Antipsychotic

Antipsychotics are a group of psychoactive drugs commonly but not exclusively used to treat psychosis,[1] which is typified by schizophrenia. Over time a wide range of antipsychotics have been developed. A first generation of antipsychotics, known as typical antipsychotics, was discovered in the 1950s. Most of the drugs in the second generation, known as atypical antipsychotics, have more recently been developed. Both classes of medication tend to block receptors in the brain's dopamine pathways, but antipsychotic drugs encompass a wide range of receptor targets. A number of side effects have been observed in relation to specific medications, including weight gain, agranulocytosis, tardive dyskinesia, tardive akathisia and tardive psychoses. The development of new antipsychotics, and the relative efficacy of different ones, is an important ongoing field of research. Antipsychotic medication is not generally regarded as a good treatment so much as the best available, and the most appropriate drug for an individual patient requires careful consideration.

Contents

Terminology

Antipsychotics are also referred to as neuroleptic drugs .[2] The word neuroleptic is derived from Greek: "νεύρον" (originally meaning sinew but today referring to the nerves) and "λαμβάνω" (meaning take hold of). Thus, the word means taking hold of one's nerves. This term reflects the drugs' ability to make movement more difficult and sluggish, which clinicians previously believed indicated that a dose was high enough. The lower doses used currently have resulted in reduced incidence of motor side effects and sedation, and the term is less commonly used than in the past..

Antipsychotics are broadly divided into two groups, the typical or first-generation antipsychotics and the atypical or second-generation antipsychotics. There are also dopamine partial agonists, which are often categorized as atypicals.

Typical antipsychotics are also sometimes referred to as tranquilizers,[3] because some of them can tranquilize and sedate. This term is increasingly disused, as the terminology implies a connection with benzodiazepines ("minor" tranquilizers) when none exists.

Usage

Common conditions with which antipsychotics might be used include schizophrenia, mania, and delusional disorder. They might be used to counter psychosis associated with a wide range of other diagnoses, such as psychotic depression. In addition, these drugs are used to treat non-psychotic disorders. For example, some antipsychotics (haloperidol, pimozide) are used off-label to treat Tourette syndrome, whereas Aripiprazole is prescribed in some cases of Asperger's syndrome.

History

The original antipsychotic drugs were happened upon largely by chance and were tested empirically for their effectiveness. The first antipsychotic was chlorpromazine, which was developed as a surgical anesthetic. It was first used on psychiatric patients because of its powerful calming effect; at the time it was regarded as a "chemical lobotomy". Lobotomy was used to treat many behavioral disorders, including psychosis, although its "effectiveness" was (from a modern viewpoint) due to its tendency to markedly reduce behavior of all types. However, chlorpromazine quickly proved to reduce the effects of psychosis in a more effective and specific manner than the extreme lobotomy-like sedation it was known for.

The underlying neurochemistry involved has since been studied in detail, and subsequent anti-psychotic drugs have been discovered by an approach that incorporates this sort of information.

Common antipsychotics

Chlorpromazine.
Haloperidol.
Quetiapine.

Commonly used antipsychotic medications are listed below by drug group. Trade names appear in parentheses.

First generation antipsychotics

Butyrophenones

Phenothiazines

Thioxanthenes

Second generation antipsychotics

Third generation antipsychotics

Other options

The most common typical antipsychotic drugs are now off-patent, meaning any pharmaceutical company is legally allowed to produce generic versions of these medications. While this makes them cheaper than the atypical drugs that are still manufactured under patent constraints, atypical drugs are preferred as a first-line treatment because they are believed to have fewer side effects and seem to have additional benefits for the 'negative symptoms' of schizophrenia, a typical condition for which they might be prescribed.

Metabotropic glutamate receptor 2 agonism has been seen as a promissing strategy in the development of novel antipsychotics.[6] When tested in patients, the research substance LY2140023 yielded promising results and had few side effects. The active metabolite of this prodrug targets the brain glutamate receptors mGluR2/3 rather than dopamine receptors.[7] It is currently in phase-2 clinical testing (2007).

Drug action

All antipsychotic drugs tend to block D2 receptors in the dopamine pathways of the brain. This means that dopamine released in these pathways has less effect. Excess release of dopamine in the mesolimbic pathway has been linked to psychotic experiences. It is the blockade of dopamine receptors in this pathway that is thought to control psychotic experiences.

Typical antipsychotics are not particularly selective and also block Dopamine receptors in the mesocortical pathway, tuberoinfundibular pathway, and the nigrostriatal pathway. Blocking D2 receptors in these other pathways is thought to produce some of the unwanted side effects that the typical antipsychotics can produce (see below). They were commonly classified on a spectrum of low potency to high potency, where potency referred to the ability of the drug to bind to dopamine receptors, and not to the effectiveness of the drug. High-potency antipsychotics such as haloperidol, in general, have doses of a few milligrams and cause less sleepiness and calming effects than low-potency antipsychotics such as chlorpromazine and thioridazine, which have dosages of several hundred milligrams. The latter have a greater degree of anticholinergic and antihistaminergic activity, which can counteract dopamine-related side effects.

Atypical antipsychotic drugs have a similar blocking effect on D2 receptors. Some also block or partially block serotonin receptors (particularly 5HT2A, C and 5HT1A receptors):ranging from risperidone, which acts overwhelmingly on serotonin receptors, to amisulpride, which has no serotonergic activity. The additional effects on serotonin receptors may be why some of them can benefit the 'negative symptoms' of schizophrenia.[8]

Side effects

Antipsychotics are associated with a range of side effects. It is well-recognized that many stop taking them (around two-thirds of people in controlled drug trials) due in part to adverse effects.[9] Extrapyramidal reactions include tardive psychosis, acute dystonias, akathisia, parkinsonism (rigidity and tremor), tardive dyskinesia, tachycardia, hypotension, impotence, lethargy, seizures, intense dreams or nightmares, and hyperprolactinaemia.

From a subjective perspective, antipsychotics heavily influence one's perceptions of pleasurable sensations, causing a severe reduction in feelings of desire, motivation, pensive thought, and awe. This does not coincide with the apathy and lack of motivation experienced by the negative symptoms of schizophrenia. Detrimental effects on short term memory, which affect the way one figures and calculates (although this also may be purely subjective), may also be observed on high enough dosages. These are all the reasons why they are thought to affect "creativity". Also, for some individuals with schizophrenia, too much stress may cause "relapse".

Following are details concerning some of the side effects of antipsychotics:

Some people suffer few apparent side effects from taking antipsychotic medication, whereas others may have serious adverse effects. Some side effects, such as subtle cognitive problems, may go unnoticed.

There is a possibility that the risk of tardive dyskinesia can be reduced by combining the anti-psychotics with diphenhydramine or benztropine, although this remains to be established. Central nervous system damage is also associated with irreversible tardive akathisia and/or tardive dysphrenia.

Structural effects

Many studies now indicate that chronic treatment with antipsychotics affects the brain at a structural level, for example increasing the volume of the basal ganglia (especially the caudate nucleus), and reducing cortical grey matter volume in different brain areas. The effects may differ for typical versus atypical antipsychotics and may interact with different stages of disorders.[12] Death of neurons in the cerebral cortex, especially in women, has been linked to the use of both typical and atypical antipsychotics for individuals with Alzheimers.[13]

Recent studies on macaque monkeys have found that administration of haloperidol or olanzapine over two years led to a significant overall shrinkage in brain tissue, in both gray and white matter across several brain areas, with lower glial cell counts and increased neuronal density. It has been said that these studies require serious attention and that such effects were not clearly tested for by pharmaceutical companies prior to obtaining approval for placing the drugs on the market.[14][15]

Efficacy

There have been a large number of studies of the efficacy of typical antipsychotics, and an increasing number on the more recent atypical antipsychotics.

The American Psychiatric Association and the UK National Institute for Health and Clinical Excellence recommend antipsychotics for managing acute psychotic episodes and for preventing relapse.[16][17] They state that response to any given antipsychotic can be variable so that trials may be necessary, and that lower doses are to be preferred where possible.

Antipsychotic polypharmacy—prescribing two or more antipsychotics at the same time for an individual—is said to be a frequent practice but not necessarily evidence-based.[18]

Some doubts have been raised about the long-term effectiveness of antipsychotics because two large international World Health Organization studies found individuals diagnosed with schizophrenia tend to have better long-term outcomes in developing countries (where there is lower availability and use of antipsychotics) than in developed countries.[19][20] The reasons for the differences are not clear, however, and various explanations have been suggested.

Some argue that the evidence for antipsychotics from withdrawal-relapse studies may be flawed, because they do not take into account that antipsychotics may sensitize the brain and provoke psychosis if discontinued.[21] Evidence from comparison studies indicates that at least some individuals recover from psychosis without taking antipsychotics, and may do better than those that do take antipsychotics.[22] Some argue that, overall, the evidence suggests that antipsychotics only help if they are used selectively and are gradually withdrawn as soon as possible.[23]

A dose response effect has been found in one study from 1971 between increasing neuroleptic dose and increasing number of psychotic breaks.[24]

Typical versus atypical

While the atypical, second-generation medications were marketed as offering greater efficacy in reducing psychotic symptoms while reducing side effects (and extra-pyramidal symptoms in particular) than typical medications, the results showing these effects often lack robustness. To remediate this problem, the NIMH conducted a recent multi-site, double-blind study (the CATIE project), which was published in 2005.[25] This study compared several atypical antipsychotics to an older typical antipsychotic, perphenazine, among 1493 persons with schizophrenia. Perphenazine was chosen because of its lower potency and moderate side effect profile. The study found that only olanzapine outperformed perphenazine in the researchers' principal outcome, the discontinuation rate. The authors also noted the apparent superior efficacy of olanzapine to the other drugs for greater reduction in psychopathology, longer duration of successful treatment, and lower rate of hospitalizations for an exacerbation of schizophrenia. In contrast, no other atypical studied (risperidone, quetiapine, and ziprasidone) did better than the typical perphenazine on those measures. Olanzapine, however, was associated with relatively severe metabolic effects: Subjects with olanzapine showed a major weight gain problem and increases in glucose, cholesterol, and triglycerides. The average weight gain (1.1 kg/month, or 44 pounds for the 18 months that the study lasted) casts serious doubt on the potentiality of long-term use of this drug. Perphenazine did not create more extrapyramidal side effects as measured by rating scales (a result supported by a meta-analysis by Dr. Leucht published in Lancet), although more patients discontinued perphenazine owing to extrapyramidal effects compared to the atypical agents (8 percent vs. 2 percent to 4 percent, P=0.002).

A phase 2 part of this study roughly replicated these findings.[26] This phase consisted of a second randomization of the patients that discontinued taking medication in the first phase. Olanzapine was again the only medication to stand out in the outcome measures, although the results did not always reach statistical significance, due in part to the decrease of power. Perphenazine again did not create more extrapyramidal effects.

A subsequent phase was conducted. [27] This phase allowed clinicians to offer clozapine which was more effective at reducing medication drop-outs than other neuroleptic agents. However, the potential for clozapine to cause toxic side effects, including agranulocytosis, limits its usefulness.

References

  1. antipsychotic agent at Dorland's Medical Dictionary
  2. neuroleptic at Dorland's Medical Dictionary
  3. tranquilizer at Dorland's Medical Dictionary
  4. Swainston, Harrison T.; Perry, C.M. (2004). "Aripiprazole: a review of its use in schizophrenia and schizoaffective disorder". Drugs 64 (15): 1715–1736. doi:10.2165/00003495-200464150-00010. PMID 15257633
  5. Zuardi, A.W; J.A.S. Crippa, J.E.C. Hallak, F.A. Moreira, F.S. Guimarães (2006). "Cannabidiol as an antipsychotic drug". Brazilian Journal of Medical and Biological Research 39: 421–429. ISSN 0100-879X ISSN 0100-879X. http://www.scielo.br/pdf/bjmbr/v39n4/6164.pdf. 
  6. PMID 17526600 PMID 18424625 PMID 18297054
  7. BBC NEWS, Schizophrenia trials 'promising'
  8. Murphy, B.P.; Chung YC, Park TW, McGorry PD (12 2006). "Pharmacological treatment of primary negative symptoms in schizophrenia: a systematic review". Schizophrenia Research 88 (1-3): 5–25. doi:10.1016/j.schres.2006.07.002. PMID 16930948
  9. Bellack AS. (2006) Scientific and consumer models of recovery in schizophrenia: concordance, contrasts, and implications. Schizophrenia Bulletin. Jul;32(3):432-42. PMID 16461575
  10. Koller EA, Cross JT, Doraiswamy PM, Malozowski SN (September 2003). "Pancreatitis associated with atypical antipsychotics: from the Food and Drug Administration's MedWatch surveillance system and published reports". Pharmacotherapy 23 (9): 1123–30. PMID 14524644. 
  11. Glever, J. (2008) Boxed Mortality Warning Added to Older Antipsychotics Given to Elderly Demented Medpage Today, June 16.
  12. Vita, Antonio & De Peri, Luca (2007), "The effects of antipsychotic treatment on cerebral structure and function in schizophrenia", International Review of Psychiatry 19: 429, doi:10.1080/09540260701486332 
  13. The influence of psychotropic drugs on cerebral cell female neurovulnerability to antipsychotics, by Raphael M. Bonelli, Peter Hofmann, Andreas Aschoff, Gerald Niederwieser, Clemens Heuberger, Gustaf Jirikowski and Hans-Peter Kapfhammer, International Clinical Psychopharmacology 2005, 20:145-149 PMID 15812264
  14. DeLisi LE (March 2008). "The concept of progressive brain change in schizophrenia: implications for understanding schizophrenia". Schizophr Bull 34 (2): 312–21. doi:10.1093/schbul/sbm164. PMID 18263882. 
  15. Konopaske, Glenn T.; Dorph-petersen, Karl-Anton; Pierri, Joseph N.; Wu, Qiang; Sampson, Allan R.; Lewis, David A. (2007), "Effect of Chronic Exposure to Antipsychotic Medication on Cell Numbers in the Parietal Cortex of Macaque Monkeys", Neuropsychopharmacology 32 (6): 1216, doi:10.1038/sj.npp.1301233  | URL = http://psychrights.org/Research/Digest/NLPs/MonkeysonNeuroleptics.pdf
  16. American Psychiatric Association (2004) Practice Guideline for the Treatment of Patients With Schizophrenia. Second Edition.
  17. The Royal College of Psychiatrists & The British Psychological Society (2003). Schizophrenia. Full national clinical guideline on core interventions in primary and secondary care (PDF). London: Gaskell and the British Psychological Society.
  18. Patrick V, Levin E, Schleifer S. (2005) Antipsychotic polypharmacy: is there evidence for its use? J Psychiatr Pract. 2005 Jul;11(4):248-57. PMID 16041235
  19. Jablensky A, Sartorius N, Ernberg G, Anker M, Korten A, Cooper J, Day R, Bertelsen A. "Schizophrenia: manifestations, incidence and course in different cultures. A World Health Organization ten-country study". Psychol Med Monogr Suppl 20: 1–97. PMID 1565705. 
  20. Hopper K, Wanderling J (2000). Revisiting the developed versus developing country distinction in course and outcome in schizophrenia: results from ISoS, the WHO collaborative followup project. International Study of Schizophrenia. Schizophrenia Bulletin, 26 (4), 835–46. PMID 11087016
  21. Moncrieff J. (2006) Does antipsychotic withdrawal provoke psychosis? Review of the literature on rapid onset psychosis (supersensitivity psychosis) and withdrawal-related relapse. Acta Psychiatrica Scandinavica Jul;114(1):3-13. PMID 16774655
  22. Harrow M, Jobe TH. (2007) Factors involved in outcome and recovery in schizophrenia patients not on antipsychotic medications: a 15-year multifollow-up study. J Nerv Ment Dis. May;195(5):406-14. PMID 17502806
  23. Whitaker R. (2004) The case against antipsychotic drugs: a 50-year record of doing more harm than good. Med Hypotheses. 2004;62(1):5-13. PMID 14728997
  24. Prien R, Levine J, Switalski R (1971). "Discontinuation of chemotherapy for chronic schizophrenics". Hosp Community Psychiatry 22 (1): 4–7. PMID 4992967. 
  25. Lieberman J et al (2005). "Effectiveness of antipsychotic drugs in patients with chronic schizophrenia". N Engl J Med 353 (12): 1209–23. doi:10.1056/NEJMoa051688. PMID 16172203. http://content.nejm.org/cgi/content/abstract/353/12/1209. 
  26. Stroup T et al (2006). "Effectiveness of olanzapine, quetiapine, risperidone, and ziprasidone in patients with chronic schizophrenia following discontinuation of a previous atypical antipsychotic". Am J Psychiatry 163 (4): 611–22. doi:10.1176/appi.ajp.163.4.611. PMID 16585435. 
  27. McEvoy J et al (2006). "Effectiveness of clozapine versus olanzapine, quetiapine, and risperidone in patients with chronic schizophrenia that did not respond to prior atypical antipsychotic treatment". Am J Psychiatry 163 (4): 600–10. doi:10.1176/appi.ajp.163.4.600. PMID 16585434. 

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Psycholeptics: antipsychotics - primarily dopamine antagonists (N05A)
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Phenothiazine
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