Chlordiazepoxide: Difference between revisions

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			{{short description\|Benzodiazepine medication}}
	{{Drugbox\|
			{{cs1 config\|name-list-style=vanc\|display-authors=6}}
	\| IUPAC_name = ''9-chloro-5-hydroxy-N-methyl-6-phenyl-<BR>2,5-diazabicycloundeca-<BR>1,6,8,10-tetraen-3-imine''
			{{Drugbox
	\| image = Chlordiazepoxide.png
			\| Watchedfields = changed
	\| width = 150
			\| class = ]
	\| image2 = Chlordiazepoxide3d.png
			\| verifiedrevid = 477165694
	\| width = 150
			\| IUPAC_name = 7-Chloro-2-methylamino-5-phenyl-3''H''-1,4-benzodiazepine-4-oxide
			\| image = Chlordiazepoxide structure.svg
			\| image2 = Chlordiazepoxide-from-xtal-1982-3D-balls.png

			<!--Clinical data-->\| tradename = Librium, others
			\| Drugs.com = {{drugs.com\|monograph\|chlordiazepoxide}}
			\| pronounce = {{IPAc-en\|ˌ\|k\|l\|ɔər\|d\|aɪ\|.\|ə\|z\|ᵻ\|ˈ\|p\|ɒ\|k\|s\|aɪ\|d}}
			\| MedlinePlus = a682078
			\| legal_AU = S4
			\| legal_BR = B1
			\| legal_BR_comment = <ref>{{Cite web \|author=Anvisa \|author-link=Brazilian Health Regulatory Agency \|date=2023-03-31 \|title=RDC Nº 784 - Listas de Substâncias Entorpecentes, Psicotrópicas, Precursoras e Outras sob Controle Especial \|trans-title=Collegiate Board Resolution No. 784 - Lists of Narcotic, Psychotropic, Precursor, and Other Substances under Special Control\|url=https://www.in.gov.br/en/web/dou/-/resolucao-rdc-n-784-de-31-de-marco-de-2023-474904992 \|url-status=live \|archive-url=https://web.archive.org/web/20230803143925/https://www.in.gov.br/en/web/dou/-/resolucao-rdc-n-784-de-31-de-marco-de-2023-474904992 \|archive-date=2023-08-03 \|access-date=2023-08-16 \|publisher=] \|language=pt-BR \|publication-date=2023-04-04}}</ref>
			\| legal_CA = Schedule IV
			\| legal_US = Schedule IV
			\| legal_DE = Rx-only/Anlage III
			\| legal_UK = Class C
			\| dependency_liability = High<ref name="Edmunds-2013">{{cite book \| vauthors = Edmunds M, Mayhew M \|year=2013 \|title= Pharmacology for the Primary Care Provider \|url=https://books.google.com/books?id=8FwdEsvnw8oC&pg=PA545 \|edition=4th \|publisher= Mosby \|page=545 \|isbn= 9780323087902 }}</ref>
			\| addiction_liability = Moderate
			\| routes_of_administration = ], ]

			<!--Pharmacokinetic data-->\| metabolism = ]
			\| metabolites = • ]<br> • ]<br>• ]<br> • ]<ref>{{cite journal \| vauthors = Greenblatt DJ, Shader RI, MacLeod SM, Sellers EM \| title = Clinical Pharmacokinetics of Chlordiazepoxide \| journal = Clinical Pharmacokinetics \| volume = 3 \| issue = 5 \| pages = 381–394 \| date = 1978 \| pmid = 359214 \| doi = 10.2165/00003088-197803050-00004 }}</ref>
			\| elimination_half-life = 5–30 hours (Active metabolite ] 36–200 hours: other active metabolites include ])
			\| excretion = ]

			<!--Identifiers-->\| IUPHAR_ligand = 3370
			\| CAS_number_Ref = {{cascite\|correct\|??}}
	\| CAS_number = 58-25-3		\| CAS_number = 58-25-3
	\| ATC_prefix = N05		\| ATC_prefix = N05
	\| ATC_suffix = BA02		\| ATC_suffix = BA02
	\| ATC_supplemental =
	\| PubChem = 2712		\| PubChem = 2712
			\| DrugBank_Ref = {{drugbankcite\|correct\|drugbank}}
	\| DrugBank = APRD00682
			\| DrugBank = DB00475
	\| C=16 \| H=14 \| Cl=1 \| N=3 \| O=1
			\| ChemSpiderID_Ref = {{chemspidercite\|correct\|chemspider}}
	\| molecular_weight = 299.8
			\| ChemSpiderID = 10248513
	\| bioavailability = well absorbed
			\| UNII_Ref = {{fdacite\|correct\|FDA}}
	\| metabolism = ]
			\| UNII = 6RZ6XEZ3CR
	\| elimination_half-life = 5-30 hours
			\| KEGG_Ref = {{keggcite\|correct\|kegg}}
	\| excretion = ]
	\| ~~pregnancy_US~~ = D		\| KEGG = D00267
			\| ChEBI_Ref = {{ebicite\|correct\|EBI}}
	\| legal_US = Schedule IV
			\| ChEBI = 3611
	\| routes_of_administration = oral <br> intramuscular
			\| ChEMBL_Ref = {{ebicite\|correct\|EBI}}
			\| ChEMBL = 451

			<!--Chemical data-->\| C = 16
			\| H = 14
			\| Cl = 1
			\| N = 3
			\| O = 1
			\| smiles = ClC1=CC2=C(N=C(NC)C()=C2C3=CC=CC=C3)C=C1
			\| StdInChI_Ref = {{stdinchicite\|correct\|chemspider}}
			\| StdInChI = 1S/C16H14ClN3O/c1-18-15-10-20(21)16(11-5-3-2-4-6-11)13-9-12(17)7-8-14(13)19-15/h2-9H,10H2,1H3,(H,18,19)
			\| StdInChIKey_Ref = {{stdinchicite\|correct\|chemspider}}
			\| StdInChIKey = ANTSCNMPPGJYLG-UHFFFAOYSA-N
	}}		}}
			<!-- Definition and medical uses -->
	'''Chlordiazepoxide''' (pronounced , marketed under the trade name '''Librium®''') is a ]/] drug which is a ] derivative. It has a medium to long ].

			'''Chlordiazepoxide''', sold under the brand name '''Librium''' among others, is a ] and ] medication of the ] class. It is used to treat ], ] and symptoms of ] from ], ], and other drugs.
	==History==
	''See the main article ] for the history of Librium.''

			Chlordiazepoxide has a medium to long ], while its ] has a very long half-life. The drug has ], ], ], ], ], and ] properties.<ref>{{cite journal \| vauthors = Liljequist R, Palva E, Linnoila M \| title = Effects on learning and memory of 2-week treatments with chlordiazepoxide lactam, N-desmethyldiazepam, oxazepam and methyloxazepam, alone or in combination with alcohol \| journal = International Pharmacopsychiatry \| volume = 14 \| issue = 4 \| pages = 190–8 \| year = 1979 \| pmid = 42628 \| doi=10.1159/000468381}}</ref>
	The correct IUPAC name is: 7-chloro-2(methylamine)-5-phenyl-3H-1,4-benzodiazepine-4-oxide-hydrochloride.

			<!-- Definition and medical uses -->
	==Pharmacology==
			Chlordiazepoxide was patented in 1958 and approved for medical use in 1960.<ref name=Fis2006>{{cite book \| vauthors = Fischer J, Ganellin CR \|title=Analogue-based Drug Discovery \|date=2006 \|publisher=John Wiley & Sons \|isbn=9783527607495 \|page=535 \|url=https://books.google.com/books?id=FjKfqkaKkAAC&pg=PA535 \|language=en}}</ref> It was the first benzodiazepine to be synthesized and the discovery of chlordiazepoxide was by pure chance.<ref>{{cite journal \| vauthors = Ban TA \| title = The role of serendipity in drug discovery \| journal = Dialogues in Clinical Neuroscience \| volume = 8 \| issue = 3 \| pages = 335–44 \| year = 2006 \| doi = 10.31887/DCNS.2006.8.3/tban \| pmid = 17117615 \| pmc = 3181823 }}</ref> Chlordiazepoxide and other benzodiazepines were initially accepted with widespread public approval, but were followed with widespread public disapproval and recommendations for more restrictive medical guidelines for its use.<ref name="Marshall-2009">{{cite journal \| vauthors = Marshall KP, Georgievskava Z, Georgievsky I \| title = Social reactions to Valium and Prozac: a cultural lag perspective of drug diffusion and adoption \| journal = Research in Social & Administrative Pharmacy \| volume = 5 \| issue = 2 \| pages = 94–107 \| date = June 2009 \| pmid = 19524858 \| doi = 10.1016/j.sapharm.2008.06.005 }}</ref>
	Chlordiazepoxide acts on benzodiazepine subreceptors of the main GABA<sub>A</sub> receptor and this results in an increased binding of the inhibitory neurotransmitter ] to the GABA<sub>A</sub> receptor thereby producing inhibitory effects on the ] and body similar to the effects of other ].<ref>{{cite journal \| author = Skerritt JH \| coauthors = Johnston GA. \| year = 1983 \| month = May \| date = 6 \| title = Enhancement of GABA binding by benzodiazepines and related anxiolytics. \| journal = Eur J Pharmacol. \| volume = 89 \| issue = 3-4 \| pages = 193-8 \| pmid = 6135616 }}</ref> Chlordiazepoxide is ] as well as ].<ref>{{cite journal \| journal = Life Sci \| year = 1985\| month = Feb\| date = 25\| volume = 36\| issue = 8\| pages = 737-44\| title = Effect of GABA agonists on the neurotoxicity and anticonvulsant activity of benzodiazepines\| author = Chweh AY\| coauthors = Swinyard EA, Wolf HH, Kupferberg HJ\| pmid = 2983169}}</ref> Chlordiazepoxide at high doses decreases histamine turnover via its action at the benzodiazepine-GABA receptor complex.<ref>{{cite journal \| author = Oishi R \| coauthors = Nishibori M, Itoh Y, Saeki K. \| year = 1986 \| month = May \| date = 27 \| title = Diazepam-induced decrease in histamine turnover in mouse brain. \| journal = Eur J Pharmacol. \| volume = 124 \| issue = 3
			{{TOC limit}}
	\| pages = 337-42 \| pmid = 3089825 }}</ref> Chlordiazepoxide is molecularly related to ] and is a ].<ref>{{cite journal \| author = Earley JV \| coauthors = Fryer RI, Ning RY. \| year = 1979 \| month = Jul \| title = Quinazolines and 1,4-benzodiazepines. LXXXIX: Haptens useful in benzodiazepine immunoassay development. \| journal = J Pharm Sci. \| volume = 68 \| issue = 7 \| pages = 845-50 \| pmid = 458601 }}</ref>
	There is preferential storage of chlordiazepoxide in some organs including the heart. Absortion by any administered route and the risk of accumulation is significantly increased in the neonate and there are clinical justification to recommend the withdrawal of chlordiazepoxide during pregnancy and breast feeding as chlordiazepoxide rapidly crosses the placenta and also is excreted in breast milk.<ref>{{cite journal \| author = Olive G \| coauthors = Dreux C. \| year = 1977 \| month = Jan \| title = Pharmacologic bases of use of benzodiazepines in peréinatal medicine. \| journal = Arch Fr Pediatr. \| volume = 34(1) \| pages = 74-89 \| pmid = 851373 }}</ref> Chlordiazepoxide induces ] in ] cells via binding to high affinity sites and modulating cell differentiation.<ref>{{cite journal \|author=Matthew E \|coauthors=Laskin JD, Zimmerman EA, Weinstein IB, Hsu KC, Engelhardt DL \|year=1981 \|month=Jun \|title=Benzodiazepines have high-affinity binding sites and induce melanogenesis in B16/C3 melanoma cells \|journal=Proc Natl Acad Sci U S A \|volume=78 \|issue=6 \|pages=3935-9 \|url=http://www.pubmedcentral.nih.gov/picrender.fcgi?artid=319688&blobtype=pdf \|pmid=6267610}}</ref> Chlordiazepoxide also decreases prolactin release.<ref>{{cite journal \|author=Grandison L \|year=1982 \|title=Suppression of prolactin secretion by benzodiazepines in vivo \|journal=Neuroendocrinology \|volume=34 \|issue=5 \|pages=369-73 \|pmid=6979001}}</ref> Benzodiazepines act via ] benzodiazepine binding sites as ] channel blockers and significantly inhibit depolarization-sensitive Calcium uptake.<ref>{{cite journal \| journal = Proc Natl Acad Sci U S A \| year = 1984 \| month = May \| volume = 81 \| issue = 10 \| pages = 3118-22 \| url = http://www.pnas.org/cgi/reprint/81/10/3118.pdf \| type = PDF \| title = Micromolar-affinity benzodiazepine receptors regulate voltage-sensitive calcium channels in nerve terminal preparations \| author = Taft WC \|coauthors = DeLorenzo RJ \| pmid = 6328498}}</ref> Chlordiazepoxide has been found to inhibit ] release and sodium-dependent high affinity ] uptake which may play a role in chlordiazepoxide's ] properties.<ref>{{cite journal \| journal = Br J Pharmacol \| year = 1985 \| month = Jan \| volume = 84 \| issue = 1 \| pages = 19-25 \| title = Effects of anticonvulsants in vivo on high affinity choline uptake in vitro in mouse hippocampal synaptosomes \| author = Miller JA \| coauthors = Richter JA \| pmid = 3978310 \| url = http://www.pubmedcentral.nih.gov/picrender.fcgi?artid=1987204&blobtype=pdf\| format = PDF }}</ref>

	Chlordiazepoxide is a long acting benzodiazepine drug. The half life of Chlordiazepoxide is 5-30 hours but has an active benzodiazepine metabolite which has a half life of 36 - 200 hours.<ref>{{cite web \| url = http://www.bcnc.org.uk/equivalence.html \| title = BENZODIAZEPINE EQUIVALENCY TABLE \| accessmonthday = Sept 23 \| accessyear = 2007 \| author = Ashton CH. \| year = 2007 \| month = April }}</ref> The half life of chlordiazepoxide increases significantly in the elderly which may result in prolonged action as well as accumulation of the drug during repeated administration. Delayed body clearance of the long half life active metabolite also occurs in those over 60 years of age which further prolongs the effects of the drugs with additional accumulation after repeated dosing.<ref>{{cite journal \| author = Vozeh S. \| coauthors = \| year = 1981 \| month = Nov \| date = 21 \| title = \| journal = Schweiz Med Wochenschr. \| volume = 111 \| issue = 47 \| pages = 1789-93 \| pmid = 6118950 }}</ref>

	==Tolerance==
	Chronic use of benzodiazepines, such as chlordiazepoxide leads to the development of tolerance with a decrease in number of benzodiazepine binding sites.<ref>{{cite journal \|author=Crawley JN \|coauthors=Marangos PJ, Stivers J, Goodwin FK \|year=1982 \|month=Jan \|title=Chronic clonazepam administration induces benzodiazepine receptor subsensitivity \|volume=21 \|issue=1 \|pages=85-9 \|pmid=6278355 \|journal=Neuropharmacology}}</ref>Tolerance to the ] effects develops rapidly and a stimulating effect develops after repeated daily administration.<ref>{{cite journal \| author = Nowakowska E \| coauthors = Chodera A, Cenajek-Musiał D, Szczawińska K. \| year = 1987 \| month = May-Jun \| title = Differences in the development of tolerance to various benzodiazepines. \| journal = Pol J Pharmacol Pharm. \| volume = 39 \| issue = 3 \| pages = 245-52 \| pmid = 2894019 }}</ref> In mice tolerance to the anticonvulsant properties of chlordiazepoxide developed slowly over 15 days, although some anticonvulsant effects were still apparent after 15 days of continued administration.<ref>{{cite journal \| author = Garratt JC \| coauthors = Gent JP, Feely M, Haigh JR. \| year = 1988 \| month = Jan \| date = 5 \| title = Can benzodiazepines be classified by characterising their anticonvulsant tolerance-inducing potential? \| journal = Eur J Pharmacol. \| volume = 145 \| issue = 1 \| pages = 75-80 \| pmid = 2894998 }}</ref>

	==Dependence==

			==Medical uses==
	Chlordiazepoxide can cause ], ] and what is known as the ]. Withdrawal from chlordiazepoxide or other benzodiazepines often leads to withdrawal symptoms which are similar to those seen with alcohol and ]. The higher the dose and the longer the drug is taken the greater the risk of experiencing unpleasant withdrawal symptoms. Withdrawal symptoms can however occur at standard dosages and also after short term use. Benzodiazepine treatment should be discontinued as soon as possible via a slow and gradual dose reduction regime.<ref>{{cite journal \| author = MacKinnon GL \| coauthors = Parker WA. \| year = 1982 \| month = \| title = Benzodiazepine withdrawal syndrome: a literature review and evaluation. \| journal = The American journal of drug and alcohol abuse. \| volume = 9 \| issue = 1 \| pages = 19-33 \| pmid = 6133446 }}</ref>
			Chlordiazepoxide is indicated for the short-term (2–4 weeks) treatment of ] that is severe and disabling or subjecting the person to unacceptable distress. It is also indicated as a treatment for the management of acute ].<ref name=UKlabelGeneric>{{cite web\|title=Chlordiazepoxide 10mg Capsules - Summary of Product Characteristics\|url=https://www.medicines.org.uk/emc/medicine/26299\|publisher=UK Electronic Medicines Compendium\|access-date=23 April 2017\|language=en\|date=19 December 2012\|archive-date=23 April 2017\|archive-url=https://web.archive.org/web/20170423152643/https://www.medicines.org.uk/emc/medicine/26299\|url-status=dead}}</ref>

			It can sometimes be prescribed to ease symptoms of ] (IBS) combined with ] as a fixed dose medication, ].<ref>{{cite web\|title=Chlordiazepoxide\|url=https://medlineplus.gov/druginfo/meds/a682078.html\|publisher=MedlinePlus Drug Information\|language=en\|date=February 15, 2017}}</ref>
	===The Committee on the Review of Medicines===

	The Committee on the Review of Medicines (UK) carried out a review into benzodiazepines due to significant concerns of tolerance, ] and ] problems and other adverse effects. The committee found that benzodiazepines do not have any ] or ] properties and are therefore unsuitable treatments for conditions such as depression, ] and ]. Benzodiazepines are also not beneficial in the treatment of ]. The committee also recommended against benzodiazepines being used in the treatment of ] or ] in children. The committee was in agreement with the ] (USA) and the conclusions of a study carried out by the White House Office of Drug Policy and the ] (USA) that there was little evidence that long term use of benzodiazepine hypnotics were benefitial in the treatment of insomnia due to the development of tolerance. Benzodiazepines tended to lose their sleep promoting properties within 3 - 14 days of continuous use and in the treatment of anxiety the committee found that there was little convincing evidence that benzodiazepines retained efficacy in the treatment of anxiety after 4 months continuous use due to the development of tolerance. The committee found that the regular use of benzodiazepines caused the development of dependence characterised by tolerance to the therapeutic effects of benzodiazepines and the development of the ] including symptoms such as ], ], ], ], ], and ] upon cessation of benzodiazepine use. Withdrawal symptoms tended to develop within 24 hours upon cessation of short acting; and 3 - 10 days after cessation of longer acting benzodiazepines. Withdrawal effects could occur after treatment lasting only 2 weeks at therapeutic dose levels however withdrawal effects tended to occur with habitual use beyond 2 weeks and were more likely the higher the dose. The withdrawal symptoms may appear to be similar to the original condition. The committee recommended that all benzodiazepine treatment be withdrawn gradually and recommended that benzodiazepine treatment be used only in carefully selected patients and that therapy be limited to short term use only. It was noted in the review that alcohol can potentiate the ] depressant effects of benzodiazepines and should be avoided. The central nervous system depressant effects of benzodiazepines may make driving or operating machinery dangerous and the elderly are more prone to these adverse effects. In the ] high single doses or repeated low doses have been reported to produce ], poor sucking, and ] in the ] and irregularities in the ] heart. Benzodiazepines should be avoided in ]. Withdrawal from benzodiazepines should be gradual as abrupt withdrawal from high doses of benzodiazepines may cause ], ], ], or a condition resembling ]. Abrupt withdrawal from lower doses may cause depression, ], ], ], ], and ].<ref>{{cite journal \| author = Committee on the Review of Medicines \| year = 1980 \| month = Mar \| date = 29 \| title = Systematic review of the benzodiazepines. Guidelines for data sheets on diazepam, chlordiazepoxide, medazepam, clorazepate, lorazepam, oxazepam, temazepam, triazolam, nitrazepam, and flurazepam. Committee on the Review of Medicines. \| journal = Br Med J. \| volume = 280 \| issue = 6218 \| pages = 910-2 \| pmid = 7388368 \| url = http://www.pubmedcentral.nih.gov/picrender.fcgi?artid=1601049&blobtype=pdf \| format = pdf }}</ref>

	==Abuse Potential==
	Chlordiazepoxide is frequently detected in urine samples of drug abusers who have not been prescribed the drug suggesting a high misuse potential for chlordiazepoxide.<ref>{{cite journal \| author = Garretty DJ \| coauthors = Wolff K, Hay AW, Raistrick D. \| year = 1997 \| month = Jan \| title = Benzodiazepine misuse by drug addicts. \| journal = Annals of clinical biochemistry. \| volume = 34 \| issue = Pt 1 \| pages = 68-73 \| pmid = 9022890 }}</ref>
	Chlordiazepoxide in animal studies has been shown to increase reward seeking behaviours which may suggest an increased risk of addictive behavioural patterns.<ref>{{cite journal \| author = Thiébot MH \| coauthors = Le Bihan C, Soubrié P, Simon P. \| year = 1985 \| month = \| title = Benzodiazepines reduce the tolerance to reward delay in rats. \| volume = 86 \| issue = 1-2 \| pages = 147-52 \| pmid = 2862657 \| journal = Psychopharmacology (Berl).}}</ref>

	==Indications==
	Chlordiazepoxide is indicated for the short term (2 - 4 weeks) treatment of severe and distressing insomnia, anxiety and panic attacks. It has also been used as a treatment for acute alcohol or opiate withdrawal, as well as relief from Crohn's and ulcerative colitis.

	==Dosage==
	Chlordiazepoxide is available in 5mg, 10mg and 25mg strengths.

	==Side effects==
	Common side effects of chlordiazepoxide include:
	* Drowsiness
	* ]
	* Impaired motor function
	** Impaired coordination
	** Impaired balance
	** ]
	* ]
	* ] (especially pronounced in higher doses)
	* Impaired learning

	Chlordiazepoxide in laboratory studies impairs latent learning. Benzodiazepines impair learning and memory via their action on benzodiazepine receptors which causes a dysfunction in the cholinergic neuronal system.<ref>{{cite journal \| author = Nabeshima T \| coauthors = Tohyama K, Ichihara K, Kameyama T. \| year = 1990 \| month = Nov \| title = Effects of benzodiazepines on passive avoidance response and latent learning in mice: relationship to benzodiazepine receptors and the cholinergic neuronal system. \| journal = J Pharmacol Exp Ther. \| volume = 255 \| issue = 2 \| pages = 789-94 \| pmid = 2173758 }}</ref> In tests of various benzodiazepine compounds Chlordiazepoxide was found to cause the most profound reduction in the turnover of 5HT (]). Serotonin is closely involved in regulating mood and may be one of the causes of feelings of depression in users of Chlordiazepoxide or other benzodiazepines.<ref>{{cite journal \| author = Antkiewicz-Michaluk L \| coauthors = Grabowska M, Baran L, Michaluk J. \| year = 1975 \| month = \| title = Influence of benzodiazepines on turnover of serotonin in cerebral structures in normal and aggressive rats. \| journal = Arch Immunol Ther Exp (Warsz). \| volume = 23 \| issue = 6 \| pages = 763-7 \| pmid = 1241268 }}</ref>

	]

	==Contraindications==		==Contraindications==
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	* Hypersensitivity or allergy to any drug in the ] class		* Hypersensitivity or allergy to any drug in the ] class

			Chlordiazepoxide is generally considered an inappropriate benzodiazepine for the elderly due to its long ] and the risks of accumulation.<ref>{{cite journal \| vauthors = Liu GG, Christensen DB \| title = The continuing challenge of inappropriate prescribing in the elderly: an update of the evidence \| journal = Journal of the American Pharmaceutical Association \| volume = 42 \| issue = 6 \| pages = 847–57 \| year = 2002 \| pmid = 12482007 \| doi = 10.1331/108658002762063682 }}</ref> Benzodiazepines require special precaution if used in the elderly, pregnancy, children, alcohol- or drug-dependent individuals and individuals with ] ].<ref>{{cite journal \| vauthors = Authier N, Balayssac D, Sautereau M, Zangarelli A, Courty P, Somogyi AA, Vennat B, Llorca PM, Eschalier A \| title = Benzodiazepine dependence: focus on withdrawal syndrome \| journal = Annales Pharmaceutiques Françaises \| volume = 67 \| issue = 6 \| pages = 408–13 \| date = November 2009 \| pmid = 19900604 \| doi = 10.1016/j.pharma.2009.07.001 }}</ref>
	==Interactions==
	Oral contraceptive pills, reduce the clearance of chlordiazepoxide which may lead to increased plasma levels of chlordiazepoxide and accumulation.<ref>{{cite journal \| author = Back DJ \| coauthors = Orme ML. \| year = 1990 \| month = Jun \| title = Pharmacokinetic drug interactions with oral contraceptives. \| journal = Clin Pharmacokinet. \| volume = 18 \| issue = 6 \| pages = 472-84 \| pmid = 2191822 }}</ref> Chlordiazepoxide interacts with contraceptives resulting in increased bleeding.<ref>{{cite journal \|author=Somos P. \|coauthors= \|title= Interaction between certain psychopharmaca and low-dose oral contraceptives. \|volume=38 \|issue=1 \|pages=37-40 \|year=1990 \|pmid=1971733 }}</ref>

			===Pregnancy===
	] a drug with anticonvulsant properties, reduces the anticonvulsant protency of chlordiazepoxide.<ref>{{cite journal \| author = Consroe P \| coauthors = Wolkin A. \| year = 1977 \| month = Apr \| title = Cannabidiol--antiepileptic drug comparisons and interactions in experimentally induced seizures in rats. \| journal = J Pharmacol Exp Ther. \| volume = 201 \| issue = 1 \| pages = 26-32 \| pmid = 850145 }}</ref>
			The research into the safety of benzodiazepines during pregnancy is limited and it is recommended that use of benzodiazepines during pregnancy should be based on whether the benefits outweigh the risks. If chlordiazepoxide is used during pregnancy the risks can be reduced via using the lowest effective dose and for the shortest time possible. Benzodiazepines should generally be avoided during the ] of pregnancy. Chlordiazepoxide and ] are considered to be among the safer benzodiazepines to use during pregnancy in comparison to other benzodiazepines. Possible adverse effects from benzodiazepine use during pregnancy include, ], ], ], functional deficits, ] and ]. Caution is also advised during ] as chlordiazepoxide passes into breast milk.<ref>{{cite journal \| vauthors = Iqbal MM, Aneja A, Fremont WP \| title = Effects of chlordiazepoxide (Librium) during pregnancy and lactation \| journal = Connecticut Medicine \| volume = 67 \| issue = 5 \| pages = 259–62 \| date = May 2003 \| pmid = 12802839 }}</ref><ref>{{cite journal \| vauthors = Iqbal MM, Sobhan T, Ryals T \| title = Effects of commonly used benzodiazepines on the fetus, the neonate, and the nursing infant \| journal = Psychiatric Services \| volume = 53 \| issue = 1 \| pages = 39–49 \| date = January 2002 \| pmid = 11773648 \| doi = 10.1176/appi.ps.53.1.39 }}</ref>

	==~~Overdose~~==		==Adverse effects==
			Sedative drugs and sleeping pills, including chlordiazepoxide, have been associated with an increased risk of death.<ref>{{cite journal \| vauthors = Kripke DF \| title = Mortality Risk of Hypnotics: Strengths and Limits of Evidence \| journal = Drug Safety \| volume = 39 \| issue = 2 \| pages = 93–107 \| date = February 2016 \| pmid = 26563222 \| doi = 10.1007/s40264-015-0362-0 \| s2cid = 7946506 \| url = https://escholarship.org/content/qt08d9f3d5/qt08d9f3d5.pdf?t=nz1gjv \| doi-access = free }}</ref> The studies had many limitations, such as possible tendency to overestimate risk, possible confounding by indication with other risk factors and confusing hypnotics with drugs having other indications.
	An individual who has consumed too much chlordiazepoxide will display one or more of the following symptoms:

			Common side-effects of chlordiazepoxide include:<ref>{{cite web\|url= https://www.drugs.com/pdr/chlordiazepoxide.html\|title= Chlordiazepoxide patient advice including side-effects\|access-date= April 7, 2008\|author= drugs\|publisher= drugs.com}}</ref>
			* ]
			* ]
			* ]
			* ]
			* Altered ]
			* Liver problems
			* Lack of muscle coordination
			* Minor menstrual irregularities
			* ]
			* Skin rash or eruptions
			* Swelling due to fluid retention
			* Yellow eyes and skin

			Chlordiazepoxide in laboratory mice studies impairs latent learning. Benzodiazepines impair learning and memory via their action on benzodiazepine receptors, which causes a dysfunction in the cholinergic neuronal system in mice.<ref>{{cite journal \| vauthors = Nabeshima T, Tohyama K, Ichihara K, Kameyama T \| title = Effects of benzodiazepines on passive avoidance response and latent learning in mice: relationship to benzodiazepine receptors and the cholinergic neuronal system \| journal = The Journal of Pharmacology and Experimental Therapeutics \| volume = 255 \| issue = 2 \| pages = 789–94 \| date = November 1990 \| pmid = 2173758 }}</ref> It was later found that impairment in learning was caused by an increase in benzodiazepine/] activity (and that benzodiazepines were not associated with the cholinergic system).<ref>{{cite journal \| vauthors = McNamara RK, Skelton RW \| title = Assessment of a cholinergic contribution to chlordiazepoxide-induced deficits of place learning in the Morris water maze \| journal = Pharmacology Biochemistry and Behavior \| volume = 41 \| issue = 3 \| pages = 529–38 \| date = March 1992 \| pmid = 1316618 \| doi = 10.1016/0091-3057(92)90368-p \| s2cid = 42752576 }}</ref> In tests of various benzodiazepine compounds, chlordiazepoxide was found to cause the most profound reduction in the turnover of 5HT (]) in rats. Serotonin is closely involved in regulating mood and may be one of the causes of feelings of depression in rats using chlordiazepoxide or other benzodiazepines.<ref>{{cite journal \| vauthors = Antkiewicz-Michaluk L, Grabowska M, Baran L, Michaluk J \| title = Influence of benzodiazepines on turnover of serotonin in cerebral structures in normal and aggressive rats \| journal = Archivum Immunologiae et Therapiae Experimentalis \| volume = 23 \| issue = 6 \| pages = 763–7 \| year = 1975 \| pmid = 1241268 }}</ref>

			]

			In September 2020, the US ] (FDA) required the ] for all benzodiazepine medicines to be updated to describe the risks of abuse, misuse, addiction, physical dependence, and withdrawal reactions consistently across all the medicines in the class.<ref>{{cite web \| title=FDA expands Boxed Warning to improve safe use of benzodiazepine drug \| website=U.S. ] (FDA) \| date=23 September 2020 \| url=https://www.fda.gov/drugs/drug-safety-and-availability/fda-requiring-boxed-warning-updated-improve-safe-use-benzodiazepine-drug-class \| access-date=23 September 2020}} {{PD-notice}}</ref>

			===Tolerance and dependence===
			====Tolerance====
			Chronic use of benzodiazepines, such as chlordiazepoxide, leads to the development of tolerance, with a decrease in number of benzodiazepine binding sites in mice forebrains.<ref>{{cite journal \| vauthors = Crawley JN, Marangos PJ, Stivers J, Goodwin FK \| title = Chronic clonazepam administration induces benzodiazepine receptor subsensitivity \| journal = Neuropharmacology \| volume = 21 \| issue = 1 \| pages = 85–9 \| date = January 1982 \| pmid = 6278355 \| doi = 10.1016/0028-3908(82)90216-7 \| s2cid = 24771398 \| author-link = Jacqueline Crawley }}</ref> The Committee of Review of Medicines, who carried out an extensive review of benzodiazepines including chlordiazepoxide, found—and were in agreement with the US ] and the conclusions of a study carried out by the White House Office of Drug Policy and the US ]—that there was little evidence that long-term use of benzodiazepines was beneficial in the treatment of insomnia due to the development of tolerance. Benzodiazepines tended to lose their sleep-promoting properties within 3 to 14 days of continuous use, and in the treatment of anxiety the committee found that there was little convincing evidence that benzodiazepines retained efficacy in the treatment of anxiety after four months' continuous use due to the development of tolerance.<ref>{{cite journal \| author = Committee on the Review of Medicines \| title = Systematic review of the benzodiazepines. Guidelines for data sheets on diazepam, chlordiazepoxide, medazepam, clorazepate, lorazepam, oxazepam, temazepam, triazolam, nitrazepam, and flurazepam. \| journal = British Medical Journal \| volume = 280 \| issue = 6218 \| pages = 910–2 \| date = March 1980 \| pmid = 7388368 \| pmc = 1601049 \| doi = 10.1136/bmj.280.6218.910 }}</ref>

			====Dependence====
			Chlordiazepoxide can cause ] and what is known as the ]. Withdrawal from chlordiazepoxide or other benzodiazepines often leads to withdrawal symptoms that are similar to those seen with alcohol and ]. The higher the dose and the longer the drug is taken, the greater the risk of experiencing unpleasant withdrawal symptoms. Withdrawal symptoms can, however, occur at standard dosages and also after short-term use. Benzodiazepine treatment should be discontinued as soon as possible through a slow and gradual dose-reduction regime.<ref>{{cite journal \| vauthors = MacKinnon GL, Parker WA \| title = Benzodiazepine withdrawal syndrome: a literature review and evaluation \| journal = The American Journal of Drug and Alcohol Abuse \| volume = 9 \| issue = 1 \| pages = 19–33 \| year = 1982 \| pmid = 6133446 \| doi = 10.3109/00952998209002608 }}</ref>

			Chlordiazepoxide taken during pregnancy can cause a ] ].<ref>{{cite journal \| vauthors = Moretti M, Montali S \| title = \| journal = La Pediatria Medica e Chirurgica \| volume = 4 \| issue = 5 \| pages = 481–90 \| date = September 1982 \| pmid = 6985425 }}</ref>

			===Overdose===
			{{See also\|Benzodiazepine overdose}}
			An individual who has consumed excess chlordiazepoxide may display some of the following symptoms:
	* ] (difficulty staying awake)		* ] (difficulty staying awake)
	* Mental confusion		* Mental confusion
	* ]		* ]
	* ]		* ]
	* Impaired motor functions		* Impaired motor functions
	** Impaired reflexes		** Impaired reflexes
	** Impaired coordination		** Impaired coordination
	** Impaired balance		** Impaired balance
	** ]		** ]
	** Muscle ~~Weakness~~		** ]
	* ]		* ]

			Chlordiazepoxide is typically used under controlled conditions for specific syndromes and sees far less frequent usage when compared to newer drugs of the same class and thus is unlikely to be encountered in a clinical emergency setting as a stand-alone drug causing life-threatening concern. Like other drugs in its class, chlordiazepoxide alongside benzodiazepines as a whole have a lowered potential to cause life-threatening injury - though this does not preclude their common co-contaminant discovery with other depressant drugs of abuse, nor their ability to contribute to an already potentially fatal episode of drug-induced respiratory depression. In cases of suspected overdose, supportive care and observation are most often indicated and provided incrementally in relation to severity and duration of symptoms. ] is uniquely poised as an "antidote" that specifically counteracts damaging ] affect induced via benzodiazepine mechanism of action - though is not generally indicated in relation to the severity of symptoms where other treatment options exist, and often has numerous damaging consequences that must be carefully weighted before any potential administration.<ref>Kang M, Galuska MA, Ghassemzadeh S. Benzodiazepine Toxicity. . In: StatPearls . Treasure Island (FL): StatPearls Publishing; 2024 Jan-. Available from: https://www.ncbi.nlm.nih.gov/books/NBK482238/
	In animal models, the oral LD<sub>50</sub> of chlordiazepoxide is 537 mg/kg.
			</ref>

			==Pharmacology==
	Chlordiazepoxide is a drug which is very frequently involved in drug intoxication, including overdose.<ref>{{cite journal \| author = Zevzikovas A \| coauthors = Kiliuviene G, Ivanauskas L, Dirse V. \| year = 2002 \| month = \| date = \| title = \| journal = Medicina (Kaunas). \| volume = 38 \| issue = 3 \| pages = 316-20 \| pmid = 12474705 }}</ref> Chlordiazepoxide overdose is considered a medical emergency and generally requires the immediate attention of medical personnel. The ] for an overdose of chlordiazepoxide (or any other benzodiazepine) is ] (Anexate®).
			Chlordiazepoxide acts on ] allosteric sites that are part of the GABA<sub>A</sub> receptor/ion-channel complex and this results in an increased binding of the inhibitory neurotransmitter ] to the GABA<sub>A</sub> receptor thereby producing inhibitory effects on the ] and body similar to the effects of other ].<ref>{{cite journal \| vauthors = Skerritt JH, Johnston GA \| title = Enhancement of GABA binding by benzodiazepines and related anxiolytics \| journal = European Journal of Pharmacology \| volume = 89 \| issue = 3–4 \| pages = 193–8 \| date = May 1983 \| pmid = 6135616 \| doi = 10.1016/0014-2999(83)90494-6 }}</ref> Chlordiazepoxide is an ].<ref>{{cite journal \| vauthors = Chweh AY, Swinyard EA, Wolf HH, Kupferberg HJ \| title = Effect of GABA agonists on the neurotoxicity and anticonvulsant activity of benzodiazepines \| journal = Life Sciences \| volume = 36 \| issue = 8 \| pages = 737–44 \| date = February 1985 \| pmid = 2983169 \| doi = 10.1016/0024-3205(85)90193-6 }}</ref>

			Chlordiazepoxide is preferentially stored in some organs including the hearts of neonates. Absorption by any administered route and the risk of accumulation is significantly higher in neonates. The withdrawal of chlordiazepoxide during pregnancy and breast feeding is recommended, as chlordiazepoxide rapidly crosses the placenta and also is excreted in breast milk.<ref>{{cite journal \| vauthors = Olive G, Dreux C \| title = \| journal = Archives Françaises de Pédiatrie \| volume = 34 \| issue = 1 \| pages = 74–89 \| date = January 1977 \| pmid = 851373 }}</ref> Chlordiazepoxide also decreases prolactin release in rats.<ref>{{cite journal \| vauthors = Grandison L \| title = Suppression of prolactin secretion by benzodiazepines in vivo \| journal = Neuroendocrinology \| volume = 34 \| issue = 5 \| pages = 369–73 \| year = 1982 \| pmid = 6979001 \| doi = 10.1159/000123330 }}</ref> Benzodiazepines act via ] benzodiazepine binding sites as ] channel blockers and significantly inhibit depolarization-sensitive Calcium uptake in animal nerve terminal preparations.<ref>{{cite journal \| vauthors = Taft WC, DeLorenzo RJ \| title = Micromolar-affinity benzodiazepine receptors regulate voltage-sensitive calcium channels in nerve terminal preparations \| journal = Proceedings of the National Academy of Sciences of the United States of America \| volume = 81 \| issue = 10 \| pages = 3118–22 \| date = May 1984 \| pmid = 6328498 \| pmc = 345232 \| doi = 10.1073/pnas.81.10.3118 \| bibcode = 1984PNAS...81.3118T \| url = http://www.pnas.org/cgi/reprint/81/10/3118.pdf \| type = PDF \| doi-access = free }}</ref> Chlordiazepoxide inhibits ] release in mouse hippocampal synaptosomes in vivo. This has been found by measuring sodium-dependent high affinity ] uptake in vitro after pretreatment of the mice in vivo with chlordiazepoxide. This may play a role in chlordiazepoxide's anticonvulsant properties.<ref>{{cite journal \| vauthors = Miller JA, Richter JA \| title = Effects of anticonvulsants in vivo on high affinity choline uptake in vitro in mouse hippocampal synaptosomes \| journal = British Journal of Pharmacology \| volume = 84 \| issue = 1 \| pages = 19–25 \| date = January 1985 \| pmid = 3978310 \| pmc = 1987204 \| doi = 10.1111/j.1476-5381.1985.tb17368.x }}</ref>
	==Legal status==

	Internationally, chlordiazepoxide is a Schedule IV drug under the ].
			==Pharmacokinetics==
			Chlordiazepoxide is a long-acting benzodiazepine drug. The half-life of chlordiazepoxide is from 5 to 30 hours but has an active benzodiazepine metabolite, ], which has a half-life of 36 to 200 hours.<ref>{{cite web \| url = http://www.bcnc.org.uk/equivalence.html \| title = Benzodiazepine equivalency table \| access-date = September 23, 2007 \| author = Ashton CH. \| date = April 2007 \| archive-date = September 28, 2007 \| archive-url = https://web.archive.org/web/20070928121055/http://www.bcnc.org.uk/equivalence.html \| url-status = dead }}</ref> The half-life of chlordiazepoxide increases significantly in the elderly, which may result in prolonged action as well as accumulation of the drug during repeated administration. Delayed body clearance of the long half-life active metabolite also occurs in those over 60 years of age, which further prolongs the effects of the drugs with additional accumulation after repeated dosing.<ref>{{cite journal \| vauthors = Vozeh S \| title = \| journal = Schweizerische Medizinische Wochenschrift \| volume = 111 \| issue = 47 \| pages = 1789–93 \| date = November 1981 \| pmid = 6118950 }}</ref>

			Despite its name, chlordiazepoxide is not an ].

			==History==
			Chlordiazepoxide (initially called ''methaminodiazepoxide'') was the first benzodiazepine to be synthesized in the mid-1950s. The synthesis was derived from work on a class of dyes, quinazoline-3-oxides.<ref>{{cite journal \| vauthors = Sternbach LH \| title = The discovery of librium \| journal = Agents and Actions \| volume = 2 \| issue = 4 \| pages = 193–6 \| date = June 1972 \| pmid = 4557348 \| doi = 10.1007/BF01965860 \| s2cid = 26923026 }}</ref> It was discovered by accident when in 1957 tests revealed that the compound had ], ], and ] effects. "The story of the chemical development of Librium and Valium was told by ]. The serendipity involved in the invention of this class of compounds was matched by the trials and errors of the pharmacologists in the discovery of the tranquilizing activity of the benzodiazepines. The discovery of Librium in 1957 was due largely to the dedicated work and observational ability of a gifted technician, Beryl Kappell. For some seven years she had been screening compounds by simple animal tests for muscle relaxant activity using ] as a standard and then ] and ] when they became available. All compounds submitted by the chemical staff for central nervous activity were screened. It was this battery of tests that picked out RO 5-0690 (Librium, chlordiazepoxide) as being similar but more potent than meprobamate."<ref>{{cite web \|url=http://garfield.library.upenn.edu/classics1980/A1980KP91000001.pdf \|title=Pharmacological and clinical-studies on valium: a new psychotherapeutic agent of the benzodiazepine class \|date=1980-11-24 \|access-date=2019-05-23 }}</ref> Three years later chlordiazepoxide was marketed as a therapeutic benzodiazepine medication under the brand name Librium. Following chlordiazepoxide, in 1963 ] hit the market under the brand name Valium—and was followed by many further benzodiazepine compounds over the subsequent years and decades.<ref>{{cite book\|url=http://www.etfrc.com/benzos1.htm\|title=The Complete Story of the Benzodiazepines \| vauthors = Cooper JR, Bloom FE, Roth RH \|date=January 15, 1996\|publisher=Oxford University Press\|isbn=0-19-510399-8\|edition=seventh\|location=USA\|access-date=7 Apr 2008 \|url-status=dead \|archive-url=https://web.archive.org/web/20080315230230/http://www.etfrc.com/benzos1.htm \|archive-date=2008-03-15 }}</ref>

			In 1959 it was used by over 2,000 physicians and more than 20,000 patients. It was described as "chemically and clinically different from any of the tranquilizers, psychic energizers or other psychotherapeutic drugs now available." During studies, chlordiazepoxide induced muscle relaxation and a quieting effect on laboratory animals like mice, ]s, ]s, and ]s. Fear and aggression were eliminated in much smaller doses than those necessary to produce hypnosis. Chlordiazepoxide is similar to ] in its ] properties. However, it lacks the hypnotic effects of ]. Animal tests were conducted in the ] and the ]. Forty-two hospital patients admitted for acute and chronic alcoholism, and various ] and ] were treated with chlordiazepoxide. In a majority of the patients, ], ], and motor excitement were "effectively reduced." The most positive results were observed among ] patients. It was reported that ]s and ] problems, both of which involved emotional factors, were reduced by chlordiazepoxide.<ref>{{cite news \| author=The New York Times \| title = Help For Mental Ills (Reports on Tests of Synthetic Drug Say The Results are Positive) \| work=]\| location = USA \| page = E9 \| date = 28 February 1960 }}</ref>

			In 1963, approval for use was given to ] (Valium), a "simplified" version of chlordiazepoxide, primarily to counteract anxiety symptoms. Sleep-related problems were treated with ] (Mogadon), which was introduced in 1972, ] (Restoril), which was introduced in 1979, and ] (Dalmane), which was introduced in 1975.<ref>{{cite journal \| vauthors = Sternbach LH \| title = The discovery of librium \| journal = Agents and Actions \| volume = 2 \| issue = 4 \| pages = 193–6 \| date = June 1972 \| pmid = 4557348 \| doi = 10.1007/BF01965860 \| s2cid = 26923026 }}</ref>

			==Recreational use==
			{{See also\|Benzodiazepine drug misuse}}
			In 1963, Carl F. Essig of the ] of the ] stated that ], ], ], ], ] and chlordiazepoxide were drugs whose usefulness “can hardly be questioned.” However, Essig labeled these “newer products” as “drugs of addiction,” like ], whose habit-forming qualities were more widely known. He mentioned a 90-day study of chlordiazepoxide, which concluded that the automobile accident rate among 68 users was 10 times higher than normal. Participants' daily dosage ranged from 5 to 100 milligrams.<ref>{{cite news \| author =The New York Times \| title = Warning Is Issued On Tranquilizers \| work=The New York Times\| location = USA \| page = 23 \| date = 30 December 1963 }}</ref>

			Chlordiazepoxide is a drug of potential ] and is frequently detected in urine samples of drug users who have not been prescribed the drug.<ref>{{cite journal \| vauthors = Garretty DJ, Wolff K, Hay AW, Raistrick D \| title = Benzodiazepine misuse by drug addicts \| journal = Annals of Clinical Biochemistry \| volume = 34 \| issue = Pt 1 \| pages = 68–73 \| date = January 1997 \| pmid = 9022890 \| doi = 10.1177/000456329703400110 \| s2cid = 42665843 \| doi-access = free }}</ref>

			===Legal status===
			Internationally, chlordiazepoxide is a ] controlled drug under the ].<ref>{{Cite book\|title=Psychotropic Substances \|publisher=United Nations International Narcotics Control Board\|year=2016\|isbn=978-92-1-048165-6\|location=New York\|pages=27}}</ref>

	==Toxicity==		==Toxicity==
			===Animal===
	Laboratory tests assessing the toxicity of chlordiazepoxide, ] and ] on mice ] found that chlordiazepoxide produced toxicities in sperm including abnormalities involving both the shape and size of the sperm head. Nitrazepam however caused more profound abnormalities than chlordiazepoxide.<ref>{{cite journal \| author = Kar RN \| coauthors = Das RK. \| year = 1983 \| month = \| title = Induction of sperm head abnormalities in mice by three tranquilizers. \| journal = Cytobios. \| volume = 36 \| issue = 141 \| pages = 45-51 \| pmid = 6132780 }}</ref>
			Laboratory tests assessing the toxicity of chlordiazepoxide, ] and ] on mice ] found that chlordiazepoxide produced toxicities in sperm including abnormalities involving both the shape and size of the sperm head. Nitrazepam, however, caused more profound abnormalities than chlordiazepoxide.<ref>{{cite journal \| vauthors = Kar RN, Das RK \| title = Induction of sperm head abnormalities in mice by three tranquilizers \| journal = Cytobios \| volume = 36 \| issue = 141 \| pages = 45–51 \| year = 1983 \| pmid = 6132780 }}</ref>

	==~~Trade names~~==		==Availability==
			Chlordiazepoxide is available in various dosage forms, alone or in combination with other drugs, worldwide. In combination with ] as NORMAXIN-CC and in combination with dicyclomine as NORMAXIN for IBS, and with the anti-depressant ] as Limbitrol.<ref>Drugs.com Page accessed April 24, 2015
	* Alpoxid
			</ref>
	* Klopoxid
	* Librium
	* Librocol
	* Librelease
	* Libritabs
	* Limbitrol
	* Menrium
	* Novo-Poxide
	* Poxidium
	* Risolid
	* Defobin
	* Elenium

	==~~Combination~~ ~~Drugs~~==		==See also==
			* ]
	* Librax - chlordiazepoxide and ]
			* ]
			* ]
			* ]
			* ]

			==References==
			{{reflist\|32em}}

	==External links==		==External links==
	*		*
	*		*
			*

	==References==
	{{reflist\|2}}

	{{Benzodiazepines}}		{{Benzodiazepines}}
	{{Anxiolytics}}		{{Anxiolytics}}
			{{GABAAR PAMs}}

			]
	]		]
	]		]
			]

	]
	]
	]
	]
	]
	]
	]
	]
	]

Latest revision as of 23:10, 30 December 2024

Benzodiazepine medication

Pharmaceutical compound

Chlordiazepoxide
Clinical data


Pronunciation	/ˌklɔːrdaɪ.əzɪˈpɒksaɪd/
Trade names	Librium, others
AHFS/Drugs.com	Monograph
MedlinePlus	a682078
Dependence liability	High
Addiction liability	Moderate
Routes of administration	By mouth, intramuscular
Drug class	Benzodiazepine
ATC code	N05BA02 (WHO)
Legal status
Legal status	AU: S4 (Prescription only) BR: Class B1 (Psychoactive drugs) CA: Schedule IV DE: Prescription only (Anlage III for higher doses) UK: Class C US: Schedule IV
Pharmacokinetic data
Metabolism	Liver
Metabolites	• Desmethylchlordiazepoxide • Demoxepam • Nordazepam • Oxazepam
Elimination half-life	5–30 hours (Active metabolite desmethyldiazepam 36–200 hours: other active metabolites include oxazepam)
Excretion	Kidney
Identifiers
IUPAC name 7-Chloro-2-methylamino-5-phenyl-3H-1,4-benzodiazepine-4-oxide
CAS Number	58-25-3
PubChem CID	2712
IUPHAR/BPS	3370
DrugBank	DB00475
ChemSpider	10248513
UNII	6RZ6XEZ3CR
KEGG	D00267
ChEBI	CHEBI:3611
ChEMBL	ChEMBL451
CompTox Dashboard (EPA)	DTXSID4046022
ECHA InfoCard	100.000.337
Chemical and physical data
Formula	C₁₆H₁₄ClN₃O
Molar mass	299.76 g·mol
3D model (JSmol)	Interactive image
SMILES ClC1=CC2=C(N=C(NC)C()=C2C3=CC=CC=C3)C=C1
InChI InChI=1S/C16H14ClN3O/c1-18-15-10-20(21)16(11-5-3-2-4-6-11)13-9-12(17)7-8-14(13)19-15/h2-9H,10H2,1H3,(H,18,19) Key:ANTSCNMPPGJYLG-UHFFFAOYSA-N
(verify)

Chlordiazepoxide, sold under the brand name Librium among others, is a sedative and hypnotic medication of the benzodiazepine class. It is used to treat anxiety, insomnia and symptoms of withdrawal from alcohol, benzodiazepines, and other drugs.

Chlordiazepoxide has a medium to long half-life, while its active metabolite has a very long half-life. The drug has amnesic, anticonvulsant, anxiolytic, hypnotic, sedative, and skeletal muscle relaxant properties.

Chlordiazepoxide was patented in 1958 and approved for medical use in 1960. It was the first benzodiazepine to be synthesized and the discovery of chlordiazepoxide was by pure chance. Chlordiazepoxide and other benzodiazepines were initially accepted with widespread public approval, but were followed with widespread public disapproval and recommendations for more restrictive medical guidelines for its use.

Medical uses

Chlordiazepoxide is indicated for the short-term (2–4 weeks) treatment of anxiety that is severe and disabling or subjecting the person to unacceptable distress. It is also indicated as a treatment for the management of acute alcohol withdrawal syndrome.

It can sometimes be prescribed to ease symptoms of irritable bowel syndrome (IBS) combined with clidinium bromide as a fixed dose medication, Librax.

Contraindications

Use of chlordiazepoxide should be avoided in individuals with the following conditions:

Myasthenia gravis
Acute intoxication with alcohol, narcotics, or other psychoactive substances
Ataxia
Severe hypoventilation
Acute narrow-angle glaucoma
Severe liver deficiencies (hepatitis and liver cirrhosis decrease elimination by a factor of 2)
Severe sleep apnea
Hypersensitivity or allergy to any drug in the benzodiazepine class

Chlordiazepoxide is generally considered an inappropriate benzodiazepine for the elderly due to its long elimination half-life and the risks of accumulation. Benzodiazepines require special precaution if used in the elderly, pregnancy, children, alcohol- or drug-dependent individuals and individuals with comorbid psychiatric disorders.

Pregnancy

The research into the safety of benzodiazepines during pregnancy is limited and it is recommended that use of benzodiazepines during pregnancy should be based on whether the benefits outweigh the risks. If chlordiazepoxide is used during pregnancy the risks can be reduced via using the lowest effective dose and for the shortest time possible. Benzodiazepines should generally be avoided during the first trimester of pregnancy. Chlordiazepoxide and diazepam are considered to be among the safer benzodiazepines to use during pregnancy in comparison to other benzodiazepines. Possible adverse effects from benzodiazepine use during pregnancy include, miscarriage, malformation, intrauterine growth retardation, functional deficits, carcinogenesis and mutagenesis. Caution is also advised during breast feeding as chlordiazepoxide passes into breast milk.

Adverse effects

Sedative drugs and sleeping pills, including chlordiazepoxide, have been associated with an increased risk of death. The studies had many limitations, such as possible tendency to overestimate risk, possible confounding by indication with other risk factors and confusing hypnotics with drugs having other indications.

Common side-effects of chlordiazepoxide include:

Confusion
Constipation
Drowsiness
Fainting
Altered sex drive
Liver problems
Lack of muscle coordination
Minor menstrual irregularities
Nausea
Skin rash or eruptions
Swelling due to fluid retention
Yellow eyes and skin

Chlordiazepoxide in laboratory mice studies impairs latent learning. Benzodiazepines impair learning and memory via their action on benzodiazepine receptors, which causes a dysfunction in the cholinergic neuronal system in mice. It was later found that impairment in learning was caused by an increase in benzodiazepine/GABA activity (and that benzodiazepines were not associated with the cholinergic system). In tests of various benzodiazepine compounds, chlordiazepoxide was found to cause the most profound reduction in the turnover of 5HT (serotonin) in rats. Serotonin is closely involved in regulating mood and may be one of the causes of feelings of depression in rats using chlordiazepoxide or other benzodiazepines.

In September 2020, the US Food and Drug Administration (FDA) required the boxed warning for all benzodiazepine medicines to be updated to describe the risks of abuse, misuse, addiction, physical dependence, and withdrawal reactions consistently across all the medicines in the class.

Tolerance and dependence

Tolerance

Chronic use of benzodiazepines, such as chlordiazepoxide, leads to the development of tolerance, with a decrease in number of benzodiazepine binding sites in mice forebrains. The Committee of Review of Medicines, who carried out an extensive review of benzodiazepines including chlordiazepoxide, found—and were in agreement with the US Institute of Medicine and the conclusions of a study carried out by the White House Office of Drug Policy and the US National Institute on Drug Abuse—that there was little evidence that long-term use of benzodiazepines was beneficial in the treatment of insomnia due to the development of tolerance. Benzodiazepines tended to lose their sleep-promoting properties within 3 to 14 days of continuous use, and in the treatment of anxiety the committee found that there was little convincing evidence that benzodiazepines retained efficacy in the treatment of anxiety after four months' continuous use due to the development of tolerance.

Dependence

Chlordiazepoxide can cause physical dependence and what is known as the benzodiazepine withdrawal syndrome. Withdrawal from chlordiazepoxide or other benzodiazepines often leads to withdrawal symptoms that are similar to those seen with alcohol and barbiturates. The higher the dose and the longer the drug is taken, the greater the risk of experiencing unpleasant withdrawal symptoms. Withdrawal symptoms can, however, occur at standard dosages and also after short-term use. Benzodiazepine treatment should be discontinued as soon as possible through a slow and gradual dose-reduction regime.

Chlordiazepoxide taken during pregnancy can cause a postnatal benzodiazepine withdrawal syndrome.

Overdose

Pharmacology

Chlordiazepoxide acts on benzodiazepine allosteric sites that are part of the GABA_A receptor/ion-channel complex and this results in an increased binding of the inhibitory neurotransmitter GABA to the GABA_A receptor thereby producing inhibitory effects on the central nervous system and body similar to the effects of other benzodiazepines. Chlordiazepoxide is an anticonvulsant.

Chlordiazepoxide is preferentially stored in some organs including the hearts of neonates. Absorption by any administered route and the risk of accumulation is significantly higher in neonates. The withdrawal of chlordiazepoxide during pregnancy and breast feeding is recommended, as chlordiazepoxide rapidly crosses the placenta and also is excreted in breast milk. Chlordiazepoxide also decreases prolactin release in rats. Benzodiazepines act via micromolar benzodiazepine binding sites as Ca2+ channel blockers and significantly inhibit depolarization-sensitive Calcium uptake in animal nerve terminal preparations. Chlordiazepoxide inhibits acetylcholine release in mouse hippocampal synaptosomes in vivo. This has been found by measuring sodium-dependent high affinity choline uptake in vitro after pretreatment of the mice in vivo with chlordiazepoxide. This may play a role in chlordiazepoxide's anticonvulsant properties.

Pharmacokinetics

Chlordiazepoxide is a long-acting benzodiazepine drug. The half-life of chlordiazepoxide is from 5 to 30 hours but has an active benzodiazepine metabolite, nordiazepam, which has a half-life of 36 to 200 hours. The half-life of chlordiazepoxide increases significantly in the elderly, which may result in prolonged action as well as accumulation of the drug during repeated administration. Delayed body clearance of the long half-life active metabolite also occurs in those over 60 years of age, which further prolongs the effects of the drugs with additional accumulation after repeated dosing.

Despite its name, chlordiazepoxide is not an epoxide.

History

Chlordiazepoxide (initially called methaminodiazepoxide) was the first benzodiazepine to be synthesized in the mid-1950s. The synthesis was derived from work on a class of dyes, quinazoline-3-oxides. It was discovered by accident when in 1957 tests revealed that the compound had hypnotic, anxiolytic, and muscle relaxant effects. "The story of the chemical development of Librium and Valium was told by Sternbach. The serendipity involved in the invention of this class of compounds was matched by the trials and errors of the pharmacologists in the discovery of the tranquilizing activity of the benzodiazepines. The discovery of Librium in 1957 was due largely to the dedicated work and observational ability of a gifted technician, Beryl Kappell. For some seven years she had been screening compounds by simple animal tests for muscle relaxant activity using myanesin as a standard and then meprobamate and chlorpromazine when they became available. All compounds submitted by the chemical staff for central nervous activity were screened. It was this battery of tests that picked out RO 5-0690 (Librium, chlordiazepoxide) as being similar but more potent than meprobamate." Three years later chlordiazepoxide was marketed as a therapeutic benzodiazepine medication under the brand name Librium. Following chlordiazepoxide, in 1963 diazepam hit the market under the brand name Valium—and was followed by many further benzodiazepine compounds over the subsequent years and decades.

In 1959 it was used by over 2,000 physicians and more than 20,000 patients. It was described as "chemically and clinically different from any of the tranquilizers, psychic energizers or other psychotherapeutic drugs now available." During studies, chlordiazepoxide induced muscle relaxation and a quieting effect on laboratory animals like mice, rats, cats, and dogs. Fear and aggression were eliminated in much smaller doses than those necessary to produce hypnosis. Chlordiazepoxide is similar to phenobarbital in its anticonvulsant properties. However, it lacks the hypnotic effects of barbiturates. Animal tests were conducted in the Boston Zoo and the San Diego Zoo. Forty-two hospital patients admitted for acute and chronic alcoholism, and various psychoses and neuroses were treated with chlordiazepoxide. In a majority of the patients, anxiety, tension, and motor excitement were "effectively reduced." The most positive results were observed among alcoholic patients. It was reported that ulcers and dermatologic problems, both of which involved emotional factors, were reduced by chlordiazepoxide.

In 1963, approval for use was given to diazepam (Valium), a "simplified" version of chlordiazepoxide, primarily to counteract anxiety symptoms. Sleep-related problems were treated with nitrazepam (Mogadon), which was introduced in 1972, temazepam (Restoril), which was introduced in 1979, and flurazepam (Dalmane), which was introduced in 1975.

Recreational use

Legal status

Internationally, chlordiazepoxide is a Schedule IV controlled drug under the Convention on Psychotropic Substances.

Toxicity

Animal

Laboratory tests assessing the toxicity of chlordiazepoxide, nitrazepam and diazepam on mice spermatozoa found that chlordiazepoxide produced toxicities in sperm including abnormalities involving both the shape and size of the sperm head. Nitrazepam, however, caused more profound abnormalities than chlordiazepoxide.

Availability

Chlordiazepoxide is available in various dosage forms, alone or in combination with other drugs, worldwide. In combination with Clidinium as NORMAXIN-CC and in combination with dicyclomine as NORMAXIN for IBS, and with the anti-depressant amitriptyline as Limbitrol.

References

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Drugs.com Drugs.com: International availability of chlordiazepoxide Page accessed April 24, 2015

External links

v t e Benzodiazepines
1,4-Benzodiazepines	2-Oxoquazepam 3-Hydroxyphenazepam Bromazepam BMS-906024* Camazepam Carburazepam Chlordiazepoxide Cinazepam Cinolazepam Clonazepam Cloniprazepam Clorazepate Cyprazepam Delorazepam Demoxepam Desmethylflunitrazepam Devazepide* Diazepam Diclazepam Difludiazepam Doxefazepam Elfazepam Ethyl carfluzepate Ethyl dirazepate Ethyl loflazepate Flubromazepam Fletazepam Fludiazepam Flunitrazepam Flurazepam Flutemazepam Flutoprazepam Fosazepam Gidazepam Halazepam Iclazepam Irazepine* Kenazepine Ketazolam Lorazepam Lormetazepam Lufuradom* Meclonazepam Medazepam Menitrazepam Metaclazepam Motrazepam N-Desalkylflurazepam Nifoxipam Nimetazepam Nitemazepam Nitrazepam Nitrazepate Nordazepam Nortetrazepam Oxazepam Phenazepam Pinazepam Pivoxazepam Prazepam Proflazepam Quazepam QH-II-66 Reclazepam RO4491533* Ro05-4082 Ro5-4864* Ro07-5220 Ro07-9749 Ro20-8065 Ro20-8552 SH-I-048A Sulazepam Temazepam Tetrazepam Tifluadom* Timelotem* Tolufazepam Triflunordazepam Tuclazepam Uldazepam
1,5-Benzodiazepines	Arfendazam Clobazam CP-1414S Lofendazam Triflubazam
2,3-Benzodiazepines*	Girisopam GYKI-52466 GYKI-52895 Nerisopam Talampanel Tofisopam
Triazolobenzodiazepines	Adinazolam Alprazolam Balovaptan* Bromazolam Clonazolam Estazolam Fluadinazolam Flualprazolam Flubromazolam Flunitrazolam Nitrazolam Phenazolam Pyrazolam Rilmazolam (active metabolite of Rilmazafone) Triazolam
Imidazobenzodiazepines	Bretazenil Climazolam EVT-201 FG-8205 Flumazenil GL-II-73 Imidazenil I-Iomazenil L-655,708 Loprazolam Midazolam PWZ-029 Remimazolam Ro15-4513 Ro48-6791 Ro48-8684 Ro4938581 Sarmazenil SH-053-R-CH3-2′F
Oxazolobenzodiazepines	Cloxazolam Flutazolam Haloxazolam Mexazolam Oxazolam
Thienodiazepines	Bentazepam Clotiazepam Ro09-9212
Thienotriazolodiazepines	α-Hydroxyetizolam Apafant* Brotizolam Ciclotizolam Clotizolam Deschloroclotizolam Deschloroetizolam Etizolam Flubrotizolam Fluclotizolam Fluetizolam Israpafant* JQ1* Metizolam
Thienobenzodiazepines*	Olanzapine Telenzepine
Pyridodiazepines	Lopirazepam
Pyridotriazolodiazepines	Zapizolam
Pyrazolodiazepines	Razobazam* Ripazepam Zolazepam Zomebazam Zometapine*
Pyrrolodiazepines	Premazepam
Tetrahydroisoquinobenzodiazepines	Clazolam
Pyrrolobenzodiazepines*	Anthramycin
Benzodiazepine prodrugs	Alprazolam triazolobenzophenone Avizafone Rilmazafone
* atypical activity profile (not GABA_A receptor ligands)

v t e Anxiolytics (N05B)
5-HT_1ARTooltip 5-HT1A receptor agonists	Buspirone Gepirone Tandospirone
GABA_ARTooltip GABAA receptor PAMsTooltip positive allosteric modulators	Benzodiazepines: Adinazolam Alprazolam Bromazepam Camazepam Chlordiazepoxide Clobazam Clonazepam Clorazepate Clotiazepam Cloxazolam Diazepam Ethyl loflazepate Etizolam Fludiazepam Halazepam Ketazolam Lorazepam Medazepam Nordazepam Oxazepam Pinazepam Prazepam; Others: Alpidem Barbiturates (e.g., phenobarbital) Carbamates (e.g., meprobamate) Carisoprodol Chlormezanone Ethanol (alcohol) Etifoxine
Hypnotics	Zopiclone
Gabapentinoids (α₂δ VDCC blockers)	Gabapentin Gabapentin enacarbil Phenibut Pregabalin
Antidepressants	SSRIsTooltip Selective serotonin reuptake inhibitors (e.g., escitalopram) SNRIsTooltip Serotonin-norepinephrine reuptake inhibitors (e.g., duloxetine) SARIsTooltip Serotonin antagonist and reuptake inhibitors (e.g., trazodone) TCAsTooltip Tricyclic antidepressants (e.g., clomipramine) TeCAsTooltip Tetracyclic antidepressants (e.g., mirtazapine) MAOIsTooltip Monoamine oxidase inhibitors (e.g., phenelzine); Others: Agomelatine Bupropion Tianeptine Vilazodone Vortioxetine
Antipsychotics	Quetiapine Flupentixol
Sympatholytics (Antiadrenergics)	Alpha-1 blockers (e.g., prazosin) Alpha-2 agonists (e.g., clonidine, dexmedetomidine, guanfacine) Beta blockers (e.g., propranolol)
Others	Benzoctamine Cycloserine Fabomotizole Hydroxyzine Lorpiprazole Mebicar Mepiprazole Nicotine Opipramol Oxaflozane Phenaglycodol Phenibut Picamilon Selank Tiagabine Tofisopam Validolum
WHO-EM Withdrawn from market Clinical trials: Phase III Never to phase III

v t e GABA_A receptor positive modulators
Alcohols	Brometone Butanol Chloralodol Chlorobutanol (cloretone) Ethanol (alcohol) (alcoholic drink) Ethchlorvynol Isobutanol Isopropanol Menthol Methanol Methylpentynol Pentanol Petrichloral Propanol tert-Butanol (2M2P) tert-Pentanol (2M2B) Tribromoethanol Trichloroethanol Triclofos Trifluoroethanol
Barbiturates	(-)-DMBB Allobarbital Alphenal Amobarbital Aprobarbital Barbexaclone Barbital Benzobarbital Benzylbutylbarbiturate Brallobarbital Brophebarbital Butabarbital/Secbutabarbital Butalbital Buthalital Butobarbital Butallylonal Carbubarb Crotylbarbital Cyclobarbital Cyclopentobarbital Difebarbamate Enallylpropymal Ethallobarbital Eterobarb Febarbamate Heptabarb Heptobarbital Hexethal Hexobarbital Metharbital Methitural Methohexital Methylphenobarbital Narcobarbital Nealbarbital Pentobarbital Phenallymal Phenobarbital Phetharbital Primidone Probarbital Propallylonal Propylbarbital Proxibarbital Reposal Secobarbital Sigmodal Spirobarbital Talbutal Tetrabamate Tetrabarbital Thialbarbital Thiamylal Thiobarbital Thiobutabarbital Thiopental Thiotetrabarbital Valofane Vinbarbital Vinylbital
Benzodiazepines	2-Oxoquazepam 3-Hydroxyphenazepam Adinazolam Alprazolam Arfendazam Avizafone Bentazepam Bretazenil Bromazepam Bromazolam Brotizolam Camazepam Carburazepam Chlordiazepoxide Ciclotizolam Cinazepam Cinolazepam Clazolam Climazolam Clobazam Clonazepam Clonazolam Cloniprazepam Clorazepate Clotiazepam Cloxazolam CP-1414S Cyprazepam Delorazepam Demoxepam Diazepam Diclazepam Dimdazenil Doxefazepam Elfazepam Estazolam Ethyl carfluzepate Ethyl dirazepate Ethyl loflazepate Etizolam FG-8205 Fletazepam Flubromazepam Flubromazolam Fludiazepam Flunitrazepam Flunitrazolam Flurazepam Flutazolam Flutemazepam Flutoprazepam Fosazepam Gidazepam Halazepam Haloxazolam Iclazepam Imidazenil Irazepine Ketazolam Lofendazam Lopirazepam Loprazolam Lorazepam Lormetazepam Meclonazepam Medazepam Menitrazepam Metaclazepam Mexazolam Midazolam Motrazepam N-Desalkylflurazepam Nifoxipam Nimetazepam Nitrazepam Nitrazepate Nitrazolam Nordazepam Nortetrazepam Oxazepam Oxazolam Phenazepam Pinazepam Pivoxazepam Prazepam Premazepam Proflazepam Pyrazolam QH-II-66 Quazepam Reclazepam Remimazolam Rilmazafone Ripazepam Ro48-6791 Ro48-8684 SH-053-R-CH3-2′F Sulazepam Temazepam Tetrazepam Tolufazepam Triazolam Triflubazam Triflunordazepam (Ro5-2904) Tuclazepam Uldazepam Zapizolam Zolazepam Zomebazam
Carbamates	Carisbamate Carisoprodol Clocental Cyclarbamate Difebarbamate Emylcamate Ethinamate Febarbamate Felbamate Hexapropymate Hydroxyphenamate Lorbamate Mebutamate Meprobamate Nisobamate Pentabamate Phenprobamate Procymate Styramate Tetrabamate Tybamate
Flavonoids	6-Methylapigenin Ampelopsin (dihydromyricetin) Apigenin Baicalein Baicalin Catechin EGC EGCG Hispidulin Linarin Luteolin Rc-OMe Skullcap constituents (e.g., baicalin) Wogonin
Imidazoles	Etomidate Metomidate Propoxate
Kava constituents	10-Methoxyyangonin 11-Methoxyyangonin 11-Hydroxyyangonin Desmethoxyyangonin 11-Methoxy-12-hydroxydehydrokavain 7,8-Dihydroyangonin Kavain 5-Hydroxykavain 5,6-Dihydroyangonin 7,8-Dihydrokavain 5,6,7,8-Tetrahydroyangonin 5,6-Dehydromethysticin Methysticin 7,8-Dihydromethysticin Yangonin
Monoureides	Acecarbromal Apronal (apronalide) Bromisoval Carbromal Capuride Ectylurea
Neuroactive steroids	Acebrochol Allopregnanolone (brexanolone) Alfadolone Alfaxalone 3α-Androstanediol Androstenol Androsterone Certain anabolic-androgenic steroids Cholesterol DHDOC 3α-DHP 5α-DHP 5β-DHP DHT Etiocholanolone Ganaxolone Hydroxydione Minaxolone ORG-20599 ORG-21465 P1-185 Posovolone Pregnanolone (eltanolone) Progesterone Renanolone SAGE-105 SAGE-324 SAGE-516 SAGE-689 SAGE-872 Testosterone THDOC Zuranolone
Nonbenzodiazepines	Cyclopyrrolones: Eszopiclone Pagoclone Pazinaclone Suproclone Suriclone Zopiclone Imidazopyridines: Alpidem DS-1 Necopidem Saripidem Zolpidem Pyrazolopyrimidines: Divaplon Fasiplon Indiplon Lorediplon Ocinaplon Panadiplon Taniplon Zaleplon Others: Adipiplon CGS-8216 CGS-9896 CGS-13767 CGS-20625 CL-218,872 CP-615,003 CTP-354 ELB-139 GBLD-345 Imepitoin JM-1232 L-838,417 Lirequinil (Ro41-3696) NS-2664 NS-2710 NS-11394 Pipequaline ROD-188 RWJ-51204 SB-205,384 SX-3228 TGSC01AA TP-003 TPA-023 TP-13 U-89843A U-90042 Viqualine Y-23684
Phenols	Fospropofol Propofol Thymol
Piperidinediones	Glutethimide Methyprylon Piperidione Pyrithyldione
Pyrazolopyridines	Cartazolate Etazolate ICI-190,622 Tracazolate
Quinazolinones	Afloqualone Cloroqualone Diproqualone Etaqualone Mebroqualone Mecloqualone Methaqualone Methylmethaqualone Nitromethaqualone SL-164
Volatiles/gases	Acetone Acetophenone Acetylglycinamide chloral hydrate Aliflurane Benzene Butane Butylene Centalun Chloral Chloral betaine Chloral hydrate Chloroform Cryofluorane Desflurane Dichloralphenazone Dichloromethane Diethyl ether Enflurane Ethyl chloride Ethylene Fluroxene Gasoline Halopropane Halothane Isoflurane Kerosine Methoxyflurane Methoxypropane Nitric oxide Nitrogen Nitrous oxide Norflurane Paraldehyde Propane Propylene Roflurane Sevoflurane Synthane Teflurane Toluene Trichloroethane (methyl chloroform) Trichloroethylene Vinyl ether
Others/unsorted	3-Hydroxybutanal α-EMTBL AA-29504 Alogabat Avermectins (e.g., ivermectin) Bromide compounds (e.g., lithium bromide, potassium bromide, sodium bromide) Carbamazepine Chloralose Chlormezanone Clomethiazole Darigabat DEABL Deuterated etifoxine Dihydroergolines (e.g., dihydroergocryptine, dihydroergosine, dihydroergotamine, ergoloid (dihydroergotoxine)) DS2 Efavirenz Etazepine Etifoxine Fenamates (e.g., flufenamic acid, mefenamic acid, niflumic acid, tolfenamic acid) Fluoxetine Flupirtine Hopantenic acid KRM-II-81 Lanthanum Lavender oil Lignans (e.g., 4-O-methylhonokiol, honokiol, magnolol, obovatol) Loreclezole Menthyl isovalerate (validolum) Monastrol Nicotinic acid Nicotinamide Org 25,435 Phenytoin Propanidid Retigabine (ezogabine) Safranal Seproxetine Stiripentol Sulfonylalkanes (e.g., sulfonmethane (sulfonal), tetronal, trional) Terpenoids (e.g., borneol) Topiramate Valerian constituents (e.g., isovaleric acid, isovaleramide, valerenic acid, valerenol) Unsorted benzodiazepine site positive modulators: α-Pinene MRK-409 (MK-0343) TCS-1105 TCS-1205
See also: Receptor/signaling modulators • GABA receptor modulators • GABA metabolism/transport modulators

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