Etoxadrol

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Etoxadrol
Etoxadrol.svg
Clinical data
ATC code
  • none
Legal status
Legal status
  • In general: legal
Identifiers
  • (2S)-2-[(2S,4S)-2-ethyl-2-phenyl-1,3-dioxolan-4-yl]piperidine
CAS Number
PubChem CID
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ChEMBL
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Chemical and physical data
Formula C16H23NO2
Molar mass 261.365 g·mol−1
3D model (JSmol)
  • CC[C@]1(C2=CC=CC=C2)OC[C@H]([C@H]3NCCCC3)O1
  • InChI=1S/C16H23NO2/c1-2-16(13-8-4-3-5-9-13)18-12-15(19-16)14-10-6-7-11-17-14/h3-5,8-9,14-15,17H,2,6-7,10-12H2,1H3/t14-,15+,16-/m0/s1 Yes check.svgY
  • Key:INOYCBNLWYEPSB-XHSDSOJGSA-N Yes check.svgY
 X mark.svgNYes check.svgY  (what is this?)    (verify)

Etoxadrol (CL-1848C) is a dissociative anaesthetic drug that has been found to be an NMDA antagonist and produce similar effects to PCP in animals. [1] [2] Etoxadrol, along with another related drug dexoxadrol, were developed as analgesics for use in humans, but development was discontinued in the late 1970s after patients reported side effects such as nightmares and hallucinations. [3] [4] [5]

Contents

Chemical structure

Phencyclidine (PCP), ketamine, etoxadrol and dexoxadrol all contain phenyl and amino groups, which bind to the PCP site on the NMDA receptor. Tenocyclidine contains a thiophene ring instead, which is bioisosteric with a phenyl ring. Chemical Structures.png
Phencyclidine (PCP), ketamine, etoxadrol and dexoxadrol all contain phenyl and amino groups, which bind to the PCP site on the NMDA receptor. Tenocyclidine contains a thiophene ring instead, which is bioisosteric with a phenyl ring.

Phenicyclidine (PCP), tenocyclidine (TCP), etoxadrol and its precursor, dexoxadrol have related chemical structures. [6] These drugs all act similarly on the nervous system, acting as dissociative hallucinogens (meaning that they interfere with normal sensory signals, replacing them with hallucinations of any sensory modality) with anesthetic and analgesic properties.

Pharmacodynamics

Etoxadrol is a non-competitive NMDA receptor antagonist. [7] It binds with high affinity to the PCP binding site on the NMDA receptor (Ki = 107 nM, determined by the displacement of radiolabeled TCP). [1] [3] Normally, the inactivated NMDA receptor possesses a magnesium (Mg2+) block in the channel, blocking the passage of cations. [8]

NMDA receptor action in the absence (left) or presence (right) of etoxadrol. NMDA Etoxadrol.png
NMDA receptor action in the absence (left) or presence (right) of etoxadrol.

When the neurotransmitter glutamate binds to the NMDA receptor, and the postsynaptic cell membrane is depolarized (from the postsynaptic cell being activated), the magnesium block in the NMDA receptor channel is displaced. Calcium (Ca2+) and sodium (Na+) can enter the cell via the open channel, while potassium (K+) can exit the cell. Etoxadrol antagonizes the NMDA receptor by binding to the PCP site, located just above the magnesium block in the ion channel. In the event that the magnesium block is displaced, etoxadrol blocks the NMDA receptor channel, preventing cations from entering or exiting the channel. This mechanism of action also applies to PCP, TCP, ketamine and dexoxadrol.

Etoxadrol binding does not affect the binding affinity of other sites on the NMDA receptor, as found by binding studies showing the displacement of radiolabeled TCP by etoxadrol (TCP binding in the absence of etoxadrol: Ki = 19.2 x 10−9 M, Bmax = 1.36 pmol/mg protein; TCP binding in the presence of etoxadrol: Ki = 21.7 x 10−9 M, Bmax = .66 pmol/mg protein). [9]

Despite its anesthetic and analgesic effects, etoxadrol does not interact with benzodiazepine, muscarinic acetylcholine, or mu opioid receptors. [9] However, etoxadrol may act in the dopamine reward pathway, explaining its reinforcing properties. [6]

Pharmacokinetics

Etoxadrol goes into effect 90 seconds after intravenous (IV) administration, and its anesthetic effects typically last for half an hour to an hour. [5] [10] Since etoxadrol is administered intravenously, the bioavailable dose is always the same as the administered dose. Etoxadrol’s analgesic effects can last for up to 2 hours or more after patients have regained consciousness. [11]

Etoxadrol is lipophilic and can readily cross the blood–brain barrier. Because of its lipophilic structure, etoxadrol can be absorbed by fat tissues and organs (e.g. the liver). Etoxadrol also acts on the respiratory and cardiovascular systems. [10]

Treatment

Etoxadrol was intended as an anesthetic for patients requiring particularly long periods of anesthesia for surgery. As an anesthetic, etoxadrol is more potent than ketamine, but less potent than PCP. [11]

Etoxadrol is also a potent analgesic. Patients given etoxadrol often reported that they were aware of experiencing pain upon waking from anesthesia, but it did not bother them. [5] Post-operative analgesics are rarely required after patients undergoing surgery are administered etoxadrol.

Etoxadrol (along with ketamine, dexoxadrol, and other PCP-like drugs) is an anticonvulsant, preventing tonic seizures in mice that are administered pentylenetetrazol (PTZ), which normally induces seizures. [12]

Side effects

Like ketamine, etoxadrol produces increases in heart rate and respiratory rate. [10] Etoxadrol may also cause vomiting. [5] At high enough doses, etoxadrol also exhibits effects on the muscular system such as convulsions or loss of the righting reflex. [13] When administered in excess, etoxadrol can be lethal on the respiratory system. Monkeys given extremely high (> 20 mg/kg) doses of etoxadrol died of apparent respiratory failure.

Etoxadrol produces a wide variety of dreams, ranging from pleasant to frightening or aversive. [11] Approximately half of patients given etoxadrol report pleasant dreams, 25% report unpleasant dreams, and the remaining 25% experience no dreams at all. Such dreams were frequently described as “floating,” “puffy” or “out of this world." Dreams and hallucinations may persist for as long as 18 to 24 hours. In rare cases, etoxadrol can induce periods of psychotic activity during this recovery period. [5]

In the brain, etoxadrol slows down the synthesis of serotonin to 50-60% of control rates and speeds up the rate of dopamine synthesis by up to 200% of the normal rate 4–6 hours after intravenous administration. [5]

Like a number of other drugs (e.g. cocaine), etoxadrol has been found to exhibit reinforcing properties. Monkeys will self-administer etoxadrol, dexoxadrol or PCP in a lever-pressing paradigm. [6]

Related Research Articles

General anaesthetics are often defined as compounds that induce a loss of consciousness in humans or loss of righting reflex in animals. Clinical definitions are also extended to include an induced coma that causes lack of awareness to painful stimuli, sufficient to facilitate surgical applications in clinical and veterinary practice. General anaesthetics do not act as analgesics and should also not be confused with sedatives. General anaesthetics are a structurally diverse group of compounds whose mechanisms encompasses multiple biological targets involved in the control of neuronal pathways. The precise workings are the subject of some debate and ongoing research.

<span class="mw-page-title-main">Ketamine</span> Dissociative medication

Ketamine is a dissociative anesthetic used medically for induction and maintenance of anesthesia. It is also used as a treatment for depression, a pain management tool, and as a recreational drug. Ketamine is a novel compound that was derived from phencyclidine in 1962, in pursuit of a safer anesthetic with fewer hallucinogenic effects.

<span class="mw-page-title-main">Phencyclidine</span> Dissociative hallucinogenic drug, mostly used recreationally

Phencyclidine or phenylcyclohexyl piperidine (PCP), also known as angel dust among other names, is a dissociative anesthetic mainly used recreationally for its significant mind-altering effects. PCP may cause hallucinations, distorted perceptions of sounds, and violent behavior. As a recreational drug, it is typically smoked, but may be taken by mouth, snorted, or injected. It may also be mixed with cannabis or tobacco.

Dissociatives, colloquially dissos, are a subclass of hallucinogens which distort perception of sight and sound and produce feelings of detachment – dissociation – from the environment and/or self. Although many kinds of drugs are capable of such action, dissociatives are unique in that they do so in such a way that they produce hallucinogenic effects, which may include dissociation, a general decrease in sensory experience, hallucinations, dream-like states or anesthesia. Despite most dissociatives’ main mechanism of action being tied to NMDA receptor antagonism, some of these substances, which are nonselective in action and affect the dopamine and/or opioid systems, may be capable of inducing more direct and repeatable euphoria or symptoms which are more akin to the effects of typical “hard drugs” or common drugs of abuse. This is likely why dissociatives are considered to be addictive with a fair to moderate potential for abuse, unlike psychedelics. Despite some dissociatives, such as phencyclidine (PCP) possessing stimulating properties, most dissociatives seem to have a general depressant effect and can produce sedation, respiratory depression, nausea, disorientation, analgesia, anesthesia, ataxia, cognitive and memory impairment as well as amnesia.

<span class="mw-page-title-main">Dizocilpine</span> Chemical compound

Dizocilpine (INN), also known as MK-801, is a pore blocker of the N-Methyl-D-aspartate (NMDA) receptor, a glutamate receptor, discovered by a team at Merck in 1982. Glutamate is the brain's primary excitatory neurotransmitter. The channel is normally blocked with a magnesium ion and requires depolarization of the neuron to remove the magnesium and allow the glutamate to open the channel, causing an influx of calcium, which then leads to subsequent depolarization. Dizocilpine binds inside the ion channel of the receptor at several of PCP's binding sites thus preventing the flow of ions, including calcium (Ca2+), through the channel. Dizocilpine blocks NMDA receptors in a use- and voltage-dependent manner, since the channel must open for the drug to bind inside it. The drug acts as a potent anti-convulsant and probably has dissociative anesthetic properties, but it is not used clinically for this purpose because of the discovery of brain lesions, called Olney's lesions (see below), in laboratory rats. Dizocilpine is also associated with a number of negative side effects, including cognitive disruption and psychotic-spectrum reactions. It inhibits the induction of long term potentiation and has been found to impair the acquisition of difficult, but not easy, learning tasks in rats and primates. Because of these effects of dizocilpine, the NMDA receptor pore blocker ketamine is used instead as a dissociative anesthetic in human medical procedures. While ketamine may also trigger temporary psychosis in certain individuals, its short half-life and lower potency make it a much safer clinical option. However, dizocilpine is the most frequently used uncompetitive NMDA receptor antagonist in animal models to mimic psychosis for experimental purposes.

<span class="mw-page-title-main">Olney's lesions</span>

Olney's lesions, also known as NMDA receptor antagonist neurotoxicity (NAN), are a form of potential brain damage due to drugs that have been studied experimentally and have produced neuronal damage, yet are administered by doctors to humans in the settings of pharmacotherapy and of anesthesia. They are named after John Olney, who conducted a study in 1989 to investigate neurotoxicity caused by PCP and related drugs.

<span class="mw-page-title-main">NMDA receptor antagonist</span> Class of anesthetics

NMDA receptor antagonists are a class of drugs that work to antagonize, or inhibit the action of, the N-Methyl-D-aspartate receptor (NMDAR). They are commonly used as anesthetics for animals and humans; the state of anesthesia they induce is referred to as dissociative anesthesia.

<span class="mw-page-title-main">Tenocyclidine</span> Chemical compound

Tenocyclidine (TCP) is a dissociative anesthetic with psychostimulant effects. It was discovered by a team at Parke-Davis in the late 1950s. It is similar in effects to phencyclidine (PCP) but is considerably more potent. TCP has slightly different binding properties to PCP, with more affinity for the NMDA receptors, but less affinity for the sigma receptors. Because of its high affinity for the PCP site of the NMDA receptor complex, the 3H radiolabelled form of TCP is widely used in research into NMDA receptors.

<span class="mw-page-title-main">Dezocine</span> Opioid analgesic

Dezocine, sold under the brand name Dalgan, is an atypical opioid analgesic which is used in the treatment of pain. It is used by intravenous infusion and intramuscular injection.

<span class="mw-page-title-main">14-Methoxymetopon</span> Chemical compound

14-Methoxymetopon is an experimental opioid drug developed by a team led by Professor Helmut Schmidhammer at the University of Insbruck in the mid 1990s. It is a derivative of metopon in which a methoxy group has been inserted at the 14-position. It is a highly potent analgesic drug that is around 500 times stronger than morphine when administered systemically; however, when given spinally or supraspinally, it exhibits analgesic activity up to a million fold greater than morphine. It binds strongly to the μ-opioid receptor and activates it to a greater extent than most similar opioid drugs. This produces an unusual pharmacological profile, and although 14-methoxymetopon acts as a potent μ-opioid full agonist in regard to some effects such as analgesia, a ceiling effect is seen on other effects such as constipation and respiratory depression which is believed to involve interaction with the κ-opioid receptor

<span class="mw-page-title-main">Selfotel</span> Chemical compound

Selfotel (CGS-19755) is a drug which acts as a competitive NMDA antagonist, directly competing with glutamate for binding to the receptor. Initial studies showed it to have anticonvulsant, anxiolytic, analgesic and neuroprotective effects, and it was originally researched for the treatment of stroke, but subsequent animal and human studies showed phencyclidine-like effects, as well as limited efficacy and evidence for possible neurotoxicity under some conditions, and so clinical development was ultimately discontinued.

<span class="mw-page-title-main">Alazocine</span> Synthetic opioid analgesic

Alazocine, also known more commonly as N-allylnormetazocine (NANM), is a synthetic opioid analgesic of the benzomorphan family related to metazocine, which was never marketed. In addition to its opioid activity, the drug is a sigma receptor agonist, and has been used widely in scientific research in studies of this receptor. Alazocine is described as a potent analgesic, psychotomimetic or hallucinogen, and opioid antagonist. Moreover, one of its enantiomers was the first compound that was found to selectively label the σ1 receptor, and led to the discovery and characterization of the receptor.

<span class="mw-page-title-main">Benocyclidine</span> Chemical compound

Benocyclidine, also known as benzo​thiophenyl​cyclo​hexylpiperidine (BTCP), is a psychoactive recreational drug of the arylcyclohexylamine class which is related to phencyclidine (PCP). It was first described in a patent application naming Marc Caron and colleagues at Duke University in 1997.

<span class="mw-page-title-main">Arylcyclohexylamine</span> Class of chemical compounds

Arylcyclohexylamines, also known as arylcyclohexamines or arylcyclohexanamines, are a chemical class of pharmaceutical, designer, and experimental drugs.

<span class="mw-page-title-main">3-MeO-PCP</span> Chemical compound

3-Methoxyphencyclidine (3-MeO-PCP) is a dissociative hallucinogen of the arylcyclohexylamine class related to phencyclidine (PCP) which has been sold online as a designer drug. It acts mainly as an NMDA receptor antagonist, though it has also been found to interact with the sigma σ1 receptor and the serotonin transporter. The drug does not possess any opioid activity nor does it act as a dopamine reuptake inhibitor.

<span class="mw-page-title-main">4-MeO-PCP</span> Chemical compound

4-Methoxyphencyclidine is a dissociative anesthetic drug that has been sold online as a research chemical. The synthesis of 4-MeO-PCP was first reported in 1965 by the Parke-Davis medicinal chemist Victor Maddox. A 1999 review published by a chemist using the pseudonym John Q. Beagle suggested the potency of 4-MeO-PCP in man was reduced relative to PCP, two years later Beagle published a detailed description of the synthesis and qualitative effects of 4-MeO-PCP, which he said possessed 70% the potency of PCP. 4-MeO-PCP was the first arylcyclohexylamine research chemical to be sold online, it was introduced in late 2008 by a company trading under the name CBAY and was followed by several related compounds such as 3-MeO-PCP and methoxetamine. 4-MeO-PCP has lower affinity for the NMDA receptor than PCP, but higher affinity than ketamine, it is orally active in a dosage range similar to ketamine, with some users requiring doses in excess of 100 mg for desired effects. Users have reported substantial differences in active dose, these discrepancies can be partially explained by the presence of unreacted PCC and other impurities in samples sold on the grey market. 4-MeO-PCP has Ki values of 404 nM for the NMDA receptor, 713 nM for the norepinephrine transporter, 844 nM for the serotonin transporter, 296 nM for the σ1 receptor and 143 nM for the σ2 receptor.

<span class="mw-page-title-main">Arketamine</span> Chemical compound

Arketamine (developmental code names PCN-101, HR-071603), also known as (R)-ketamine or (R)-(−)-ketamine, is the (R)-(−) enantiomer of ketamine. Similarly to racemic ketamine and esketamine, the S(+) enantiomer of ketamine, arketamine is biologically active; however, it is less potent as an NMDA receptor antagonist and anesthetic and thus has never been approved or marketed for clinical use as an enantiopure drug. Arketamine is currently in clinical development as a novel antidepressant.

<span class="mw-page-title-main">3-HO-PCP</span> Chemical compound

3-Hydroxyphencyclidine (3-HO-PCP) is a dissociative of the arylcyclohexylamine class related to phencyclidine (PCP) that has been sold online as a designer drug.

<span class="mw-page-title-main">PD-137889</span> Chemical compound

PD-137889 (N-methylhexahydrofluorenamine) is a chemical compound that is active as an NMDA receptor antagonist in the central nervous system at roughly 30 times the potency of the "flagship" of its class, ketamine, and substitutes for phencyclidine in animal studies. Ki [3H]TCP binding = 27 nM versus ketamine's Ki = 860 nM.

Total intravenous anesthesia (TIVA) refers to the intravenous administration of anesthetic agents to induce a temporary loss of sensation or awareness. The first study of TIVA was done in 1872 using chloral hydrate, and the common anesthetic agent propofol was licensed in 1986. TIVA is currently employed in various procedures as an alternative technique of general anesthesia in order to improve post-operative recovery.

References

  1. 1 2 Thurkauf A, Zenk PC, Balster RL, May EL, George C, Carroll FI, et al. (December 1988). "Synthesis, absolute configuration, and molecular modeling study of etoxadrol, a potent phencyclidine-like agonist". Journal of Medicinal Chemistry. 31 (12): 2257–63. doi:10.1021/jm00120a004. PMID   2903930.
  2. Thurkauf A, Mattson MV, Richardson S, Mirsadeghi S, Ornstein PL, Harrison EA, et al. (April 1992). "Analogues of the dioxolanes dexoxadrol and etoxadrol as potential phencyclidine-like agents. Synthesis and structure-activity relationships". Journal of Medicinal Chemistry. 35 (8): 1323–9. doi:10.1021/jm00086a001. PMID   1349351.
  3. 1 2 Sax M, Wünsch B (2006). "Relationships between the structure of dexoxadrol and etoxadrol analogues and their NMDA receptor affinity". Current Topics in Medicinal Chemistry. 6 (7): 723–32. doi:10.2174/156802606776894483. PMID   16719812.
  4. Aepkers M, Wünsch B (December 2005). "Structure-affinity relationship studies of non-competitive NMDA receptor antagonists derived from dexoxadrol and etoxadrol". Bioorganic & Medicinal Chemistry. 13 (24): 6836–49. doi:10.1016/j.bmc.2005.07.030. PMID   16169732.
  5. 1 2 3 4 5 6 Frederickson EL, Longnecker DE, Allen GW (May–Jun 1976). "Clinical investigation of a new intravenous anesthetic--etoxadrol hydrochloride (CL-1848; U-37862A)". Anesthesia and Analgesia. 55 (3): 335–9. doi:10.1213/00000539-197605000-00010. PMID   5921. S2CID   45801472.
  6. 1 2 3 Brady KT, Woolverton WL, Balster RL (January 1982). "Discriminative stimulus and reinforcing properties of etoxadrol and dexoxadrol in monkeys". The Journal of Pharmacology and Experimental Therapeutics. 220 (1): 56–62. PMID   6118431.
  7. Domino EF (January 1992). "Chemical dissociation of human awareness: focus on non-competitive NMDA receptor antagonists" (PDF). Journal of Psychopharmacology. 6 (3): 418–24. doi:10.1177/026988119200600312. hdl: 2027.42/68872 . PMID   22291389. S2CID   17738916.
  8. Paradiso MF, Bear BW, Connors MA (2007). Neuroscience : exploring the brain (3rd ed.). Philadelphia, PA: Lippincott Williams & Wilkins. pp.  154–155. ISBN   978-0781760034.
  9. 1 2 Thurkauf A, Mattson MV, Huguenin PN, Rice KC, Jacobson AE (October 1988). "Etoxadrol-meta-isothiocyanate: a potent, enantioselective, electrophilic affinity ligand for the phencyclidine-binding site". FEBS Letters. 238 (2): 369–74. doi: 10.1016/0014-5793(88)80514-3 . PMID   2901991. S2CID   22308090.
  10. 1 2 3 Traber DL, Priano LL, Wilson RD (November 1970). "Effects of CL 1848C, a new dissociative anesthetic, on the canine cardiovascular and respiratory systems". The Journal of Pharmacology and Experimental Therapeutics. 175 (2): 395–403. PMID   5481707.
  11. 1 2 3 Wilson RD, Traber DL, Barratt E, Creson DL, Schmitt RC, Allen CR (Mar–Apr 1970). "Evaluation of CL-1848C: a new dissociative anesthetic in normal human volunteers". Anesthesia and Analgesia. 49 (2): 236–41. doi: 10.1213/00000539-197003000-00011 . PMID   4931158. S2CID   33036876.
  12. Hayes BA, Balster RL (October 1985). "Anticonvulsant properties of phencyclidine-like drugs in mice". European Journal of Pharmacology. 117 (1): 121–5. doi:10.1016/0014-2999(85)90480-7. PMID   4085541.
  13. Hidalgo J, Dileo RM, Rikimaru MT, Guzman RJ, Thompson CR (Mar–Apr 1971). "Etoxadrol (CL-1848C) a new dissociative anesthetic: studies in primates and other species". Anesthesia and Analgesia. 50 (2): 231–9. doi:10.1213/00000539-197103000-00016. PMID   4994714. S2CID   29976263.
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