Category: Mental Health Treatment

What is Iprindole?

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Introduction

Iprindole, sold under the brand names Prondol, Galatur, and Tertran, is an atypical tricyclic antidepressant (TCA) that has been used in the United Kingdom and Ireland for the treatment of depression but appears to no longer be marketed.

It was developed by Wyeth and was marketed in 1967. The drug has been described by some as the first “second-generation” antidepressant to be introduced. However, it was very little-used compared to other TCAs, with the number of prescriptions dispensed only in the thousands.

Medical Uses

Iprindole was used in the treatment of major depressive disorder in dosages similar to those of other TCAs.

Contraindications

Iprindole has been associated with jaundice and hepatotoxicity and should not be taken by alcoholics or people with pre-existing liver disease. If such symptoms are encountered iprindole should be discontinued immediately.

Side Effects

Anticholinergic side effects such as dry mouth and constipation are either greatly reduced in comparison to imipramine and most other TCAs or fully lacking with iprindole. However, it still has significant antihistamine effects and therefore can produce sedation, though this is diminished relative to other TCAs similarly. Iprindole also lacks significant alpha-blocking properties, and hence does not pose a risk of orthostatic hypotension.

Overdose

Refer to Tricyclic Antidepressant Overdose.

In overdose, iprindole is much less toxic than most other TCAs and is considered relatively benign. For instance, between 1974 and 1985, only two deaths associated with iprindole were recorded in the United Kingdom, whereas 278 were reported for imipramine, although imipramine is used far more often than iprindole.

Interactions

Iprindole has been shown to be a potent inhibitor of the aromatic hydroxylation and/or N-dealkylation-mediated metabolism of many substances including, but not limited to octopamine, amphetamine, methamphetamine, fenfluramine, phenelzine, tranylcypromine, trimipramine, and fluoxetine, likely via inactivating cytochrome P450 enzymes. It also inhibits its own metabolism.

On account of these interactions, caution should be used when combining iprindole with other drugs. As an example, when administered with amphetamine or methamphetamine, iprindole increases their brain concentrations and prolongs their terminal half-lives by 2- to 3-fold, strongly augmenting both their physiological effects and neurotoxicity in the process.

Pharmacology

Pharmacodynamics

Iprindole is unique compared to most other TCAs in that it is a very weak and negligible inhibitor of the reuptake of serotonin and norepinephrine and appears to act instead as a selective albeit weak antagonist of 5-HT2 receptors; hence its classification by some as “second-generation”.

Additionally, iprindole has very weak/negligible antiadrenergic and anticholinergic activity and weak although possibly significant antihistamine activity; as such, side effects of iprindole are much less prominent relative to other TCAs, and it is well tolerated. However, iprindole may not be as effective as other TCAs, particularly in terms of anxiolysis. Based on animal research, the antidepressant effects of iprindole may be mediated through downstream dopaminergic mechanisms.

The binding affinities of iprindole for various biological targets are presented in the table to the right. It is presumed to act as an inhibitor or antagonist/inverse agonist of all sites. Considering the range of its therapeutic concentrations (e.g. 63–271 nM at 90 mg/day), only the actions of iprindole on the 5-HT2 and histamine receptors might be anticipated to be of possible clinical significance. However, it is unknown whether these actions are in fact responsible for the antidepressant effects of iprindole. The plasma protein binding of iprindole and hence its free percentage and potentially bioactive concentrations do not seem to be known.

Pharmacokinetics

Only one study appears to have evaluated the pharmacokinetics of iprindole. A single oral dose of 60 mg iprindole to healthy volunteers has been found to achieve mean peak plasma concentrations of 67.1 ng/mL (236 nmol/L) after 2 to 4 hours. The mean terminal half-life of iprindole was 52.5 hours, which is notably much longer than that of other TCAs like amitriptyline and imipramine. Following chronic treatment with 90 mg/day iprindole for 3 weeks, plasma concentrations of the drug ranged between 18 and 77 ng/mL (63–271 nmol/L). Theoretical steady-state concentrations should be reached by 99% within 15 to 20 days of treatment.

Chemistry

Iprindole is a tricyclic compound, specifically a cyclooctaindole (that is, an indole nucleus joined with a cyclooctyl ring), and possesses three rings fused together with a side chain attached in its chemical structure. It is a tertiary amine TCA, although its ring system and pharmacological properties are very different from those of other TCAs. Other tertiary amine TCAs that are similar to iprindole include butriptyline and trimipramine. The chemical name of iprindole is 3-(6,7,8,9,10,11-hexahydro-5H-cycloocta[b]indol-5-yl)-N,N-dimethylpropan-1-amine and its free base form has a chemical formula of C19H28N2 with a molecular weight of 284.439 g/mol. The drug has been used commercially as both the free base and the hydrochloride salt. The CAS Registry Number of the free base is 5560-72-5 and of the hydrochloride is 20432-64-8.

Society and Culture

Generic Names

Iprindole is the English and French generic name of the drug and its INN, USAN, BAN, and DCF, while iprindole hydrochloride is its BANM. Its generic name in Spanish and German is iprindol while its generic name in Latin is iprindolum. Iprindole was originally known unofficially as pramindole.

Brand Names

Iprindole has been marketed under the brand name Prondol by Wyeth in the United Kingdom and Ireland for the indication of major depressive disorder, and has also been sold as Galatur and Tertran by Wyeth.

Availability

Iprindole was previously available in the United Kingdom and Ireland but seems to no longer be available for medical use in any country.

This page is based on the copyrighted Wikipedia article < https://en.wikipedia.org/wiki/Iprindole >; it is used under the Creative Commons Attribution-ShareAlike 3.0 Unported License (CC-BY-SA). You may redistribute it, verbatim or modified, providing that you comply with the terms of the CC-BY-SA.

What is Etizolam?

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Introduction

Etizolam (marketed under many brand names) is a thienodiazepine derivative which is a benzodiazepine analogue. The etizolam molecule differs from a benzodiazepine in that the benzene ring has been replaced by a thiophene ring and triazole ring has been fused, making the drug a thienotriazolodiazepine.

Although a thienodiazepine, etizolam is clinically regarded as a benzodiazepine because of its mode of action via the benzodiazepine receptor and directly targeting GABAA receptors.

It possesses anxiolytic, amnesic, anticonvulsant, hypnotic, sedative and skeletal muscle relaxant properties. Etizolam is an anxiolytic found to have lower tolerance and dependence liability than benzodiazepines.

It was patented in 1972 and approved for medical use in 1983.

As of April 2021, the export of Etizolam has been banned in India.

Medical Uses

  • Short-term treatment of insomnia.
  • Anxiety disorders such as obsessive compulsive disorder (OCD) and general anxiety disorder (GAD), mostly as a short-term medication to be used purely on an at-need basis

Side Effects

Long term use may result in blepharospasms, especially in women. Doses of 4 mg or more may cause anterograde amnesia.

In rare cases, erythema annulare centrifugum skin lesions have resulted.

Tolerance, Dependence and Withdrawal

Abrupt or rapid discontinuation from etizolam, as with benzodiazepines, may result in the appearance of the benzodiazepine withdrawal syndrome, including rebound insomnia. Neuroleptic malignant syndrome, a rare event in benzodiazepine withdrawal, has been documented in a case of abrupt withdrawal from etizolam. This is particularly relevant given etizolam’s short half life relative to benzodiazepines such as diazepam resulting in a more rapid drug level decrease in blood plasma levels.

In a study that compared the effectiveness of etizolam, alprazolam, and bromazepam for the treatment of GAD, all three drugs retained their effectiveness over 2 weeks, but etizolam became more effective from 2 weeks to 4 weeks. Administering .5 mg etizolam twice daily did not induce cognitive deficits over 3 weeks when compared to placebo.

When multiple doses of etizolam, or lorazepam, were administered to rat neurons, lorazepam caused downregulation of alpha-1 benzodiazepine binding sites (tolerance/dependence), while etizolam caused an increase in alpha-2 benzodiazepine binding sites (reverse tolerance to anti-anxiety effects). Tolerance to the anticonvulsant effects of lorazepam was observed, but no significant tolerance to the anticonvulsant effects of etizolam was observed. Etizolam therefore has a reduced liability to induce tolerance, and dependence, compared with classic benzodiazepines.

Etizolam may represent a possible anxiolytic of choice with reduced liability to produce tolerance and dependence after long-term treatment of anxiety and stress syndromes.

Pharmacology

Etizolam, a thienodiazepine derivative, is absorbed fairly rapidly, with peak plasma levels achieved between 30 minutes and 2 hours. It has a mean elimination half life of about 3.4 hours. Etizolam possesses potent hypnotic properties, and is comparable with other short-acting benzodiazepines. Etizolam acts as a positive allosteric modulator of the GABAA receptor by agonising the receptor’s benzodiazepine site.

According to the Italian prescribing information sheet, etizolam belongs to a new class of diazepines, thienotriazolodiazepines. This new class is easily oxidized, rapidly metabolized, and has a lower risk of accumulation, even after prolonged treatment. Etizolam has an anxiolytic action about 6-8 times greater than that of diazepam. Etizolam produces, especially at higher dosages, a reduction in time taken to fall asleep, an increase in total sleep time, and a reduction in the number of awakenings. During tests, there were no substantial changes in deep sleep; however, it may reduce REM sleep. In EEG tests of healthy volunteers, etizolam showed some similar characteristics to tricyclic antidepressants.

Etizolam’s main metabolites in humans are alpha-hydroxyetizolam and 8-hydroxyetizolam. alpha-Hydroxyetizolam is pharmacologically active and has a half-life of approximately 8.2 hours.

Interactions

Itraconazole and fluvoxamine slow down the rate of elimination of etizolam, leading to accumulation of etizolam, therefore increasing its pharmacological effects. Carbamazepine speeds up the metabolism of etizolam, resulting in reduced pharmacological effects.

Overdose

Refer to Benzodiazepine Overdose.

Cases of intentional suicide by overdose using etizolam in combination with GABA agonists have been reported. Although etizolam has a lower LD50 than certain benzodiazepines, the LD50 is still far beyond the prescribed or recommended dose. Flumazenil, a GABA antagonist agent used to reverse benzodiazepine overdoses, inhibits the effect of etizolam as well as classical benzodiazepines such as diazepam and chlordiazepoxide.

Etizolam overdose deaths are rising – for instance, the National Records of Scotland report on drug-related deaths, ‘street’ Etizolam was a factor in (“implicated in, or potentially contributed to”) 752, or 59%, of drug-related deaths in Scotland in 2019. It is important to highlight that more than one drug contributed to the vast majority of the deaths (by way of comparison, opiates and opioids were a factor in 1092, or 86%, of drug-related deaths).

Society and Culture

Brand Names

Etilaam, Sedekopan, Etizest, Etizex, Pasaden or Depas

Legal Status

International Drug Control Conventions

On 13 December 2019, the World Health Organisation recommended Etizolam be placed in Schedule 4 of the 1971 Convention on Psychotropic Substances. This recommendation was followed by the placement of Etizolam into Schedule IV in March 2020.

Australia

Etizolam is not used medically in Australia but has been found in counterfeit Xanax pills.

Denmark

Etizolam is controlled in Denmark under the Danish Misuse of Drugs Act.

Germany

Etizolam was controlled in Germany in July 2013 but is not used medically.

Italy

Etizolam is licensed for the treatment of anxiety, insomnia and neurosis as a prescription-only medication.

India

In India, it is a prescription-only medication used for anxiety disorders, sometimes in combination with other drugs like propranolol.

United Kingdom

In the UK, etizolam has been classified as a Class C drug by the May 2017 amendment to The Misuse of Drugs Act 1971 along with several other designer benzodiazepine drugs.

United States

Etizolam is not authorised by the FDA for medical use in the U.S. However, it currently remains unscheduled at the federal level and is legal for research purposes as of March 2020. As of March 2016, etizolam is a controlled substance in the following states: Alabama, Arkansas, Florida, Georgia (as Schedule IV, whereas all other states listed here prohibit it as a Schedule I substance), Louisiana, Mississippi, Texas, South Carolina, and Virginia. It is controlled in Indiana as of 01 July 2017. It is controlled in Ohio as of February 2018. On 23 December 2022 the DEA announced it had begun consideration on the matter of placing Etizolam under temporary Schedule I status.

Misuse

Etizolam is a drug of potential misuse. Cases of etizolam dependence have been documented in the medical literature. However, conflicting reports from the World Health Organisation, made public in 1991, dispute the misuse claims. Since 1991, cases of etizolam misuse and addiction have substantially increased, due to varying levels of accessibility and cultural popularity. Pills being sold as Xanax or other benzodiazepines that are illicitly manufactured may often contain etizolam rather than their listed ingredient.

This page is based on the copyrighted Wikipedia article < https://en.wikipedia.org/wiki/Etizolam >; it is used under the Creative Commons Attribution-ShareAlike 3.0 Unported License (CC-BY-SA). You may redistribute it, verbatim or modified, providing that you comply with the terms of the CC-BY-SA.

What is Etoperidone?

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Introduction

Etoperidone, associated with several brand names, is an atypical antidepressant which was developed in the 1970s and either is no longer marketed or was never marketed. It is a phenylpiperazine related to trazodone and nefazodone in chemical structure and is a serotonin antagonist and reuptake inhibitor (SARI) similarly to them.

Brief History

Etoperidone was discovered by scientists at Angelini, who also discovered trazodone. Its development names have included ST-1191 and McN-A-2673-11. The INN etoperidone was proposed in 1976 and recommended in 1977. The drug was given brand names in Spain (Centren (Esteve) and Depraser (Lepori)) and Italy (Staff (Sigma Tau)) and was also given the brand names Axiomin and Etonin, but it is not entirely clear if it was actually marketed; the Pharmaceutical Manufacturing Encyclopedia provides no dates for commercial introduction. According to Micromedex’s Index Nominum: International Drug Directory, etoperidone was indeed previously marketed in Spain and Italy.

Medical Uses

Etoperidone was used or was intended for use as an antidepressant in the treatment of depression.

Pharmacology

Pharmacodynamics

Etoperidone is as an antagonist of several receptors in the following order of potency: 5-HT2A receptor (36 nM) > α1-adrenergic receptor (38 nM) > 5-HT1A receptor (85 nM) (may be a partial agonist) > α2-adrenergic receptor (570 nM); it has only very weak or negligible affinity for blocking the following receptors: D2 receptor (2,300 nM) > H1 receptor (3,100 nM) > mACh receptors (>35,000 nM). In addition to its receptor blockade, etoperidone also has weak affinity for the monoamine transporters as well: serotonin transporter (890 nM) > norepinephrine transporter (20,000 nM) > dopamine transporter (52,000 nM).

Pharmacokinetics

Etoperidone is metabolised in part to meta-chlorophenylpiperazine (mCPP), which likely accounts for its serotonergic effects.

Chemistry

Etoperidone is a phenylpiperazine and is chemically related to nefazodone and trazodone.

Society and Culture

Generic Names

Etoperidone is the generic name of the drug and its INN, while etoperidone hydrochloride is its USAN.

Brand Names

Etoperidone has been associated with the brand names Axiomin, Centren, Depraser, Etonin, and Staff.

Research

Etoperidone has been studied in dementia and found to be about as effective as thioridazine.

This page is based on the copyrighted Wikipedia article < https://en.wikipedia.org/wiki/Etoperidone >; it is used under the Creative Commons Attribution-ShareAlike 3.0 Unported License (CC-BY-SA). You may redistribute it, verbatim or modified, providing that you comply with the terms of the CC-BY-SA.

What is Doxepin?

Published on by Andrew Marshall3 Comments

Introduction

Doxepin is a medication belonging to the tricyclic antidepressant (TCA) class of drugs used to treat major depressive disorder, anxiety disorders, chronic hives, and insomnia. For hives it is a less preferred alternative to antihistamines. It has a mild to moderate benefit for sleeping problems. It is used as a cream for itchiness due to atopic dermatitis or lichen simplex chronicus.

Common side effects include sleepiness, dry mouth, constipation, nausea, and blurry vision. Serious side effects may include increased risk of suicide in those under the age of 25, mania, and urinary retention. A withdrawal syndrome may occur if the dose is rapidly decreased. Use during pregnancy and breastfeeding is not generally recommended. Although how it works for treating depression remains an area of active inquiry, it may involve increasing the levels of norepinephrine, along with blocking histamine, acetylcholine, and serotonin.

Doxepin was approved for medical use in the United States in 1969. It is available as a generic medication. In 2020, it was the 252nd most commonly prescribed medication in the United States, with more than 1 million prescriptions.

Brief History

Doxepin was discovered in Germany in 1963 and was introduced in the United States as an antidepressant in 1969. It was subsequently approved at very low doses in the United States for the treatment of insomnia in 2010.

Medical Uses

Doxepin is used as a pill to treat major depressive disorder, anxiety disorders, and chronic hives, and for short-term help with trouble remaining asleep after going to bed (a form of insomnia). As a cream it is used for short-term treatment of itchiness caused by atopic dermatitis or lichen simplex chronicus.

Insomnia

Doxepin is used in the treatment of insomnia. In 2016, the American College of Physicians advised that insomnia be treated first by treating comorbid conditions, then with cognitive behavioural therapy and behavioural changes, and then with drugs; doxepin was among those recommended for short-term help maintaining sleep, on the basis of weak evidence. The 2017 American Academy of Sleep Medicine recommendations focused on treatment with drugs were similar. A 2015 Agency for Healthcare Research and Quality review of treatments for insomnia had similar findings.

A major systematic review and network meta-analysis of medications for the treatment of insomnia published in 2022 found that doxepin had an effect size (standardized mean difference (SMD)) against placebo for treatment of insomnia at 4 weeks of 0.30 (95% CI –0.05 to 0.64). The certainty of evidence was rated as very low, and no data were available for longer-term treatment (3 months). For comparison, the other sedating antihistamines assessed, trimipramine and doxylamine, had effect sizes (SMD) at 4 weeks of 0.55 (95% CI –0.11 to 1.21) (very low certainty evidence) and 0.47 (95% CI 0.06 to 0.89) (moderate certainty evidence), respectively. Benzodiazepines and Z-drugs generally showed larger effect sizes (e.g. SMDs of 0.45 to 0.83) than doxepin, whereas the effect sizes of orexin receptor antagonists, such as suvorexant, were more similar (SMDs of 0.23 to 0.44).

Doses of doxepin used for sleep normally range from 3 to 6 mg, but high doses of up to 25 to 50 mg may be used as well.

Other Uses

A 2010 review found that topical doxepin is useful to treat itchiness.

A 2010 review of treatments for chronic hives found that doxepin had been superseded by better drugs but was still sometimes useful as a second-line treatment.

Contraindications

Known contraindications include:

  • Hypersensitivities to doxepin, other TCAs, or any of the excipients inside the product used
  • Glaucoma
  • A predisposition to developing urinary retention such as in benign prostatic hyperplasia
  • Use of monoamine oxidase inhibitors in last 14 days

Pregnancy and Lactation

Its use in pregnant and lactating women is advised against, although the available evidence suggests it is unlikely to cause negative effects on foetal development. The lack of evidence from human studies, however, means it is currently impossible to rule out any risk to the foetus and it is known to cross the placenta. Doxepin is secreted in breast milk and neonatal cases of respiratory depression in association with maternal doxepin use have been reported.

Side Effects

Doxepin’s side effects profile may differ from the list below in some countries where it is licensed to be used in much smaller doses (viz., 3 mg and 6 mg).

  • Central nervous system: fatigue, dizziness, drowsiness, lightheadedness, confusion, nightmares, agitation, increased anxiety, difficulty sleeping, seizures (infrequently), temporary confusion (delirium), rarely induction of hypomania and schizophrenia (stop medication immediately), extrapyramidal side effects (rarely), abuse in patients with polytoxicomania (rarely), ringing in the ears (tinnitus)
  • Anticholinergic: dry mouth, constipation, even ileus (rarely), difficulties in urinating, sweating, precipitation of glaucoma
  • Antiadrenergic: Low blood pressure, (if patient arises too fast from the lying/sitting position to standing—known as orthostatic hypotension), abnormal heart rhythms (e.g. sinus tachycardia, bradycardia, and atrioventricular block)
  • Allergic/toxic: skin rash, photosensitivity, liver damage of the cholestatic type (rarely), hepatitis (extremely rare), leuko- or thrombocytopenia (rarely), agranulocytosis (very rarely), hypoplastic anaemia (rarely)
  • Others: frequently increased appetite and weight gain, rarely nausea, rarely high blood pressure. May increase or decrease liver enzyme levels in the blood of some people.

Overdose

Refer to Tricyclic Antidepressant Overdose.

Like other TCAs, doxepin is highly toxic in cases of overdose. Mild symptoms include drowsiness, stupor, blurred vision, and excessive dryness of mouth. More serious adverse effects include respiratory depression, hypotension, coma, convulsions, cardiac arrhythmia, and tachycardia. Urinary retention, decreased gastrointestinal motility (paralytic ileus), hyperthermia (or hypothermia), hypertension, dilated pupils, and hyperactive reflexes are other possible symptoms of doxepin overdose. Management of overdose is mostly supportive and symptomatic, and can include the administration of a gastric lavage so as to reduce absorption of the doxepin. Supportive measures to prevent respiratory aspiration is also advisable. Antiarrhythmic agents may be an appropriate measure to treat cardiac arrhythmias resulting from doxepin overdose. Slow intravenous administration of physostigmine may reverse some of the toxic effects of overdose such as anticholinergic effects. Haemodialysis is not recommended due to the high degree of protein binding with doxepin. ECG monitoring is recommended for several days after doxepin overdose due to the potential for cardiac conduction abnormalities.

Interactions

Doxepin should not be used within 14 days of using a monoamine oxidase inhibitor (MAOI) such as phenelzine due to the potential for hypertensive crisis or serotonin syndrome to develop. Its use in those taking potent CYP2D6 inhibitors such as fluoxetine, paroxetine, sertraline, duloxetine, bupropion, and quinidine is recommended against owing to the potential for its accumulation in the absence of full CYP2D6 catalytic activity. Hepatic enzyme inducers such as carbamazepine, phenytoin, and barbiturates are advised against in patients receiving TCAs like doxepin owing to the potential for problematically rapid metabolism of doxepin to occur in these individuals. Sympathomimetic agents may have their effects potentiated by TCAs like doxepin. Doxepin also may potentiate the adverse effects of anticholinergic agents such as benztropine, atropine and hyoscine (scopolamine). Tolazamide, when used in conjunction with doxepin has been associated with a case of severe hypoglycaemia in a type II diabetic individual. Cimetidine may influence the absorption of doxepin. Alcohol may potentiate some of the CNS depressant effects of doxepin. Antihypertensive agents may have their effects mitigated by doxepin. Cotreatment with CNS depressants such as the benzodiazepines can cause additive CNS depression. Co-treatment with thyroid hormones may also increase the potential for adverse reactions.

Pharmacology

Doxepin is a tricyclic antidepressant (TCA). It acts as a serotonin–norepinephrine reuptake inhibitor (SNRI) (a reuptake inhibitor of serotonin and norepinephrine), with additional antiadrenergic, antihistamine, antiserotonergic, and anticholinergic activities.

Pharmacodynamics

Doxepin is a reuptake inhibitor of serotonin and norepinephrine, or a SNRI, and has additional antiadrenergic, antihistamine, antiserotonergic, and anticholinergic activities. It is specifically an antagonist of the histamine H1 and H2 receptors, the serotonin 5-HT2A and 5-HT2C receptors, the α1-adrenergic receptor, and the muscarinic acetylcholine receptors (M1–M5). Similarly to other TCAs, doxepin is often prescribed as an effective alternative to SSRI medications. Doxepin is also a potent blocker of voltage-gated sodium channels, and this action is thought to be involved in both its lethality in overdose and its effectiveness as an analgesic (including in the treatment of neuropathic pain, and as a local anaesthetic). The potencies of doxepin in terms of its receptor antagonism specifically are as follows:

  • Extremely strong: Histamine H1 receptor
  • Strong: α1-adrenergic receptor, 5-HT2A and muscarinic acetylcholine receptors
  • Moderate: 5-HT2C and 5-HT1A receptors
  • Weak: α2-adrenergic and D2 receptors

Based on its IC50 values for monoamine reuptake inhibition, doxepin is relatively selective for the inhibition of norepinephrine reuptake, with a much weaker effect on the serotonin transporter. Although there is a significant effect that takes place at one of the specific serotonergic binding sites, the 5-HT2A serotonin receptor subtype. There is negligible influence on dopamine reuptake.

The major metabolite of doxepin, nordoxepin (desmethyldoxepin), is pharmacologically active similarly, but relative to doxepin, is much more selective as a norepinephrine reuptake inhibitor. In general, the demethylated variants of tertiary amine TCAs like nordoxepin are much more potent inhibitors of norepinephrine reuptake, less potent inhibitors of serotonin reuptake, and less potent in their antiadrenergic, antihistamine, and anticholinergic activities.

Antidepressant doses of doxepin are defined as 25 to 300 mg/day, although are typically above 75 mg/day. Antihistamine doses, including for dermatological uses and as a sedative/hypnotic for insomnia, are considered to be 3 to 25 mg, although higher doses between 25 and 50 mg and in some cases even up to 150 mg have been used to treat insomnia. At low doses, below 25 mg, doxepin is a pure antihistamine and has more of a sedative effect. At antidepressant doses of above 75 mg, doxepin is more stimulating with antiadrenergic, antiserotonergic, and anticholinergic effects, and these activities contribute to its side effects.

Doxepin is a mixture of (E) and (Z) stereoisomers with an approximate ratio of 85:15. When doxepin was developed, no effort was made to separate or balance the mixture following its synthesis, resulting in the asymmetric ratio. (Z)-Doxepin is more active as an inhibitor of serotonin and norepinephrine reuptake than (E)-doxepin. The selectivity of doxepin for inhibition of norepinephrine reuptake over that of serotonin is likely due to the 85% presence of (E)-doxepin in the mixture. Most other tertiary amine TCAs like amitriptyline and imipramine do not exhibit E-Z isomerism or such mixture asymmetry and are comparatively more balanced inhibitors of serotonin and norepinephrine reuptake.

As a Hypnotic

Doxepin is a highly potent antihistamine, with this being its strongest activity. In fact, doxepin has been said to be the most or one of the most potent H1 receptor antagonists available, with one study finding an in vitro Ki of 0.17 nM. It is the most potent and selective H1 receptor antagonist of the TCAs (although the tetracyclic antidepressant (TeCA) mirtazapine is slightly more potent), and other sedating antihistamines, for instance the over-the-counter diphenhydramine (Ki = 16 nM) and doxylamine (Ki = 42 nM), show far lower affinities for this receptor in comparison. The affinity of doxepin for the H1 receptor is far greater than its affinity for other sites, and 10- to 100-fold higher doses are needed for antidepressant effects. In accordance, although it is often described as a “dirty drug” due to its highly promiscuous binding profile, doxepin acts as a highly selective antagonist of the H1 receptor at very low doses (less than 10 mg; typically 3 to 6 mg). At these doses, it notably has no clinically relevant anticholinergic effects such as dry mouth or cognitive/memory impairment, unlike most other sedating antihistamines, and similarly has no effect on other receptors such as adrenergic and serotonin receptors.

The H1 receptor antagonism of doxepin is responsible for its hypnotic effects and its effectiveness in the treatment of insomnia at low doses. The incidence of side effects with doxepin and its safety at these doses was similar to that of placebo in clinical trials; the most frequent side effects were headache and somnolence/sedation, both with an incidence of less than 5%. Other side effects sometimes associated with antihistamines, including daytime sedation, increased appetite, and weight gain, all were not observed. Clinical evidence of H1 receptor antagonists and TCAs for the treatment insomnia shows mixed effectiveness and is limited in its quality due to weaknesses like small sample sizes and poor generalisability. However, doxepin is a unique and notable exception; it has been well-studied in the treatment of insomnia and shows consistent benefits with excellent tolerability and safety. Aside from diphenhydramine and doxylamine, which have historical approval as hypnotics, doxepin is the only H1 receptor antagonist that is specifically approved for the treatment of insomnia in the United States.

The effect sizes of very low-dose doxepin in the treatment of insomnia range from small to medium. These include subjective and objective measures of sleep maintenance, sleep duration, and sleep efficiency. Conversely, very low-dose doxepin shows relatively weak effects on sleep initiation and does not significantly separate from placebo on this measure. This is in contrast to benzodiazepines and nonbenzodiazepine (Z-drug) hypnotics, which are additionally effective in improving sleep onset latency. However, it is also in contrast to higher doses of doxepin (50 to 300 mg/day), which have been found to significantly reduce latency to sleep onset. A positive dose–response relationship on sleep measures was observed for doses of doxepin between 1 and 6 mg in clinical studies, whereas the incidence of adverse effects remained constant across this dose range in both young and older adults. However, the incidence of adverse effects appeared to increase with longer treatment duration. A dose of doxepin as low as 1 mg/day was found to significantly improve most of the assessed sleep measures, but unlike the 3 and 6 mg/day doses, was not able to improve wake time during sleep. This, along with greater effect sizes with the higher doses, was likely the basis for the approval of the 3 and 6 mg doses of doxepin for insomnia and not the 1 mg dose.

At very low doses, doxepin has not shown discontinuation or withdrawal effects nor rebound insomnia. Sustained effectiveness without apparent tolerance was demonstrated in clinical studies of up to 12 weeks duration. This appears to be in contrast to over-the-counter antihistamines like diphenhydramine and doxylamine and all other first-generation antihistamines, which are associated with rapid development of tolerance and dependence (by day 3 or 4 of continuous dosing) and loss of hypnotic effectiveness. It is for this reason that, unlike doxepin, they are not recommended for the chronic management of insomnia and are advised for only short-term treatment (i.e. 1 week). It is not entirely clear why doxepin and first-generation antihistamines are different in this regard, but it has been suggested that it may have to do with the lack of selectivity for the H1 receptor of the latter or may have to do with the use of optimal doses. Unlike very-low-dose doxepin, most first-generation antihistamines also have marked anticholinergic activity as well as associated side effects such as dry mouth, constipation, urinary retention, and confusion. This is particularly true in older people, and antihistamines with concomitant anticholinergic effects are not recommended in adults over the age of 65. Anticholinergic activity notably may interfere with the sleep-promoting effects of H1 receptor blockade.

Antagonism of the H1, 5-HT2A, 5-HT2C, and α1-adrenergic receptors is thought to have sleep-promoting effects and to be responsible for the sedative effects of TCAs including those of doxepin. Although doxepin is selective for the H1 receptor at doses lower than 25 mg, blockade of serotonin and adrenergic receptors may also be involved in the hypnotic effects of doxepin at higher doses. However, in contrast to very low doses of doxepin, rebound insomnia and daytime sedation are significantly more frequent than placebo with moderate doses (25 to 50 mg/day) of the drug. In addition, one study found that although such doses of doxepin improved sleep measures initially, most of the benefits were lost with chronic treatment (by 4 weeks). Due to limited data however, more research on potential tolerance and withdrawal effects of moderate doses of doxepin is needed. At these doses of doxepin, dry mouth, an anticholinergic effect, was common (71%), and other side effects such as headache (25%), increased appetite (21%), and dizziness (21%) were also frequently observed, although these adverse effects were notably not significantly more frequent than with placebo in the study in question. In any case, taken together, higher doses of doxepin than very low doses are associated with an increased rate of side effects as well as apparent loss of hypnotic effectiveness with chronic treatment.

Doxepin at a dose of 25 mg/day for 3 weeks has been found to decrease cortisol levels by 16% in adults with chronic insomnia and to increase melatonin production by 26% in healthy volunteers. In individuals with neuroendocrine dysregulation in the form of nocturnal melatonin deficiency presumably due to chronic insomnia, very-low-dose doxepin was found to restore melatonin levels to near-normal values after 3 weeks of treatment. These findings suggest that normalization of the hypothalamic–pituitary–adrenal axis and the circadian sleep–wake cycle may be involved in the beneficial effects of doxepin on sleep and insomnia.

CYP2D6 Inhibition

Doxepin has been identified as an inhibitor of CYP2D6 in vivo in a study of human patients being treated with 75 to 250 mg/day for depression. While it significantly altered metabolic ratios for sparteine and its metabolites, doxepin did not convert any of the patients to a different metabolizer phenotype (e.g. extensive to intermediate or poor). Nonetheless, inhibition of CYP2D6 by doxepin could be of clinical importance.

Pharmacokinetics

Absorption

Doxepin is well-absorbed from the gastrointestinal tract but between 55 and 87% undergoes first-pass metabolism in the liver, resulting in a mean oral bioavailability of approximately 29%. Following a single very low dose of 6 mg, peak plasma levels of doxepin are 0.854 ng/mL (3.06 nmol/L) at 3 hours without food and 0.951 ng/mL (3.40 nmol/L) at 6 hours with food. Plasma concentrations of doxepin with antidepressant doses are far greater, ranging between 50 and 250 ng/mL (180 to 900 nmol/L). Area-under-curve levels of the drug are increased significantly when it is taken with food.

Distribution

Doxepin is widely distributed throughout the body and is approximately 80% plasma protein-bound, specifically to albumin and α1-acid glycoprotein.

Metabolism

Doxepin is extensively metabolized by the liver via oxidation and N-demethylation. Its metabolism is highly stereoselective. Based on in vitro research, the major enzymes involved in the metabolism of doxepin are the cytochrome P450 enzymes CYP2D6 and CYP2C19, with CYP1A2, CYP2C9, and CYP3A4 also involved to a lesser extent. The major active metabolite of doxepin, nordoxepin, is formed mainly by CYP2C19 (>50% contribution), while CYP1A2 and CYP2C9 are involved to a lesser extent, and CYP2D6 and CYP3A4 are not involved. Both doxepin and nordoxepin are hydroxylated mainly by CYP2D6, and both doxepin and nordoxepin are also transformed into glucuronide conjugates. The elimination half-life of doxepin is about 15–18 hours, whereas that of nordoxepin is around 28–31 hours. Up to 10% of Caucasian individuals show substantially reduced metabolism of doxepin that can result in up to 8-fold elevated plasma concentrations of the drug compared to normal.

Nordoxepin is a mixture of (E) and (Z) stereoisomers similarly to doxepin. Whereas pharmaceutical doxepin is supplied in an approximate 85:15 ratio mixture of (E)- and (Z)-stereoisomers and plasma concentrations of doxepin remain roughly the same as this ratio with treatment, plasma levels of the (E)- and (Z)-stereoisomers of nordoxepin, due to stereoselective metabolism of doxepin by cytochrome P450 enzymes, are approximately 1:1.

Elimination

Doxepin is excreted primarily in the urine and predominantly in the form of glucuronide conjugates, with less than 3% of a dose excreted unchanged as doxepin or nordoxepin.

Pharmacogenetics

Since doxepin is mainly metabolized by CYP2D6, CYP2C9, and CYP2C19, genetic variations within the genes coding for these enzymes can affect its metabolism, leading to changes in the concentrations of the drug in the body. Increased concentrations of doxepin may increase the risk for side effects, including anticholinergic and nervous system adverse effects, while decreased concentrations may reduce the drug’s efficacy.

Individuals can be categorized into different types of cytochrome P450 metabolisers depending on which genetic variations they carry. These metaboliser types include poor, intermediate, extensive, and ultrarapid metabolisers. Most people are extensive metabolisers, and have “normal” metabolism of doxepin. Poor and intermediate metabolisers have reduced metabolism of the drug as compared to extensive metabolisers; patients with these metaboliser types may have an increased probability of experiencing side effects. Ultrarapid metabolisers break down doxepin much faster than extensive metabolisers; patients with this metaboliser type may have a greater chance of experiencing pharmacological failure.

A study assessed the metabolism of a single 75 mg oral dose of doxepin in healthy volunteers with genetic polymorphisms in CYP2D6, CYP2C9, and CYP2C19 enzymes. In CYP2D6 extensive, intermediate, and poor metabolizers, the mean clearance rates of (E)-doxepin were 406, 247, and 127 L/hour, respectively (~3-fold difference between extensive and poor). In addition, the bioavailability of (E)-doxepin was about 2-fold lower in extensive relative to poor CYP2D6 metabolizers, indicating a significant role of CYP2D6 in the first-pass metabolism of (E)-doxepin. The clearance of (E)-doxepin in CYP2C9 slow metabolizers was also significantly reduced at 238 L/hour. CYP2C19 was involved in the metabolism of (Z)-doxepin, with clearance rates of 191 L/hour in CYP2C19 extensive metabolisers and 73 L/hour in poor metabolisers (~2.5-fold difference). Area-under-the-curve (0–48 hour) levels of nordoxepin were dependent on the genotype of CYP2D6 with median values of 1.28, 1.35, and 5.28 nM•L/hour in CYP2D6 extensive, intermediate, and poor metabolisers, respectively (~4-fold difference between extensive and poor). Taken together, doxepin metabolism appears to be highly stereoselective, and CYP2D6 genotype has a major influence on the pharmacokinetics of (E)-doxepin. Moreover, CYP2D6 poor metabolisers, as well as patients taking potent CYP2D6 inhibitors (which can potentially convert a CYP2D6 extensive metaboliser into a poor metaboliser), may be at an increased risk for adverse effects of doxepin due to their slower clearance of the drug.

Another study assessed doxepin and nordoxepin metabolism in CYP2D6 ultra-rapid, extensive, and poor metabolisers following a single 75 mg oral dose. They found up to more than 10-fold variation in total exposure to doxepin and nordoxepin between the different groups. The researchers suggested that in order to achieve equivalent exposure, based on an average dose of 100%, the dosage of doxepin might be adjusted to 250% in ultra-rapid metabolisers, 150% in extensive metabolisers, 50% in intermediate metabolisers, and 30% in poor metabolisers.

Chemistry

Doxepin is a tricyclic compound, specifically a dibenzoxepin, and possesses three rings fused together with a side chain attached in its chemical structure. It is the only TCA with a dibenzoxepin ring system to have been marketed. Doxepin is a tertiary amine TCA, with its side chain-demethylated metabolite nordoxepin being a secondary amine. Other tertiary amine TCAs include amitriptyline, imipramine, clomipramine, dosulepin (dothiepin), and trimipramine. Doxepin is a mixture of (E) and (Z) stereoisomers (the latter being known as cidoxepin or cis-doxepin) and is used commercially in a ratio of approximately 85:15. The chemical name of doxepin is (E/Z)-3-(dibenzo[b,e]oxepin-11(6H)-ylidene)-N,N-dimethylpropan-1-amine and its free base form has a chemical formula of C19H21NO with a molecular weight of 279.376 g/mol. The drug is used commercially almost exclusively as the hydrochloride salt; the free base has been used rarely. The CAS Registry Number of the free base is 1668-19-5 and of the hydrochloride is 1229-29-4.

Society and Culture

Generic Names

Doxepin is the generic name of the drug in English and German and its INN and BAN, while doxepin hydrochloride is its USAN, USP, BANM, and JAN. Its generic name in Spanish and Italian and its DCIT are doxepina, in French and its DCF are doxépine, and in Latin is doxepinum.

The cis or (Z) stereoisomer of doxepin is known as cidoxepin, and this is its INN while cidoxepin hydrochloride is its USAN.

Brand Names

It was introduced under the brand names Quitaxon and Aponal by Boehringer and as Sinequan by Pfizer.

Doxepin is marketed under many brand names worldwide, including: Adnor, Anten, Antidoxe, Colian, Deptran, Dofu, Doneurin, Dospin, Doxal, Doxepini, Doxesom, Doxiderm, Flake, Gilex, Ichderm, Li Ke Ning, Mareen, Noctaderm, Oxpin, Patoderm, Prudoxin, Qualiquan, Quitaxon, Sagalon, Silenor, Sinepin, Sinequan, Sinquan, and Zonalon. It is also marketed as a combination drug with levomenthol under the brand name Doxure.

Approvals

The oral formulations of doxepin are US Food and Drug Administration (FDA)-approved for the treatment of depression and sleep-maintenance insomnia, and its topical formulations are FDA-approved the short-term management for some itchy skin conditions. In Australia and the United Kingdom, the only licensed indications are in the treatment of major depression and pruritus in eczema.

Research

Antihistamine

Cidoxepin is under development by Elorac, Inc. for the treatment of chronic urticaria (hives). As of 2017, it is in phase II clinical trials for this indication. The drug was also under investigation for the treatment of allergic rhinitis, atopic dermatitis, and contact dermatitis, but development for these indications was discontinued.

Headache

Doxepin was under development by Winston Pharmaceuticals in an intranasal formulation for the treatment of headache. As of August 2015, it was in phase II clinical trials for this indication.

Neuropathic Pain

As of 2017, there was no good evidence that topical doxepin was useful to treat localised neuropathic pain.

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What is Dosulepin?

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Introduction

Dosulepin, also known as dothiepin and sold under the brand name Prothiaden among others, is a tricyclic antidepressant (TCA) which is used in the treatment of depression.

Dosulepin was once the most frequently prescribed antidepressant in the United Kingdom, but it is no longer widely used due to its relatively high toxicity in overdose without therapeutic advantages over other TCAs. It acts as a serotonin–norepinephrine reuptake inhibitor (SNRI) and also has other activities including antihistamine, antiadrenergic, antiserotonergic, anticholinergic, and sodium channel-blocking effects.

Brief History

Dosulepin was developed by SPOFA (then the largest producer of pharmaceutical products in the USSR). It was patented in 1962 and first appeared in the literature in 1962. The drug was first introduced for medical use in 1969, in the United Kingdom.

Medical Uses

Dosulepin is used for the treatment of major depressive disorder. There is clear evidence of the efficacy of dosulepin in psychogenic facial pain, though the drug may be needed for up to a year.

Contraindications

Contraindications include:

  • Epilepsy as it can lower the seizure threshold
  • TCAs should not be used concomitantly or within 14 days of treatment with monoamine oxidase inhibitors due to the risk for serotonin syndrome
  • Acute recovery phase following myocardial infarction as TCAs may produce conduction defects and arrhythmias
  • Liver failure
  • Hypersensitivity to dosulepin

Side Effects

Common Adverse Effects

  • Drowsiness
  • Extrapyramidal symptoms
  • Tremor
  • Disorientation
  • Dizziness
  • Paresthaesias
  • Alterations to ECG patterns
  • Dry mouth
  • Sweating
  • Urinary retention
  • Hypotension
  • Postural hypotension
  • Tachycardia
  • Palpitations
  • Arrhythmias
  • Conduction defects
  • Increased or decreased libido
  • Nausea
  • Vomiting
  • Constipation
  • Blurred vision

Less Common Adverse Effects

  • Disturbed concentration
  • Delusions
  • Hallucinations
  • Anxiety
  • Fatigue
  • Headaches
  • Restlessness
  • Excitement
  • Insomnia
  • Hypomania
  • Nightmares
  • Peripheral neuropathy
  • Ataxia
  • Incoordination
  • Seizures
  • Paralytic ileus
  • Hypertension
  • Heart block
  • Myocardial infarction
  • Stroke
  • Gynecomastia (swelling of breast tissue in males)
  • Testicular swelling
  • Impotence
  • Epigastric distress
  • Abdominal cramps
  • Parotid swellings
  • Diarrhea
  • Stomatitis (swelling of the mouth)
  • Black tongue
  • Peculiar taste sensations
  • Cholestatic jaundice
  • Altered liver function
  • Hepatitis (swelling of the liver)
  • Skin rash
  • Urticaria (hives)
  • Photosensitisation
  • Skin blisters
  • Angioneurotic edema
  • Weight loss
  • Urinary frequency
  • Mydriasis
  • Weight gain
  • Hyponatraemia (low blood sodium)
  • Movement disorders
  • Dyspepsia (indigestion)
  • Increased intraocular pressure
  • Changes in blood sugar levels
  • Thrombocytopenia (an abnormally low number of platelets in the blood. This makes one more susceptible to bleeds)
  • Eosinophilia (an abnormally high number of eosinophils in the blood)
  • Agranulocytosis (a dangerously low number of white blood cells in the blood leaving one open to potentially life-threatening infections)
  • Galactorrhoea (lactation that is non-associated with breastfeeding and lactation)

Overdose

Refer to Tricyclic Antidepressant Overdose.

The symptoms and the treatment of an overdose are largely the same as for the other TCAs. Dosulepin may be particularly toxic in overdose compared to other TCAs. The onset of toxic effects is around 4–6 hours after dosulepin is ingested. In order to minimise the risk of overdose it is advised that patients only receive a limited number of tablets at a time so as to limit their risk of overdosing. It is also advised that patients are not prescribed any medications that are known to increase the risk of toxicity in those receiving dosulepin due to the potential for mixed overdoses. The medication should also be kept out of reach of children.

Interactions

Dosulepin can potentiate the effects of alcohol and at least one death has been attributed to this combination. TCAs potentiate the sedative effects of barbiturates, tranquilisers and CNS depressants. Guanethidine and other adrenergic neuron blocking drugs can have their antihypertensive effects blocked by dosulepin. Sympathomimetics may potentiate the sympathomimetic effects of dosulepin. Due to the anticholinergic and antihistamine effects of dosulepin anticholinergic and antihistamine medications may have their effects potentiated by dosulepin and hence these combinations are advised against. Dosulepin may have its postural hypotensive effects potentiated by diuretics. Anticonvulsants may have their efficacy reduced by dosulepin due to its ability to reduce the seizure threshold.

Pharmacology

Pharmacodynamics

Dosulepin is a reuptake inhibitor of the serotonin transporter (SERT) and the norepinephrine transporter (NET), thereby acting as an SNRI. It is also an antagonist of the histamine H1 receptor, α1-adrenergic receptor, serotonin 5-HT2 receptors, and muscarinic acetylcholine receptors (mACh), as well as a blocker of voltage-gated sodium channels (VGSCs). The antidepressant effects of dosulepin are thought to be due to inhibition of the reuptake of norepinephrine and possibly also of serotonin.

Dosulepin has three metabolites, northiaden (desmethyldosulepin), dosulepin sulfoxide, and northiaden sulfoxide, which have longer terminal half-lives than that of dosulepin itself. However, whereas northiaden has potent activity similarly to dosulepin, the two sulfoxide metabolites have dramatically reduced activity. They have been described as essentially inactive, and are considered unlikely to contribute to either the therapeutic effects or side effects of dosulepin. Relative to dosulepin, northiaden has reduced activity as a serotonin reuptake inhibitor, antihistamine, and anticholinergic and greater potency as a norepinephrine reuptake inhibitor, similarly to other secondary amine TCAs. Unlike the sulfoxide metabolites, northiaden is thought to play an important role in the effects of dosulepin.

Although Heal & Cheetham (1992) reported relatively high Ki values of 12 and 15 nM for dosulepin and northiaden at the rat α2-adrenergic receptor and suggested that antagonism of the receptor could be involved in the antidepressant effects of dosulepin, Richelson & Nelson (1984) found a low KD of only 2,400 nM for dosulepin at this receptor using human brain tissue. This suggests that it in fact has low potency for this action, similarly to other TCAs.

Pharmacokinetics

Dosulepin is readily absorbed from the small intestine and is extensively metabolized on first-pass through the liver into its chief active metabolite, northiaden. Peak plasma concentrations of between 30.4 and 279 ng/mL (103–944 nmol/L) occur within 2–3 hours of oral administration. It is distributed in breast milk and crosses the placenta and blood–brain barrier. It is highly bound to plasma proteins (84%), and has a whole-body elimination half-life of 51 hours.

Chemistry

Dosulepin is a tricyclic compound, specifically a dibenzothiepine, and possesses three rings fused together with a side chain attached in its chemical structure. It is the only TCA with a dibenzothiepine ring system to have been marketed. The drug is a tertiary amine TCA, with its side chain-demethylated metabolite northiaden (desmethyldosulepin) being a secondary amine. Other tertiary amine TCAs include amitriptyline, imipramine, clomipramine, doxepin, and trimipramine. Dosulepin exhibits (E) and (Z) stereoisomerism like doxepin but in contrast the pure E or trans isomer is used medicinally. The drug is used commercially as the hydrochloride salt; the free base is not used.

Society and Culture

Generic Names

Dosulepin is the English and German generic name of the drug and its INN and BAN, while dosulepin hydrochloride is its BANM and JAN. Dothiepin is the former BAN of the drug while dothiepin hydrochloride is the former BANM and remains the current USAN. Its generic name in Spanish and Italian and its DCIT are dosulepina, in French and its DCF are dosulépine, and in Latin is dosulepinum.

Brand Names

Dosulepin is marketed throughout the world mainly under the brand name Prothiaden. It is or has been marketed under a variety of other brand names as well, including Altapin, Depresym, Dopress, Dothapax, Dothep, Idom, Prepadine, Protiaden, Protiadene, Thaden, and Xerenal.

Availability

Dosulepin is marketed throughout Europe (as Prothiaden, Protiaden, and Protiadene), Australia (as Dothep and Prothiaden), New Zealand (as Dopress) and South Africa (as Thaden). It is also available in Japan, Hong Kong, Taiwan, India, Singapore, and Malaysia. The drug is not available in the United States or Canada.

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What is Clotiapine?

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Introduction

Clotiapine (Entumine) is an atypical antipsychotic of the dibenzothiazepine chemical class.

Outline

It was first introduced in a few European countries (namely, Belgium, Italy, Spain and Switzerland), Argentina, Taiwan and Israel in 1970.

Some sources regard clotiapine as a typical antipsychotic rather than atypical due to its high incidence of extrapyramidal side effects compared to the atypicals like clozapine and quetiapine, to which it is structurally related.

Despite its profile of a relatively high incidence of extrapyramidal side effects it has demonstrated efficacy in treatment-resistant individuals with schizophrenia according to a number of psychiatrists with clinical experience with it, some weak clinical evidence supports this view too.

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What is Clovoxamine?

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Introduction

Clovoxamine (INN) (developmental code name DU-23811) is a drug that was discovered in the 1970s.

Outline

It was subsequently investigated as an antidepressant and anxiolytic agent but was never marketed.

It acts as a serotonin-norepinephrine reuptake inhibitor (SNRI), with little affinity for the muscarinic acetylcholine, histamine, adrenergic, and serotonin receptors.

The compound is structurally related to fluvoxamine.

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What is Buprenorphine/Samidorphan?

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Introduction

Buprenorphine/samidorphan (developmental code name ALKS-5461) is a combination formulation of buprenorphine and samidorphan which is under development as an add on to antidepressants in treatment-resistant depression (TRD).

ALKS-5461 failed to meet its primary efficacy endpoints in two trials from 2016. On the basis of a third study that did meet its primary endpoints, Alkermes initiated a rolling New Drug Application with the FDA.

In November 2018, a US Food and Drug Administration (FDA) panel voted against recommending approval, finding that evidence was insufficient. As such, approval of the medication was rejected in 2019. It is a κ-opioid receptor (KOR) antagonist and is being developed by Alkermes.

Brief History

ALKS-5461 was granted Fast Track Designation by the FDA for treatment-resistant depression in October 2013. During June and July 2014, three phase III clinical trials were initiated in the United States for treatment-resistant depression. Alkermes reported that the first two trials failed in 2016. In August 2017, based on the third trial, Alkermes announced the initiation of a rolling submission of a New Drug Application for ALKS-5461 to the FDA. On 31 January 2018, Alkermes submitted a New Drug Application for ALKS-5461 to the FDA for the adjunctive treatment of major depressive disorder. The submission was accepted by the FDA on 09 April 2018 after initially serving a refuse-to-file letter due to insufficient evidence of overall effectiveness.

In November 2018, an FDA advisory committee voted 21-2 against recommending approval of ALKS-5461 for MDD, setting the medication up for likely rejection. The main reason cited was insufficient evidence of effectiveness. The panel voted in favour of adequate safety having been demonstrated.

Pharmacology

Pharmacodynamics

ALKS-5461 is a (1:1 ratio) combination of:

  1. Buprenorphine, a weak partial agonist of the μ-opioid receptor (MOR), antagonist/very weak partial agonist of the κ-opioid receptor (KOR), and, to a lesser extent, antagonist of the δ-opioid receptor (DOR) and weak partial agonist of the nociceptin receptor (NOP); and
  2. Samidorphan, a preferential antagonist of the MOR (but also, to a slightly lesser extent, weak partial agonist of the KOR and DOR).

The combination of these two drugs putatively results in what is functionally a blockade of KORs with negligible activation of MORs.

κ-Opioid Receptor Antagonism

It has been known since the 1980s that buprenorphine binds to at high affinity and antagonizes the KOR.

Through activation of the KOR, dynorphins, opioid peptides that are the endogenous ligands of the KOR and that can, in many regards, be figuratively thought of as functional inverses of the morphine-like, euphoric and stress-inhibiting endorphins, induce dysphoria and stress-like responses in both animals and humans, as well as psychotomimetic effects in humans, and are thought to be essential for the mediation of the dysphoric aspects of stress. In addition, dynorphins are believed to be critically involved in producing the changes in neuroplasticity evoked by chronic stress that lead to the development of depressive and anxiety disorders, increased drug-seeking behaviour, and dysregulation of the hypothalamic-pituitary-adrenal (HPA) axis. In support of this, in knockout mice lacking the genes encoding the KOR and/or prodynorphin (the endogenous precursor of the dynorphins), many of the usual effects of exposure to chronic stress are completely absent, such as increased immobility in the forced swimming test (a widely employed assay of depressive-like behaviour) and increased conditioned place preference for cocaine (a measure of the rewarding properties and addictive susceptibility to cocaine). Accordingly, KOR antagonists show robust efficacy in animal models of depression, anxiety, anhedonia, drug addiction, and other stress-related behavioural and physiological abnormalities.

A mouse study found that knockout of the MOR or DOR or selective pharmacological ablation of the NOP did not affect the antidepressant-like effects of buprenorphine, whereas knockout of the KOR abolished the antidepressant-like effects of the drug, supporting the notion that the antidepressant-like effects of buprenorphine are indeed mediated by modulation of the KOR by the drug (and not of the MOR, DOR, or NOP). However, a subsequent study found that the MOR may play an important role in the antidepressant-like effects of buprenorphine in animals.

Buprenorphine is not a silent antagonist of the KOR but rather a weak partial agonist. In vitro, it has shown some activation of the KOR at concentrations of ≥ 100 nM, with an Emax of 22% at 30 μM; no plateau in maximal response (EC50) was observed at concentrations up to 30 μM. Samidorphan similarly shows activation of the KOR in vitro, but to an even greater extent, with an EC50 of 3.3 nM and an Emax of 36%. As such, ALKS-5461 may possess both antagonistic and agonistic potential at the KOR. Because antagonism of the KOR seems to be responsible for the antidepressant effects of ALKS-5461, this property could in theory limit the effectiveness of ALKS-5461 in the treatment of depression.

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What is Amitriptyline/Perphenazine?

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Introduction

Amitriptyline/perphenazine (Duo-Vil, Etrafon, Triavil, Triptafen) is a formulation that contains the tricyclic antidepressant amitriptyline and the medium-potency typical (first-generation) antipsychotic, perphenazine. In the United States amitriptyline/perphenazine is marketed by Mylan Pharmaceuticals Inc. and Remedy Repack Inc.

Medical Uses

In the United States amitriptyline/perphenazine is indicated for the treatment of patients with:

  • Moderate-severe anxiety and/or agitation and depression
  • Depression and anxiety in association with chronic physical disease
  • Schizophrenia with prominent depressive symptoms

Adverse Effects

Common (>1% incidence) Adverse Effects Include

  • Sedation
  • Hypertension — high blood pressure.
  • Neurological impairments (such as extrapyramidal side effects which include dystonia, akathisia, parkinsonism, muscle rigidity, etc.)
  • Anticholinergic side effects such as:
    • Blurred vision
    • Constipation
    • Dry mouth
    • Nasal congestion
  • Increased appetite
  • Weight gain
  • Nausea
  • Dizziness
  • Headache
  • Vomiting

Unknown Frequency Adverse Effects Include

  • Diarrhoea
  • Alopecia — hair loss
  • Photophobia
  • Pigmentation
  • Eczema up to exfoliative dermatitis
  • Urticaria
  • Erythema
  • Itching
  • Photosensitivity (increased sensitivity of affected skin to sunlight)
  • Hypersalivation — excessive salivation.
  • Hyperprolactinaemia — elevated blood prolactin levels. This may present with the following symptoms:
    • Galactorrhoea — the release of milk that is not associated with pregnancy or breastfeeding
    • Gynaecomastia — the development of breast tissue in males
    • Disturbances in menstrual cycle
    • Sexual dysfunction
  • Pigmentation of the cornea and lens
  • Hyperglycaemia — elevated blood glucose (sugar) levels.
  • Hypoglycaemia — low blood glucose (sugar) levels.
  • Disturbed concentration
  • Excitement
  • Anxiety
  • Insomnia
  • Restlessness
  • Nightmares
  • Weakness
  • Fatigue
  • Diaphoresis — excessive/abnormal sweating.

Uncommon/Rare Adverse Effects Include

  • Tardive dyskinesia, an often irreversible adverse effect that usually results from chronic use antipsychotic medications, especially the high-potency first-generation antipsychotics. It is characterised by slow (hence tardive), involuntary, repetitive, purposeless muscle movements.
  • Neuroleptic malignant syndrome, a potentially fatal complication of antipsychotic drug use. It is characterised by the following symptoms:
    • Muscle rigidity
    • Tremors
    • Mental status change (e.g. hallucinations, agitation, stupor, confusion, etc.)
    • Hyperthermia — elevated body temperature
    • Autonomic instability (e.g. tachycardia, high blood pressure, diaphoresis, diarrhoea, etc.)
  • Urinary retention — the inability to pass urine despite having urine to pass.
  • Blood dyscrasias e.g. agranulocytosis (a potentially fatal drop in white blood cell count), leukopenia (a drop in white blood cell counts but not to as extreme an extent as agranulocytosis), neutropoenia (a drop in neutrophil [the cells of the immune system that specifically destroy bacteria] count), thrombocytopaenia (a dangerous drop in platelet [a cell found in the blood that plays a crucial role in the blood clotting process] counts), purpura (the appearance of red or purple discolouration’s of the skin that do not blanch when pressure is applied), eosinophilia (raised eosinophil [the cells of the immune system that specifically fights off parasites] count)
  • Hepatitis — inflammation of the liver
  • Jaundice
  • Pigmentary retinopathy
  • Anaphylactoid reactions
  • Oedema — the abnormal build-up of fluids in the tissues
  • Asthma
  • Coma
  • Seizures
  • Confusional states
  • Disorientation
  • Incoordination
  • Ataxia
  • Tremors
  • Peripheral neuropathy — nerve damage
  • Numbness, tingling and paraesthesia of the extremities
  • Dysarthria
  • Syndrome of inappropriate antidiuretic hormone secretion (SIADH)
  • Tinnitus — falsely hearing ringing in the ears.
  • Alteration in EEG patterns
  • Paralytic ileus — cessation of the peristaltic waves that propel partially digested food through the digestive tract.
  • Hyperpyrexia (elevated body temperature)
  • Disturbance of accommodation
  • Increased intraocular pressure
  • Mydriasis

This page is based on the copyrighted Wikipedia article < https://en.wikipedia.org/wiki/Amitriptyline/perphenazine >; it is used under the Creative Commons Attribution-ShareAlike 3.0 Unported License (CC-BY-SA). You may redistribute it, verbatim or modified, providing that you comply with the terms of the CC-BY-SA.

What are Treatment Improvement Protocols?

Published on by Andrew MarshallLeave a comment

Introduction

Treatment Improvement Protocols (TIPs) are a series of best-practice manuals for the treatment of substance use and other related disorders.

The TIP series is published by the Substance Abuse and Mental Health Services Administration (SAMHSA), an operational division of the US Department of Health and Human Services.

SAMHSA convenes panels of clinical, research, and administrative experts to produce the content of TIPs, which are distributed to public and private substance abuse treatment facilities and individuals throughout the United States and its territories. TIPs deal with all aspects of substance abuse treatment, from intake procedures to screening and assessment to various treatment methodologies and referral to other avenues of care. TIPs also deal with administrative and programmatic issues such as funding, inter-agency collaboration, training, accreditation, and workforce development. Some TIPs also cover ancillary topics that tend to be associated with substance abuse treatment, such as co-occurring mental health problems, criminal justice issues, housing, and primary care. Once the content of a TIP has been finalised and approved by SAMHSA, the publications are printed through the US Government Printing Office.

As of February 2023, 62 TIPs have been published (although the most recent is numbered #63; see below). Most are available through the SAMHSA ‘Store.’ SAMHSA also makes newer TIPs available for download in Portable Document Format (PDF), or accessible online through the National Library of Medicine. Although TIPs frequently show up on internet auction sites and through used book sellers for varying costs, they are intended to be available for free to the public. SAMHSA does not charge for them.

The TIP Series

  • TIP 1: State Methadone Treatment Guidelines (replaced by TIP 43)
  • TIP 2: Pregnant, Substance-Using Women (replaced by TIP 51)
  • TIP 3: Screening and Assessment of Alcohol- and Other Drug-Abusing Adolescents (replaced by TIP 31)
  • TIP 4: Guidelines for the Treatment of Alcohol- and Other Drug-Abusing Adolescents (replaced by TIP 32)
  • TIP 5: Improving Treatment for Drug-Exposed Infants
  • TIP 6: Screening for Infectious Diseases Among Substance Abusers
  • TIP 7: Screening and Assessment for Alcohol and Other Drug Abuse Among Adults in the Criminal Justice System (replaced by TIP 44)
  • TIP 8: Intensive Outpatient Treatment for Alcohol and Other Drug Abuse (replaced by TIPs 46 and 47)
  • TIP 9: Assessment and Treatment of Patients with Coexisting Mental Illness and Alcohol and Other Drug Abuse
  • TIP 10: Assessment and Treatment Planning for Cocaine-Abusing Methadone-Maintained Patients
  • TIP 11: Simple Screening Instruments for Outreach for Alcohol and Other Drug Abuse and Infectious Diseases
  • TIP 12: Combining Substance Abuse Treatment with Intermediate Sanctions for Adults in the Criminal Justice System (replaced by TIP 44)
  • TIP 13: Role and Current Status of Patient Placement Criteria in the Treatment of Substance Use Disorders
  • TIP 14: Developing State Outcomes Monitoring Systems for Alcohol and Other Drug Abuse Treatment
  • TIP 15: Treatment for HIV-Infected Alcohol and Other Drug Abusers (replaced by TIP 37)
  • TIP 16: Alcohol and Other Drug Screening of Hospitalised Trauma Patients
  • TIP 17: Planning for Alcohol and Other Drug Abuse Treatment for Adults in the Criminal Justice System (replaced by TIP 44)
  • TIP 18: The Tuberculosis Epidemic: Legal and Ethical Issues for Alcohol and Other Drug Treatment Providers
  • TIP 19: Detoxification From Alcohol and Other Drugs (replaced by TIP 45)
  • TIP 20: Matching Treatment to Patient Needs in Opioid Substitution Therapy (replaced by TIP 43)
  • TIP 21: Combining Alcohol and Other Drug Abuse Treatment With Diversion for Juveniles in the Justice System
  • TIP 22: LAAM in the Treatment of Opiate Addiction (replaced by TIP 43)
  • TIP 23: Treatment Drug Courts: Integrating Substance Abuse Treatment With Legal Case Processing
  • TIP 24: A Guide to Substance Abuse Services for Primary Care Clinicians
  • TIP 25: Substance Abuse Treatment and Domestic Violence
  • TIP 26: Substance Abuse Among Older Adults
  • TIP 27: Comprehensive Case Management for Substance Abuse Treatment
  • TIP 28: Naltrexone and Alcoholism Treatment
  • TIP 29: Substance Use Disorder Treatment For People With Physical and Cognitive Disabilities
  • TIP 30: Continuity of Offender Treatment for Substance Use Disorders from Institution to Community
  • TIP 31: Screening and Assessing Adolescents for Substance Use Disorders
  • TIP 32: Treatment of Adolescents with Substance Use Disorders
  • TIP 33: Treatment for Stimulant Use Disorders
  • TIP 34: Brief Interventions and Brief Therapies for Substance Abuse
  • TIP 35: Enhancing Motivation for Change in Substance Abuse Treatment
  • TIP 36: Substance Abuse Treatment for Persons with Child Abuse and Neglect Issues
  • TIP 37: Substance Abuse Treatment for Persons with HIV/AIDS
  • TIP 38: Integrating Substance Abuse Treatment and Vocational Services
  • TIP 39: Substance Abuse Treatment and Family Therapy
  • TIP 40: Clinical Guidelines for the Use of Buprenorphine in the Treatment of Opioid Addiction
  • TIP 41: Substance Abuse Treatment: Group Therapy
  • TIP 42: Substance Abuse Treatment for Persons With Co-Occurring Disorders
  • TIP 43: Medication-Assisted Treatment for Opioid Addiction in Opioid Treatment Programs
  • TIP 44: Substance Abuse Treatment for Adults in the Criminal Justice System
  • TIP 45: Detoxification and Substance Abuse Treatment
  • TIP 46: Substance Abuse: Administrative Issues in Outpatient Treatment
  • TIP 47: Substance Abuse: Clinical Issues in Intensive Outpatient Treatment
  • TIP 48: Managing Depressive Symptoms in Substance Abuse Clients During Early Recovery
  • TIP 49: Incorporating Alcohol Pharmacotherapies Into Medical Practice
  • TIP 50: Addressing Suicidal Thoughts and Behaviours in Substance Abuse Treatment
  • TIP 51: Substance Abuse Treatment: Addressing the Specific Needs of Women
  • TIP 52: Clinical Supervision and Professional Development of the Substance Abuse Counsellor
  • TIP 53: Addressing Viral Hepatitis in People With Substance Use Disorders
  • TIP 54: Managing Chronic Pain in Adults With or in Recovery From Substance Use Disorders
  • TIP 55: Behavioural Health Services for People Who Are Homeless
  • TIP 56: Addressing the Specific Behavioural Health Needs of Men
  • TIP 57: Trauma-Informed Care in Behavioural Health Services
  • TIP 58: Addressing Foetal Alcohol Spectrum Disorders (FASD)
  • TIP 59: Improving Cultural Competence
  • TIP 60: Using Technology-Based Therapeutic Tools in Behavioural Health Services
  • TIP 61: Behavioural Health Services for American Indians and Alaska Natives
  • TIP 63: Medications for Opioid Use Disorders

This page is based on the copyrighted Wikipedia article < https://en.wikipedia.org/wiki/Treatment_Improvement_Protocols >; it is used under the Creative Commons Attribution-ShareAlike 3.0 Unported License (CC-BY-SA). You may redistribute it, verbatim or modified, providing that you comply with the terms of the CC-BY-SA.