dogs and 1.3 hours rats.

Research

Atipamezole's effects on cognitive function have been studied in rats and in humans. While low doses in rats improved alertness, selective attention, learning, and recall, higher doses generally impaired cognitive function (most likely due to norepinephrine overactivity). In rats, it has also been shown to improve cognitive function decreased by strokes or brain lesions. Studies in humans have found it to increase focus but decrease multitasking abilities. Atipamezole has also been researched in humans as a potential anti-Parkinsonian.

Because atipamezole increases sexual activity in monkeys, there have been claims of its potential to treat erectile dysfunction.

Further reading

• Book: Clinical Veterinary Advisor – E-Book: Dogs and Cats. Cote E . Elsevier Health Sciences. 2010. 978-0-323-06876-5. 2nd, revised.
• Book: Anesthesia and Analgesia in Laboratory Animals. Fish RE . Academic Press. 2008. 978-0-12-373898-1. American College of Laboratory Animal Medicine series.

Notes and References

1. Web site: Antisedan Product information . health-products.canada.ca . 24 March 2011 . 5 April 2024.
2. Web site: Antisedan- atipamezole hydrochloride injection, solution . DailyMed . 18 June 2020 . 5 April 2024.
3. Web site: Contrased- atipamezole hydrochloride injection, solution . DailyMed . 1 March 2024 . 5 April 2024.
4. Web site: Cropamezole- atipamezole hydrochloride injection, solution . DailyMed . 26 December 2023 . 5 April 2024.
5. Web site: Revertased- atipamezole hydrochloride injection, solution . DailyMed . 14 September 2023 . 5 April 2024.
6. Web site: Revertidine- atipamezole hydrochloride injection, solution . DailyMed . 12 January 2023 . 5 April 2024.
7. Book: Textbook of Veterinary Internal Medicine - eBook . Ettinger SJ, Feldman EC . Elsevier Health Sciences . 2009 . 978-1-4377-0282-8 . 7th . 61 .
8. Web site: Atipamezole. Drugs.com. 2019-08-07.
9. Because dexmedetomidine is the only pharmacologically active component of medetomidine, they will both be referred to as dexmedetomidine from here on out.
10. Web site: Antisedan for Animal Use . Drugs.com . 24 February 2018.
11. Book: Saunders Handbook of Veterinary Drugs – E-Book: Small and Large Animal . Papich MG . Elsevier Health Sciences . 2010 . 978-1-4377-0192-0 . 56 .
12. Talke P, Harper D, Traber L, Richardson CR, Traber D . February 1999 . Reversal of medetomidine induced sedation by atipamezole in sheep: Effects on organ blood . Anesthesia & Analgesia . 88 . 2S . 391S . 10.1097/00000539-199902001-00388 . 0003-2999 .
13. Kim MS, Jeong SM, Park JH, Nam TC, Seo KM . Reversal of medetomidine-ketamine combination anesthesia in rabbits by atipamezole . Experimental Animals . 53 . 5 . 423–428 . October 2004 . 15516790 . 10.1538/expanim.53.423 . free .
14. Book: Veterinary Pharmacology and Therapeutics . Riviere JE, Papich MG . John Wiley & Sons . 2009 . 978-0-8138-2061-3 . illustrated . 352–355 .
15. Heaton-Jones TG, Ko JC, Heaton-Jones DL . Evaluation of medetomidine-ketamine anesthesia with atipamezole reversal in American alligators (Alligator mississippiensis) . Journal of Zoo and Wildlife Medicine . 33 . 1 . 36–44 . March 2002 . 12216791 . 10.1638/1042-7260(2002)033[0036:EOMKAW]2.0.CO;2 . 25527884 .
16. Book: Fowler's Zoo and Wild Animal Medicine, Volume 8 – E-Book . Miller RE, Fowler ME . Elsevier Health Sciences . 2014 . 978-1-4557-7399-2 . revised . 29, 358, 587, 605 .
17. Book: Current Therapy in Reptile Medicine and Surgery - E-Book . Mader DR, Divers SJ . Elsevier Health Sciences . 2013 . 978-0-323-24293-6 . 143, 387 .
18. Book: Manual of Stroke Models in Rats . Wang-Fischer Y . CRC Press . 2008 . 978-1-4200-0952-1 . 65 .
19. Book: Veterinary Toxicology . DeClementi C . Academic Press . 2007 . 978-0-12-370467-2 . Gupta R . Oxford . 1139–1158 . Chapter 91: Prevention and treatment of poisoning . 10.1016/B978-012370467-2/50188-7 .
20. Bahri L . May 2008 . Pharm Profile: Atipamezole . Compendium . 30 . 5 .
21. Book: Veterinary Toxicology . Gupta RC . Academic Press . 2007 . 978-0-12-370467-2 . Oxford . 514–517 . Chapter 46: Amitraz . 10.1016/B978-012370467-2/50143-7 .
22. Book: Veterinary Anaesthesia E-Book . Clarke KW, Trim CM . Elsevier Health Sciences . 2013 . 978-0-7020-5423-5 . 11th . 91 . 10.1016/B978 . 1 November 2024 .
23. Book: L.S.A., List of C.F.R. Sections Affected . National Archives of the United States . 2004 . 978-0-16-072065-9 . 221 .
24. Pertovaara A, Haapalinna A, Sirviö J, Virtanen R . Pharmacological properties, central nervous system effects, and potential therapeutic applications of atipamezole, a selective alpha2-adrenoceptor antagonist . CNS Drug Reviews . 11 . 3 . 273–288 . 1 September 2005 . 16389294 . 6741735 . 10.1111/j.1527-3458.2005.tb00047.x . free .
25. Book: The Practice of Veterinary Anesthesia: Small Animals, Birds, Fish and Reptiles . Sawyer D . CRC Press . 2008 . 978-1-59161-034-2 . Manson Series . 42 .
26. Book: Saunders Comprehensive Review of the NAVLE – E-Book . Schenck P . Elsevier Health Sciences . 2009 . 978-1-4377-1448-7 . 402 .
27. Book: Veterinary Anaesthesia: Principles to Practice . Dugdale A . John Wiley & Sons . 2011 . 978-1-118-27933-5 . 257, 368 .
28. Book: Reptile Medicine and Surgery - E-Book . Divers SJ, Mader DR . Elsevier Health Sciences . 2005 . 978-1-4160-6477-0 . 2 . 444 .
29. Book: Annual Reports in Medicinal Chemistry . Academic Press . 1999 . 978-0-08-058378-5 . 34 . 78 .
30. Web site: Safety Data Sheet . 20 March 2017 . Zoetis.
31. Book: Pain Management in Small Animals . Grant D . Elsevier Health Sciences . 2006 . 978-0-7506-8812-3 . 191, 199 .
32. Blaxall HS, Murphy TJ, Baker JC, Ray C, Bylund DB . Characterization of the alpha-2C adrenergic receptor subtype in the opossum kidney and in the OK cell line . The Journal of Pharmacology and Experimental Therapeutics . 259 . 1 . 323–329 . October 1991 . 1656026 .
33. Vacher B, Funes P, Chopin P, Cussac D, Heusler P, Tourette A, Marien M . Rigid analogues of the α2-adrenergic blocker atipamezole: small changes, big consequences . Journal of Medicinal Chemistry . 53 . 19 . 6986–6995 . October 2010 . 20809632 . 10.1021/jm1006269 .
34. Kaivosaari S, Salonen JS, Taskinen J . N-Glucuronidation of some 4-arylalkyl-1H-imidazoles by rat, dog, and human liver microsomes . Drug Metabolism and Disposition . 30 . 3 . 295–300 . March 2002 . 11854148 . 10.1124/dmd.30.3.295 . free .
35. Book: Small Animal Pediatrics – E-Book: The First 12 Months of Life . Peterson ME, Kutzler M . Elsevier Health Sciences . 2010 . 978-1-4377-0195-1 . 226 .