Tag: Neuroleptic Malignant Syndrome

What is Neuroleptic Malignant Syndrome?

Published on by Andrew Marshall2 Comments

Introduction

Neuroleptic malignant syndrome (NMS) is a rare but life-threatening reaction that can occur in response to neuroleptic or antipsychotic medication. Symptoms include high fever, confusion, rigid muscles, variable blood pressure, sweating, and fast heart rate. Complications may include rhabdomyolysis, high blood potassium, kidney failure, or seizures.

Any medications within the family of neuroleptics can cause the condition, though typical antipsychotics appear to have a higher risk than atypicals, specifically first generation antipsychotics like haloperidol. Onset is often within a few weeks of starting the medication but can occur at any time. Risk factors include dehydration, agitation, and catatonia.

Rapidly decreasing the use of levodopa or other dopamine agonists, such as pramipexole, may also trigger the condition. The underlying mechanism involves blockage of dopamine receptors. Diagnosis is based on symptoms.

Management includes stopping the offending medication, rapid cooling, and starting other medications. Medications used include dantrolene, bromocriptine, and diazepam. The risk of death among those affected is about 10%. Rapid diagnosis and treatment is required to improve outcomes. Many people can eventually be restarted on a lower dose of antipsychotic.

As of 2011, among those in psychiatric hospitals on neuroleptics about 15 per 100,000 are affected per year (0.015%). In the second half of the 20th century rates were over 100 times higher at about 2% (2,000 per 100,000). Males appear to be more often affected than females. The condition was first described in 1956.

Brief History

NMS was known about as early as 1956, shortly after the introduction of the first phenothiazines. NMS was first described in 1960 by French clinicians who had been working on a study involving haloperidol. They characterized the condition that was associated with the side effects of haloperidol “syndrome malin des neuroleptiques”, which was translated to neuroleptic malignant syndrome.

Signs and Symptoms

The first symptoms of neuroleptic malignant syndrome are usually muscle cramps and tremors, fever, symptoms of autonomic nervous system instability such as unstable blood pressure, and sudden changes in mental status (agitation, delirium, or coma). Once symptoms appear, they may progress rapidly and reach peak intensity in as little as three days. These symptoms can last anywhere from eight hours to forty days.

Symptoms are sometimes misinterpreted by doctors as symptoms of mental illness which can result in delayed treatment. NMS is less likely if a person has previously been stable for a period of time on antipsychotics, especially in situations where the dose has not been changed and there are no issues of noncompliance or consumption of psychoactive substances known to worsen psychosis.

  • Increased body temperature >38 °C (>100.4 °F);
  • Confused or altered consciousness;
  • sweating;
  • Rigid muscles; and/or
  • Autonomic imbalance.

Causes

NMS is usually caused by antipsychotic drug use, and a wide range of drugs can result in NMS. Individuals using butyrophenones (such as haloperidol and droperidol) or phenothiazines (such as promethazine and chlorpromazine) are reported to be at greatest risk. However, various atypical antipsychotics such as clozapine, olanzapine, risperidone, quetiapine, and ziprasidone have also been implicated in cases.

NMS may also occur in people taking dopaminergic drugs (such as levodopa) for Parkinson’s disease, most often when the drug dosage is abruptly reduced. In addition, other drugs with anti-dopaminergic activity, such as the antiemetic metoclopramide, can induce NMS. Tetracyclics with anti-dopaminergic activity have been linked to NMS in case reports, such as the amoxapines. Additionally, desipramine, dothiepin, phenelzine, tetrabenazine, and reserpine have been known to trigger NMS. Whether lithium can cause NMS is unclear.

At the molecular level, NMS is caused by a sudden, marked reduction in dopamine activity, either from withdrawal of dopaminergic agents or from blockade of dopamine receptors.

Risk Factors

One of the clearest risk factors in the development of NMS is the course of drug therapy chosen to treat a condition. Use of high-potency neuroleptics, a rapid increase in the dosage of neuroleptics, and use of long-acting forms of neuroleptics are all known to increase the risk of developing NMS.

It has been purported that there is a genetic risk factor for NMS, since identical twins have both presented with NMS in one case, and a mother and two of her daughters have presented with NMS in another case.

Demographically, it appears that males, especially those under forty, are at greatest risk for developing NMS, although it is unclear if the increased incidence is a result of greater neuroleptic use in men under forty. It has also been suggested that postpartum women may be at a greater risk for NMS.

An important risk factor for this condition is Lewy body dementia. These patients are extremely sensitive to neuroleptics. As a result, neuroleptics should be used cautiously in all cases of dementia.

Pathophysiology

The mechanism is commonly thought to depend on decreased levels of dopamine activity due to:

  • Dopamine receptor blockade.
  • Genetically reduced function of dopamine receptor D2.

It has been proposed that blockade of D2-like (D2, D3 and D4) receptors induce massive glutamate release, generating catatonia, neurotoxicity and myotoxicity. Additionally, the blockade of diverse serotonin receptors by atypical antipsychotics and activation of 5HT1 receptors by certain of them reduces GABA release and indirectly induces glutamate release, worsening this syndrome.

The muscular symptoms are most likely caused by blockade of the dopamine receptor D2, leading to abnormal function of the basal ganglia similar to that seen in Parkinson’s disease.

However, the failure of D2 dopamine receptor antagonism, or dopamine receptor dysfunction, do not fully explain the presenting symptoms and signs of NMS, as well as the occurrence of NMS with atypical antipsychotic drugs with lower D2 dopamine activity. This has led to the hypothesis of sympathoadrenal hyperactivity (results from removing tonic inhibition from the sympathetic nervous system) as a mechanism for NMS. Release of calcium is increased from the sarcoplasmic reticulum with antipsychotic usage. This can result in increased muscle contractility, which can play a role in the breakdown of muscle, muscle rigidity, and hyperthermia. Some antipsychotic drugs, such as typical neuroleptics, are known to block dopamine receptors; other studies have shown that when drugs supplying dopamine are withdrawn, symptoms similar to NMS present themselves.

There is also thought to be considerable overlap between malignant catatonia and NMS in their pathophysiology, the former being idiopathic and the latter being the drug-induced form of the same syndrome.

The raised white blood cell count and creatine phosphokinase (CPK) plasma concentration seen in those with NMS is due to increased muscular activity and rhabdomyolysis (destruction of muscle tissue). The patient may suffer hypertensive crisis and metabolic acidosis. A non-generalized slowing on an EEG is reported in around 50% of cases.

The fever seen with NMS is believed to be caused by hypothalamic dopamine receptor blockade. The peripheral problems (the high white blood cell and CPK count) are caused by the antipsychotic drugs. They cause an increased calcium release from the sarcoplasmic reticulum of muscle cells which can result in rigidity and eventual cell breakdown. No major studies have reported an explanation for the abnormal EEG, but it is likely also attributable to dopamine blockage leading to changes in neuronal pathways.

Diagnosis

Differential Diagnosis

Differentiating NMS from other neurological disorders can be very difficult. It requires expert judgement to separate symptoms of NMS from other diseases. Some of the most commonly mistaken diseases are encephalitis, toxic encephalopathy, status epilepticus, heat stroke, catatonia and malignant hyperthermia. Due to the comparative rarity of NMS, it is often overlooked and immediate treatment for the syndrome is delayed. Drugs such as cocaine and amphetamine may also produce similar symptoms.

The differential diagnosis is similar to that of hyperthermia, and includes serotonin syndrome. Features which distinguish NMS from serotonin syndrome include bradykinesia, muscle rigidity, and a high white blood cell count.

Treatment

NMS is a medical emergency and can lead to death if untreated. The first step is to stop the antipsychotic medication and treat the hyperthermia aggressively, such as with cooling blankets or ice packs to the axillae and groin. Supportive care in an intensive care unit capable of circulatory and ventilatory support is crucial. The best pharmacological treatment is still unclear. Dantrolene has been used when needed to reduce muscle rigidity, and more recently dopamine pathway medications such as bromocriptine have shown benefit. Amantadine is another treatment option due to its dopaminergic and anticholinergic effects. Apomorphine may be used however its use is supported by little evidence. Benzodiazepines may be used to control agitation. Highly elevated blood myoglobin levels can result in kidney damage, therefore aggressive intravenous hydration with diuresis may be required. When recognised early NMS can be successfully managed; however, up to 10% of cases can be fatal.

Should the affected person subsequently require an antipsychotic, trialling a low dose of a low-potency atypical antipsychotic is recommended.

Prognosis

The prognosis is best when identified early and treated aggressively. In these cases NMS is not usually fatal. In earlier studies the mortality rates from NMS ranged from 20%-38%, but by 2009 mortality rates were reported to have fallen below 10% over the previous two decades due to early recognition and improved management. Re-introduction to the drug that originally caused NMS to develop may also trigger a recurrence, although in most cases it does not.

Memory impairment is a consistent feature of recovery from NMS, and is usually temporary though in some cases may become persistent.

Epidemiology

Pooled data suggest the incidence of NMS is between 0.2%-3.23%. However, greater physician awareness coupled with increased use of atypical anti-psychotics have likely reduced the prevalence of NMS. Additionally, young males are particularly susceptible and the male-female ratio has been reported to be as high as 2:1.

Research

While the pathophysiology of NMS remains unclear, the two most prevalent theories are:

  • Reduced dopamine activity due to receptor blockade.
  • Sympathoadrenal hyperactivity and autonomic dysfunction.

In the past, research and clinical studies seemed to corroborate the D2 receptor blockade theory in which antipsychotic drugs were thought to significantly reduce dopamine activity by blocking the D2 receptors associated with this neurotransmitter. However, recent studies indicate a genetic component to the condition. In support of the sympathoadrenal hyperactivity model proposed, it has been hypothesized that a defect in calcium regulatory proteins within the sympathetic neurons may bring about the onset of NMS. This model of NMS strengthens its suspected association with malignant hyperthermia in which NMS may be regarded as a neurogenic form of this condition which itself is linked to defective calcium-related proteins.

The introduction of atypical antipsychotic drugs, with lower affinity to the D2 dopamine receptors, was thought to have reduced the incidence of NMS. However, recent studies suggest that the decrease in mortality may be the result of increased physician awareness and earlier initiation of treatment rather than the action of the drugs themselves. NMS induced by atypical drugs also resembles “classical” NMS (induced by “typical” antipsychotic drugs), further casting doubt on the overall superiority of these drugs.

What is Haloperidol?

Published on by Andrew Marshall18 Comments

Introduction

Haloperidol, sold under the brand name Haldol among others, is a typical antipsychotic medication.

Haloperidol is used in the treatment of schizophrenia, tics in Tourette syndrome, mania in bipolar disorder, delirium, agitation, acute psychosis, and hallucinations in alcohol withdrawal. It may be used by mouth or injection into a muscle or a vein. Haloperidol typically works within 30 to 60 minutes. A long-acting formulation may be used as an injection every four weeks in people with schizophrenia or related illnesses, who either forget or refuse to take the medication by mouth.

Haloperidol may result in a movement disorder known as tardive dyskinesia which may be permanent. Neuroleptic malignant syndrome and QT interval prolongation may occur. In older people with psychosis due to dementia it results in an increased risk of death. When taken during pregnancy it may result in problems in the infant. It should not be used in people with Parkinson’s disease.

Haloperidol was discovered in 1958 by Paul Janssen. It was made from pethidine (meperidine). It is on the World Health Organisation’s (WHO’s) List of Essential Medicines. It is the most commonly used typical antipsychotic. In 2017, it was the 296th most commonly prescribed medication in the United States, with more than one million prescriptions.

Brief History

Haloperidol was discovered by Paul Janssen. It was developed in 1958 at the Belgian company Janssen Pharmaceutica and submitted to the first of clinical trials in Belgium later that year.

Haloperidol was approved by the US Food and Drug Administration (FDA) on 12 April 1967; it was later marketed in the US and other countries under the brand name Haldol by McNeil Laboratories.

Medical Uses

Haloperidol is used in the control of the symptoms of:

  • Acute psychosis, such as drug-induced psychosis caused by LSD, psilocybin, amphetamines, ketamine, and phencyclidine, and psychosis associated with high fever or metabolic disease.
    • Some evidence, however, has found haloperidol to worsen psychosis due to psilocybin.
  • Adjunctive treatment of alcohol and opioid withdrawal.
  • Agitation and confusion associated with cerebral sclerosis.
  • Alcohol-induced psychosis.
  • Hallucinations in alcohol withdrawal.
  • Hyperactive delirium (to control the agitation component of delirium).
  • Hyperactivity, aggression.
  • Otherwise uncontrollable, severe behavioral disorders in children and adolescents.
  • Schizophrenia.
  • Therapeutic trial in personality disorders, such as borderline personality disorder.
  • Treatment of intractable hiccups.
  • Treatment of neurological disorders, such as tic disorders such as Tourette syndrome, and chorea.
  • Treatment of severe nausea and emesis in postoperative and palliative care, especially for palliating adverse effects of radiation therapy and chemotherapy in oncology.

Haloperidol was considered indispensable for treating psychiatric emergency situations, although the newer atypical drugs have gained a greater role in a number of situations as outlined in a series of consensus reviews published between 2001 and 2005.

In a 2013 comparison of 15 antipsychotics in schizophrenia, haloperidol demonstrated standard effectiveness. It was 13-16% more effective than ziprasidone, chlorpromazine, and asenapine, approximately as effective as quetiapine and aripiprazole, and 10% less effective than paliperidone.

Pregnancy and Lactation

Data from animal experiments indicate haloperidol is not teratogenic, but is embryotoxic in high doses. In humans, no controlled studies exist. Reports in pregnant women revealed possible damage to the foetus, although most of the women were exposed to multiple drugs during pregnancy. In addition, reports indicate neonates exposed to antipsychotic drugs are at risk for extrapyramidal and/or withdrawal symptoms following delivery, such as agitation, hypertonia, hypotonia, tremor, somnolence, respiratory distress, and feeding disorder. Following accepted general principles, haloperidol should be given during pregnancy only if the benefit to the mother clearly outweighs the potential foetal risk.

Haloperidol is excreted in breast milk. A few studies have examined the impact of haloperidol exposure on breastfed infants and in most cases, there were no adverse effects on infant growth and development.

Other Considerations

During long-term treatment of chronic psychiatric disorders, the daily dose should be reduced to the lowest level needed for maintenance of remission. Sometimes, it may be indicated to terminate haloperidol treatment gradually. In addition, during long-term use, routine monitoring including measurement of BMI, blood pressure, fasting blood sugar, and lipids, is recommended due to the risk of side effects.

Other forms of therapy (psychotherapy, occupational therapy/ergotherapy, or social rehabilitation) should be instituted properly. PET imaging studies have suggested low doses are preferable. Clinical response was associated with at least 65% occupancy of D2 receptors, while greater than 72% was likely to cause hyperprolactinaemia and over 78% associated with extrapyramidal side effects. Doses of haloperidol greater than 5 mg increased the risk of side effects without improving efficacy. Patients responded with doses under even 2 mg in first-episode psychosis. For maintenance treatment of schizophrenia, an international consensus conference recommended a reduction dosage by about 20% every 6 months until a minimal maintenance dose is established.

Depot forms are also available; these are injected deeply intramuscularly at regular intervals. The depot forms are not suitable for initial treatment, but are suitable for patients who have demonstrated inconsistency with oral dosages.

The decanoate ester of haloperidol (haloperidol decanoate, trade names Haldol decanoate, Halomonth, Neoperidole) has a much longer duration of action, so is often used in people known to be noncompliant with oral medication. A dose is given by intramuscular injection once every two to four weeks. The IUPAC name of haloperidol decanoate is [4-(4-chlorophenyl)-1-[4-(4-fluorophenyl)-4-oxobutyl]piperidin-4-yl] decanoate.

Topical formulations of haloperidol should not be used as treatment for nausea because research does not indicate this therapy is more effective than alternatives.

Adverse Effects

As haloperidol is a high-potency typical antipsychotic, it tends to produce significant extrapyramidal side effects. According to a 2013 meta-analysis of the comparative efficacy and tolerability of 15 antipsychotic drugs it was the most prone of the 15 for causing extrapyramidal side effects.

With more than 6 months of use 14 percent of users gain weight. Haloperidol may be neurotoxic.

  • Common (>1% incidence):
    • Extrapyramidal side effects including:
      • Akathisia (motor restlessness).
      • Dystonia (continuous spasms and muscle contractions).
      • Muscle rigidity.
      • Parkinsonism (characteristic symptoms such as rigidity).
    • Hypotension:
    • Anticholinergic side effects such as (These adverse effects are less common than with lower-potency typical antipsychotics, such as chlorpromazine and thioridazine):
      • Blurred vision.
      • Constipation.
      • Dry mouth.
    • Somnolence (which is not a particularly prominent side effect, as is supported by the results of the aforementioned meta-analysis).
  • Unknown frequency:
    • Anaemia.
    • Headache.
    • Increased respiratory rate.
    • Orthostatic hypotension.
    • Prolonged QT interval.
    • Visual disturbances.
  • Rare (<1% incidence):
    • Acute hepatic failure.
    • Agitation.
    • Agranulocytosis.
    • Anaphylactic reaction.
    • Anorexia.
    • Bronchospasm.
    • Cataracts.
    • Cholestasis.
    • Confusional state.
    • Depression.
    • Dermatitis exfoliative.
    • Dyspnoea.
    • Oedema.
    • Extrasystoles.
    • Face oedema.
    • Gynecomastia.
    • Hepatitis.
    • Hyperglycaemia.
    • Hypersensitivity.
    • Hyperthermia.
    • Hypoglycaemia.
    • Hyponatremia.
    • Hypothermia.
    • Increased sweating.
    • Injection site abscess.
    • Insomnia.
    • Itchiness.
    • Jaundice.
    • Laryngeal oedema.
    • Laryngospasm.
    • Leukocytoclastic vasculitis.
    • Leukopenia.
    • Liver function test abnormal.
    • Nausea.
    • Neuroleptic malignant syndrome.
    • Neutropenia.
    • Pancytopenia.
    • Photosensitivity reaction.
    • Priapism.
    • Psychotic disorder.
    • Pulmonary embolism.
    • Rash.
    • Retinopathy.
    • Seizure.
    • Sudden death.
    • Tardive dyskinesia.
    • Thrombocytopenia.
    • Torsades de pointes.
    • Urinary retention.
    • Urticaria.
    • Ventricular fibrillation.
    • Ventricular tachycardia.
    • Vomiting.

Contraindications

  • Pre-existing coma, acute stroke.
  • Severe intoxication with alcohol or other central depressant drugs.
  • Known allergy against haloperidol or other butyrophenones or other drug ingredients.
  • Known heart disease, when combined will tend towards cardiac arrest.

Special Cautions

  • A multiple-year study suggested this drug and other neuroleptic antipsychotic drugs commonly given to people with Alzheimer’s with mild behavioural problems often make their condition worse and its withdrawal was even beneficial for some cognitive and functional measures.
  • Elderly patients with dementia-related psychosis: analysis of 17 trials showed the risk of death in this group of patients was 1.6 to 1.7 times that of placebo-treated patients.
    • Most of the causes of death were either cardiovascular or infectious in nature.
    • It is not clear to what extent this observation is attributed to antipsychotic drugs rather than the characteristics of the patients.
    • The drug bears a boxed warning about this risk.
  • Impaired liver function, as haloperidol is metabolised and eliminated mainly by the liver.
  • In patients with hyperthyroidism, the action of haloperidol is intensified and side effects are more likely.
  • IV injections: risk of hypotension or orthostatic collapse.
  • Patients at special risk for the development of QT prolongation (hypokalaemia, concomitant use of other drugs causing QT prolongation).
  • Patients with a history of leukopenia: a complete blood count should be monitored frequently during the first few months of therapy and discontinuation of the drug should be considered at the first sign of a clinically significant decline in white blood cells.
  • Pre-existing Parkinson’s disease or dementia with Lewy bodies.

Interactions

  • Amiodarone: Q-Tc interval prolongation (potentially dangerous change in heart rhythm).
  • Amphetamine and methylphenidate: counteracts increased action of norepinephrine and dopamine in patients with narcolepsy or ADD/ADHD.
  • Epinephrine: action antagonised, paradoxical decrease in blood pressure may result.
  • Guanethidine: antihypertensive action antagonised.
  • Levodopa: decreased action of levodopa.
  • Lithium: rare cases of the following symptoms have been noted: encephalopathy, early and late extrapyramidal side effects, other neurologic symptoms, and coma.
  • Methyldopa: increased risk of extrapyramidal side effects and other unwanted central effects.
  • Other central depressants (alcohol, tranquilizers, narcotics): actions and side effects of these drugs (sedation, respiratory depression) are increased.
    • In particular, the doses of concomitantly used opioids for chronic pain can be reduced by 50%.
  • Other drugs metabolised by the CYP3A4 enzyme system: inducers such as carbamazepine, phenobarbital, and rifampicin decrease plasma levels and inhibitors such as quinidine, buspirone, and fluoxetine increase plasma levels.
  • Tricyclic antidepressants: metabolism and elimination of tricyclics significantly decreased, increased toxicity noted (anticholinergic and cardiovascular side effects, lowering of seizure threshold).

Discontinuation

The British National Formulary recommends a gradual withdrawal when discontinuing antipsychotics to avoid acute withdrawal syndrome or rapid relapse. Symptoms of withdrawal commonly include nausea, vomiting, and loss of appetite. Other symptoms may include restlessness, increased sweating, and trouble sleeping. Less commonly there may be a feeling of the world spinning, numbness, or muscle pains. Symptoms generally resolve after a short period of time.

There is tentative evidence that discontinuation of antipsychotics can result in psychosis. It may also result in reoccurrence of the condition that is being treated. Rarely tardive dyskinesia can occur when the medication is stopped.

Overdose

Symptoms

Symptoms are usually due to side effects. Most often encountered are:

  • Anticholinergic side effects (dry mouth, constipation, paralytic ileus, difficulties in urinating, decreased perspiration).
  • Coma in severe cases, accompanied by respiratory depression and massive hypotension, shock.
  • Hypotension or hypertension.
  • Rarely, serious ventricular arrhythmia (torsades de pointes), with or without prolonged QT-time.
  • Sedation.
  • Severe extrapyramidal side effects with muscle rigidity and tremors, akathisia, etc.

Treatment

Treatment is mostly symptomatic and involves intensive care with stabilisation of vital functions. In early detected cases of oral overdose, induction of emesis, gastric lavage, and the use of activated charcoal can be tried. In the case of a severe overdose, antidotes such as bromocriptine or ropinirole may be used to treat the extrapyramidal effects caused by haloperidol, acting as dopamine receptor agonists. ECG and vital signs should be monitored especially for QT prolongation and severe arrhythmias should be treated with antiarrhythmic measures.

Prognosis

In general, the prognosis of overdose is good, provided the person has survived the initial phase. An overdose of haloperidol can be fatal.

Pharmacology

Haloperidol is a typical butyrophenone type antipsychotic that exhibits high affinity dopamine D2 receptor antagonism and slow receptor dissociation kinetics. It has effects similar to the phenothiazines. The drug binds preferentially to D2 and α1 receptors at low dose (ED50 = 0.13 and 0.42 mg/kg, respectively), and 5-HT2 receptors at a higher dose (ED50 = 2.6 mg/kg). Given that antagonism of D2 receptors is more beneficial on the positive symptoms of schizophrenia and antagonism of 5-HT2 receptors on the negative symptoms, this characteristic underlies haloperidol’s greater effect on delusions, hallucinations and other manifestations of psychosis. Haloperidol’s negligible affinity for histamine H1 receptors and muscarinic M1 acetylcholine receptors yields an antipsychotic with a lower incidence of sedation, weight gain, and orthostatic hypotension though having higher rates of treatment emergent extrapyramidal symptoms.

Haloperidol acts on these receptors: (Ki)

  • D1 (silent antagonist) – Unknown efficiency.
  • D5 (silent antagonist) – Unknown efficiency.
  • D2 (inverse agonist) – 0.7 nM.
  • D3 (inverse agonist) – 0.2 nM.
  • D4 (inverse agonist) – 5–9 nM.
  • σ1 (irreversible inactivation by haloperidol metabolite HPP+) – 3 nM.
  • σ2 (agonist): 54 nM.
  • 5HT1A receptor agonist – 1927 nM.
  • 5HT2A (silent antagonist) – 53 nM.
  • 5HT2C (silent antagonist) – 10,000 nM.
  • 5HT6 (silent antagonist) – 3666 nM.
  • 5HT7 (irreversible silent antagonist) – 377.2 nM.
  • H1 (silent antagonist) – 1,800 nM.
  • M1 (silent antagonist) – 10,000 nM.
  • α1A (silent antagonist) – 12 nM.
  • α2A (silent antagonist) – 1130 nM.
  • α2B (silent antagonist) – 480 nM.
  • α2C (silent antagonist) – 550 nM.
  • NR1/NR2B subunit containing NMDA receptor (antagonist; ifenprodil site): IC50 – 2,000 nM.

Pharmacokinetics

By Mouth

The bioavailability of oral haloperidol ranges from 60-70%. However, there is a wide variance in reported mean Tmax and T1/2 in different studies, ranging from 1.7 to 6.1 hours and 14.5 to 36.7 hours respectively.

Intramuscular Injections

The drug is well and rapidly absorbed with a high bioavailability when injected intramuscularly. The Tmax is 20 minutes in healthy individuals and 33.8 minutes in patients with schizophrenia. The mean T1/2 is 20.7 hours. The decanoate injectable formulation is for intramuscular administration only and is not intended to be used intravenously. The plasma concentrations of haloperidol decanoate reach a peak at about six days after the injection, falling thereafter, with an approximate half-life of three weeks.

Intravenous Injections

The bioavailability is 100% in intravenous (IV) injection, and the very rapid onset of action is seen within seconds. The T1/2 is 14.1 to 26.2 hours. The apparent volume of distribution is between 9.5 and 21.7 L/kg. The duration of action is four to six hours.

Therapeutic Concentrations

Plasma levels of five to 15 micrograms per litre are typically seen for therapeutic response (Ulrich S, et al. Clin Pharmacokinet. 1998). The determination of plasma levels is rarely used to calculate dose adjustments but can be useful to check compliance.

The concentration of haloperidol in brain tissue is about 20-fold higher compared to blood levels. It is slowly eliminated from brain tissue, which may explain the slow disappearance of side effects when the medication is stopped.

Distribution and Metabolism

Haloperidol is heavily protein bound in human plasma, with a free fraction of only 7.5 to 11.6%. It is also extensively metabolised in the liver with only about 1% of the administered dose excreted unchanged in the urine. The greatest proportion of the hepatic clearance is by glucuronidation, followed by reduction and CYP-mediated oxidation, primarily by CYP3A4.

Society and Culture

Cost

Haloperidol is relatively inexpensive, being up to 100 fold less expensive than newer antipsychotics.

Brand Names

Haloperidol is the INN, BAN, USAN, AAN approved name.

It is sold under the tradenames Aloperidin, Bioperidolo, Brotopon, Dozic, Duraperidol (Germany), Einalon S, Eukystol, Haldol (common tradename in the US and UK), Halol, Halosten, Keselan, Linton, Peluces, Serenace and Sigaperidol.

Veterinary Use

Haloperidol is also used on many different kinds of animals for nonselective tranquilisation and diminishing behavioural arousal, in veterinary and other settings including captivity management.