Antihistamine

Antihistamines are drugs which treat allergic rhinitis and other allergies.[1] Typically people take antihistamines as an inexpensive, generic, over-the-counter drug that can provide relief from nasal congestion, sneezing, or hives caused by pollen, dust mites, or animal allergy with few side effects.[1] Antihistamines are usually for short-term treatment.[1] Chronic allergies increase the risk of health problems which antihistamines might not treat, including asthma, sinusitis, and lower respiratory tract infection.[1] Consultation of a medical professional is recommended for those who intend to take antihistamines for longer-term use.[1]

Antihistamine
Drug class
Histamine structure
Class identifiers
ATC codeR06
Mechanism of action  Receptor antagonist
  Inverse agonist
Biological targetHistamine receptors
  HRH1
  HRH2
  HRH3
  HRH4
External links
MeSHD006633
In Wikidata

Although people typically use the word “antihistamine” to describe drugs for treating allergies, doctors and scientists use the term to describe a class of drug that opposes the activity of histamine receptors in the body.[2] In this sense of the word, antihistamines are subclassified according to the histamine receptor that they act upon. The two largest classes of antihistamines are H1-antihistamines and H2-antihistamines.

H1-antihistamines work by binding to histamine H1 receptors in mast cells, smooth muscle, and endothelium in the body as well as in the tuberomammillary nucleus in the brain. Antihistamines that target the histamine H1-receptor are used to treat allergic reactions in the nose (e.g., itching, runny nose, and sneezing). In addition, they may be used to treat insomnia, motion sickness, or vertigo caused by problems with the inner ear. H2-antihistamines bind to histamine H2 receptors in the upper gastrointestinal tract, primarily in the stomach. Antihistamines that target the histamine H2-receptor are used to treat gastric acid conditions (e.g., peptic ulcers and acid reflux).

Histamine receptors exhibit constitutive activity, so antihistamines can function as either a neutral receptor antagonist or an inverse agonist at histamine receptors.[2][3][4][5] Only a few currently marketed H1-antihistamines are known to function as inverse agonists.[2][5]

Medical uses

Histamine produces increased vascular permeability, causing fluid to escape from capillaries into tissues, which leads to the classic symptoms of an allergic reaction — a runny nose and watery eyes. Histamine also promotes angiogenesis.[6]

Antihistamines suppress the histamine-induced wheal response (swelling) and flare response (vasodilation) by blocking the binding of histamine to its receptors or reducing histamine receptor activity on nerves, vascular smooth muscle, glandular cells, endothelium, and mast cells.

Itching, sneezing, and inflammatory responses are suppressed by antihistamines that act on H1-receptors.[2][7] In 2014, antihistamines such as desloratadine were found to be effective as adjuvants to standardized treatment of acne due to their anti-inflammatory properties and their ability to suppress sebum production.[8][9]

Types

H1-antihistamines

H1-antihistamines refer to compounds that inhibit the activity of the H1 receptor.[4][5] Since the H1 receptor exhibits constitutive activity, H1-antihistamines can be either neutral receptor antagonists or inverse agonists.[4][5] Normally, histamine binds to the H1 receptor and heightens the receptor's activity; the receptor antagonists work by binding to the receptor and blocking the activation of the receptor by histamine; by comparison, the inverse agonists bind to the receptor and both block the binding of histamine, and reduce its constitutive activity, an effect which is opposite to histamine's.[4] Most antihistamines are inverse agonists at the H1 receptor, but it was previously thought that they were antagonists.[10]

Clinically, H1-antihistamines are used to treat allergic reactions and mast cell-related disorders. Sedation is a common side effect of H1-antihistamines that readily cross the blood–brain barrier; some of these drugs, such as diphenhydramine and doxylamine, may therefore be used to treat insomnia. H1-antihistamines can also reduce inflammation, since the expression of NF-κB, the transcription factor the regulates inflammatory processes, is promoted by both the receptor's constitutive activity and agonist (i.e., histamine) binding at the H1 receptor.[2]

A combination of these effects, and in some cases metabolic ones as well, lead to most first-generation antihistamines having analgesic-sparing (potentiating) effects on opioid analgesics and to some extent with non-opioid ones as well. The most common antihistamines utilized for this purpose include hydroxyzine, promethazine (enzyme induction especially helps with codeine and similar prodrug opioids), phenyltoloxamine, orphenadrine, and tripelennamine; some may also have intrinsic analgesic properties of their own, orphenadrine being an example.

Second-generation antihistamines cross the blood–brain barrier to a much lesser extent than the first-generation antihistamines. They minimize sedatory effects due to their focused effect on peripheral histamine receptors. However, upon high doses second-generation antihistamines will begin to act on the central nervous system and thus can induce drowsiness when ingested in higher quantity. Additionally, some second-generation antihistamines, notably cetirizine, can interact with CNS psychoactive drugs such as bupropion and benzodiazepines.[11]

H1 antagonists/inverse agonists

H2-antihistamines

H2-antihistamines, like H1-antihistamines, exist as inverse agonists and neutral antagonists. They act on H2 histamine receptors found mainly in the parietal cells of the gastric mucosa, which are part of the endogenous signaling pathway for gastric acid secretion. Normally, histamine acts on H2 to stimulate acid secretion; drugs that inhibit H2 signaling thus reduce the secretion of gastric acid.

H2-antihistamines are among first-line therapy to treat gastrointestinal conditions including peptic ulcers and gastroesophageal reflux disease. Some formulations are available over the counter. Most side effects are due to cross-reactivity with unintended receptors. Cimetidine, for example, is notorious for antagonizing androgenic testosterone and DHT receptors at high doses.

Examples include:

H3-antihistamines

An H3-antihistamine is a classification of drugs used to inhibit the action of histamine at the H3 receptor. H3 receptors are primarily found in the brain and are inhibitory autoreceptors located on histaminergic nerve terminals, which modulate the release of histamine. Histamine release in the brain triggers secondary release of excitatory neurotransmitters such as glutamate and acetylcholine via stimulation of H1 receptors in the cerebral cortex. Consequently, unlike the H1-antihistamines which are sedating, H3-antihistamines have stimulant and cognition-modulating effects.

Examples of selective H3-antihistamines include:

H4-antihistamines

H4-antihistamines inhibit the activity of the H4 receptor.

Examples:

Atypical antihistamines

Histidine decarboxylase inhibitors

Inhibit the action of histidine decarboxylase:

Mast cell stabilizers

Mast cell stabilizers are drugs which prevent mast cell degranulation.

History

Currently most people who use an antihistamine to treat allergies use a second-generation drug.[1]

The first generation of antihistamine drugs became available in the 1930s.[16] This marked the beginning of medical treatment of nasal allergies.[16] Research into these drugs led to the discovery that they were H1 antagonists and also to the development of H2 antagonists, where H1 antihistamines affected the nose and the H2 antihistamines affected the stomach.[17] This history has led to contemporary research into drugs which are H3 receptor antagonist and which affect the Histamine H4 receptor.[17]

Society and culture

The United States government removed two second generation antihistamines, terfenadine and astemizole, from the market based on evidence that they could cause heart problems.[1]

Research

Not much published research exists which compares the efficacy and safety of the various antihistamines available.[1] The research which does exist is mostly short-term studies or studies which look at too few people to make general assumptions.[1] Another gap in the research is in information reporting the health effects for individuals with long term allergies to take antihistamines for a long period of time.[1] Newer antihistamines have been demonstrated to be effective in treating hives.[1] However, there is not research comparing the relative efficacy of these drugs.[1]

Special populations

Most studies of antihistamines reported on people who are younger, so the effects on people over age 65 are not as well understood.[1] Older people are more likely to experience drowsiness from antihistamine use than younger people.[1] Also, most of the research has been on white people and other ethnicities are not as represented in the research.[1] The evidence does not report how antihistamines affect women differently than men.[1] Different studies have reported on antihistamine use in children, with various studies finding evidence that certain antihistamines could be used by children 2 years of age, and other drugs being safer for younger or older children.[1]

gollark: No. They're not composable or anything.
gollark: Being able to read the low-level structure of the code (oh, this is looping over a thing and doing another thing) IS NOT THE SAME as UNDERSTANDING WHAT IT DOES AND WHY!
gollark: READABLE IS NOT COMPREHENSIBLE! WHEN WILL THEY UNDERSTAND?
gollark: So because "hurr durr me no want spend time understanding code" it's gone.
gollark: No, it shows that Guido in his infinite wisdom removed it.

See also

References

  1. Consumer Reports (2013), Using Antihistamines to Treat Allergies, Hay Fever, & Hives - Comparing Effectiveness, Safety, and Price (PDF), Yonkers, New York: Consumer Reports, archived from the original (PDF) on 17 May 2017, retrieved 29 June 2017
  2. Canonica GW, Blaiss M (2011). "Antihistaminic, anti-inflammatory, and antiallergic properties of the nonsedating second-generation antihistamine desloratadine: a review of the evidence". World Allergy Organ J. 4 (2): 47–53. doi:10.1097/WOX.0b013e3182093e19. PMC 3500039. PMID 23268457. The H1-receptor is a transmembrane protein belonging to the G-protein coupled receptor family. Signal transduction from the extracellular to the intracellular environment occurs as the GCPR becomes activated after binding of a specific ligand or agonist. A subunit of the G-protein subsequently dissociates and affects intracellular messaging including downstream signaling accomplished through various intermediaries such as cyclic AMP, cyclic GMP, calcium, and nuclear factor kappa B (NF-κB), a ubiquitous transcription factor thought to play an important role in immune-cell chemotaxis, proinflammatory cytokine production, expression of cell adhesion molecules, and other allergic and inflammatory conditions.1,8,12,30–32 ... For example, the H1-receptor promotes NF-κB in both a constitutive and agonist-dependent manner and all clinically available H1-antihistamines inhibit constitutive H1-receptor-mediated NF-κB production ...
    Importantly, because antihistamines can theoretically behave as inverse agonists or neutral antagonists, they are more properly described as H1-antihistamines rather than H1-receptor antagonists.15
  3. Panula P, Chazot PL, Cowart M, et al. (2015). "International Union of Basic and Clinical Pharmacology. XCVIII. Histamine Receptors". Pharmacol. Rev. 67 (3): 601–55. doi:10.1124/pr.114.010249. PMC 4485016. PMID 26084539.
  4. Leurs R, Church MK, Taglialatela M (April 2002). "H1-antihistamines: inverse agonism, anti-inflammatory actions and cardiac effects". Clinical and Experimental Allergy. 32 (4): 489–98. doi:10.1046/j.0954-7894.2002.01314.x. PMID 11972592.
  5. "H1 receptor". IUPHAR/BPS Guide to Pharmacology. Retrieved 8 October 2015.
  6. Norrby K (1995). "Evidence of a dual role of endogenous histamine in angiogenesis". Int J Exp Pathol. 76 (2): 87–92. PMC 1997159. PMID 7540412.
  7. Monroe EW, Daly AF, Shalhoub RF (February 1997). "Appraisal of the validity of histamine-induced wheal and flare to predict the clinical efficacy of antihistamines". The Journal of Allergy and Clinical Immunology. 99 (2): S798–806. doi:10.1016/s0091-6749(97)70128-3. PMID 9042073.
  8. Lee HE, Chang IK, Lee Y, Kim CD, Seo YJ, Lee JH, Im M (2014). "Effect of antihistamine as an adjuvant treatment of isotretinoin in acne: a randomized, controlled comparative study". J Eur Acad Dermatol Venereol. 28 (12): 1654–60. doi:10.1111/jdv.12403. PMID 25081735.
  9. Layton AM (2016). "Top Ten List of Clinical Pearls in the Treatment of Acne Vulgaris". Dermatol Clin. 34 (2): 147–57. doi:10.1016/j.det.2015.11.008. PMID 27015774.
  10. Church, Diana S; Church, Martin K (15 March 2011). "Pharmacology of Antihistamines". The World Allergy Organization Journal. 4 (Suppl 3): S22–S27. doi:10.1097/1939-4551-4-S3-S22. ISSN 1939-4551. PMC 3666185. PMID 23282332.
  11. "Drug Interaction Report". drugs.com. Retrieved 28 January 2017.
  12. Yoneyama H, et al. (March 2008). "Efficient approaches to S-alkyl-N-alkylisothioureas: syntheses of histamine H3 antagonist clobenpropit and its analogues". The Journal of Organic Chemistry. 73 (6): 2096–104. doi:10.1021/jo702181x. PMID 18278935.
  13. {{cite journal | vauthors = Fox GB, Esbenshade TA, Pan JB, Radek RJ, Krueger KM, Yao BB, Browman KE, Buckley MJ, Ballard ME, Komater VA, Miner H, Zhang M, Faghih R, Rueter LE, Bitner RS, Drescher KU, Wetter J, Marsh K, Lemaire M, Porsolt RD, Bennani YL, Sullivan JP, Cowart MD, Decker MW, Hancock AA | title = Pharmacological properties of ABT-239 [4-(2-{2-[(2R)-2-Methylpyrrolidinyl]ethyl}-benzofuran-5-yl)benzonitrile]: II. Neurophysiological characterization and broad preclinical efficacy in cognition and schizophrenia of a potent and selective histamine H3 receptor antagonist | journal = The Journal of Pharmacology and Experimental Therapeutics | volume = 313 | issue = 1 | pages = 176–90 | date = April 2005 | pmid = 15608077 | doi = 10.1124/jpet.104.078402 | url = http://jpet.aspetjournals.org/cgi/pmidlookup?view=long&pmid=15608077 }}
  14. Ligneau X, Lin J, Vanni-Mercier G, Jouvet M, Muir JL, Ganellin CR, Stark H, Elz S, Schunack W, Schwartz J (November 1998). "Neurochemical and behavioral effects of ciproxifan, a potent histamine H3-receptor antagonist". The Journal of Pharmacology and Experimental Therapeutics. 287 (2): 658–66. PMID 9808693.
  15. Esbenshade TA, Fox GB, Krueger KM, Baranowski JL, Miller TR, Kang CH, Denny LI, Witte DG, Yao BB, Pan JB, Faghih R, Bennani YL, Williams M, Hancock AA (September 2004). "Pharmacological and behavioral properties of A-349821, a selective and potent human histamine H3 receptor antagonist". Biochemical Pharmacology. 68 (5): 933–45. doi:10.1016/j.bcp.2004.05.048. PMID 15294456.
  16. Ostrom, NK (2014). "The history and progression of treatments for allergic rhinitis". Allergy and Asthma Proceedings. 35 Suppl 1 (3): S3–10. doi:10.2500/aap.2014.35.3758. PMID 25582156.
  17. Jones, AW (January 2016). "Perspectives in Drug Development and Clinical Pharmacology: The Discovery of Histamine H1 and H2 Antagonists". Clinical Pharmacology in Drug Development. 5 (1): 5–12. doi:10.1002/cpdd.236. PMID 27119574.
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