Home
Random
Nearby

Log in

Settings

Donate Now If Wikipedia is useful to you, please give today.

About Wikipedia
Disclaimers

Cocaine: Difference between revisions

Article
Talk

Language
Watch
View history
View source

Browse history interactively

← Previous edit

Content deleted Content added

Revision as of 21:09, 12 March 2007 view source 163.248.200.144 (talk) →Consumption ← Previous edit		Latest revision as of 00:42, 1 September 2025 view source Slothwizard (talk \| contribs) Extended confirmed users 3,149 edits Wikilinked Schedule II drug Tags: Visual edit Mobile edit Mobile web edit
Line 1: {{Short description\|Tropane alkaloid and stimulant drug}} ~~{{Otheruses}}~~ {{About\|the purified salt form of cocaine\|the vaporized freebase\|Crack cocaine\|the crude coca leaf extract\|Cocaine paste\|the disguised smuggled form\|Black cocaine}} {{Distinguish\|text="Pink cocaine", which typically does not contain cocaine; see [[Tusi (drug)]]}} ~~{{drugbox~~ {{Other uses}} ~~\| IUPAC_name = methyl (1''R'',2''R'',3''S'',5''S'')-3- (benzoyloxy)-8-methyl-8-azabicyclo[3.2.1] octane-2-carboxylate~~ {{Pp-semi-indef}} ~~\| image = Cocaine-2D-skeletal.svg~~ {{pp-move}} ~~\| image2 = Cocaine-3D-balls.png~~ {{Use dmy dates\|date=May 2025}} ~~\| CAS_number = 50-36-2~~ {{cs1 config\|name-list-style=vanc\|display-authors=6}} {{Use American English\|date=December 2017}} {{Infobox drug \| Verifiedfields = changed \| Watchedfields = changed \| verifiedrevid = 477165921 \| image = Kokain - Cocaine.svg \| image_class = skin-invert-image \| width = \| alt = \| caption = \| image2 = Cocaine-from-xtal-1983-3D-balls.png \| width2 = \| alt2 = <!-- Clinical data --> \| pronounce = kə(ʊ)ˈkeɪn \| tradename = Neurocaine,<ref>{{Cite book \|vauthors=Nordegren T \|title=The A-Z Encyclopedia of Alcohol and Drug Abuse \|date=2002 \|publisher=Universal-Publishers \|isbn=978-1-58112-404-0 \|page=461 \|url=https://books.google.com/books?id=4yaGePenGKgC&pg=PA461 \|access-date=3 September 2020 \|archive-date=8 July 2024 \|archive-url=https://web.archive.org/web/20240708191823/https://books.google.com/books?id=4yaGePenGKgC&pg=PA461#v=onepage&q&f=false \|url-status=live }}</ref> Goprelto,<ref name="Goprelto FDA label" /> Numbrino,<ref name="Numbrino FDA label" /> others \| Drugs.com = {{drugs.com\|CONS\|cocaine}} \| MedlinePlus = \| DailyMedID = Cocaine \| pregnancy_AU = <!-- A / B1 / B2 / B3 / C / D / X --> \| pregnancy_AU_comment = \| pregnancy_category = \| dependency_liability = [[Physical dependence\|Physical]]: Low [[Psychological dependence\|Psychological]]: High<ref name="Gho_2010">{{Cite book \| vauthors = Ghodse H \| title = Ghodse's Drugs and Addictive Behaviour: A Guide to Treatment\|date=2010\|publisher=Cambridge University Press\|isbn=978-1-139-48567-8\|page=91\|edition=4\|url=https://books.google.com/books?id=WYQ23OMjWbcC&pg=PA91\|url-status=live\|archive-url=https://web.archive.org/web/20170910234911/https://books.google.com/books?id=WYQ23OMjWbcC&pg=PA91\|archive-date=10 September 2017}}</ref> \| addiction_liability = High<ref>{{Cite book\|title=Introduction to Pharmacology\|edition=3 \|date=2007\|publisher=CRC Press\|___location=Abingdon\|isbn=978-1-4200-4742-4\|pages=222–223\|url=https://books.google.com/books?id=qfrLBQAAQBAJ&pg=PA222\|url-status=live\|archive-url=https://web.archive.org/web/20170910234921/https://books.google.com/books?id=qfrLBQAAQBAJ&pg=PA222\|archive-date=10 September 2017}}</ref> \| routes_of_administration = [[Topical]], [[Oral administration\|by mouth]], [[insufflation (medicine)\|insufflation]], [[intravenous]], [[smoking\|inhalation]] \| class = {{plainlist\| * [[Local anesthetic]]; * [[SNDRI]];<ref name="Sora_2001">{{cite journal \| vauthors = Sora I, Hall FS, Andrews AM, Itokawa M, Li XF, Wei HB, Wichems C, Lesch KP, Murphy DL, Uhl GR \| title = Molecular mechanisms of cocaine reward: combined dopamine and serotonin transporter knockouts eliminate cocaine place preference \| journal = Proceedings of the National Academy of Sciences of the United States of America \| volume = 98 \| issue = 9 \| pages = 5300–5305 \| date = April 2001 \| pmid = 11320258 \| pmc = 33204 \| doi = 10.1073/pnas.091039298 \| doi-access = free \| bibcode = 2001PNAS...98.5300S }}</ref><ref name="Azizi_2022">{{cite journal \| vauthors = Azizi SA \| title = Monoamines: Dopamine, Norepinephrine, and Serotonin, Beyond Modulation, "Switches" That Alter the State of Target Networks \| journal = The Neuroscientist \| volume = 28 \| issue = 2 \| pages = 121–143 \| date = April 2022 \| pmid = 33292070 \| doi = 10.1177/1073858420974336 \| s2cid = 228080727 }}</ref> * [[Stimulant]] }} \| ATC_prefix = N01 \| ATC_suffix = BC01 \| ATC_supplemental = {{ATC\|R02\|AD03}}, {{ATC\|S01\|HA01}}, {{ATC\|S02\|DA02}} ~~\| PubChem = 5760~~ <!-- Legal status -->\| legal_AU = Schedule 8 ~~\| DrugBank = APRD00080~~ \| legal_AU_comment = ~~\| C=17 \| H=21 \| N=1 \| O=4~~ \| legal_BR = F1<!-- OTC, A1, A2, A3, B1, B2, C1, C2, C3, C4, C5, D1, D2, E, F--> ~~\| molecular_weight = 303.353 g/mol~~ \| ~~melting_point~~legal_BR_comment = ~~195~~ ~~\| solubility = 1800~~ \| bioavailability = Oral: 30%<br/>Nasal: 30-60% <ref name="pagliaros">{{cite book \| first=Louis \| last=Pagliaro \| coauthors=Ann Marie Pagliaro \| title=Pagliaros’ Comprehensive Guide to Drugs and Substances of Abuse \| publisher=[[American Pharmacists Association]] \| ___location=Washington, D.C. \| year=2004 \| id=ISBN 1-58212-066-8 \| curly=true}}</ref> ~~\| protein_bound =~~ ~~\| metabolism = [[Hepatic]] [[CYP3A4]]~~ ~~\| elimination_half-life = 1 hour~~ ~~\| excretion = Renal (benzoylecgonine and ecgonine methyl ester)~~ ~~\| pregnancy_category = C~~ ~~\| legal_AU = Schedule 9~~ \| legal_CA = Schedule I \| legal_CA_comment = ~~\| legal_US = Schedule II~~ \| legal_DE = Anlage III \| legal_DE_comment = \| legal_NZ = Class A \| legal_NZ_comment = \| legal_UK = Class A \| legal_UK_comment = ~~\| legal_status =~~ \| legal_US = Schedule II ~~\| routes_of_administration = Topical, Oral, Insufflation, IV, PO~~ \| legal_US_comment = <ref name=DEA2017Sched>{{Cite web\|title=DEA / Drug Scheduling\|url=https://www.dea.gov/druginfo/ds.shtml\|website=www.dea.gov\|access-date=7 August 2017\|url-status=dead\|archive-url=https://web.archive.org/web/20170809044016/https://www.dea.gov/druginfo/ds.shtml\|archive-date=9 August 2017}}</ref> ~~\| dependency_liability = High~~ \| legal_UN = N I III \| legal_UN_comment = \| legal_status = <!-- For countries not listed above --> <!-- Pharmacokinetic data -->\| bioavailability = {{plainlist\| * [[Oral administration\|By mouth]]: 33%<ref name="Fattinger_2000">{{Cite journal \| vauthors = Fattinger K, Benowitz NL, Jones RT, Verotta D \| title = Nasal mucosal versus gastrointestinal absorption of nasally administered cocaine \| journal = European Journal of Clinical Pharmacology \| volume = 56 \| issue = 4 \| pages = 305–10 \| date = July 2000 \| pmid = 10954344 \| doi = 10.1007/s002280000147 \| s2cid = 20708443 }}</ref> * [[Insufflation (medicine)\|Insufflation]]: 60<ref>{{Cite journal \| vauthors = Barnett G, Hawks R, Resnick R \| title = Cocaine pharmacokinetics in humans \| journal = Journal of Ethnopharmacology \| volume = 3 \| issue = 2–3 \| pages = 353–66 \| year = 1981 \| pmid = 7242115 \| doi = 10.1016/0378-8741(81)90063-5 }}</ref>–80%<ref>{{Cite journal \| vauthors = Jeffcoat AR, Perez-Reyes M, Hill JM, Sadler BM, Cook CE \| title = Cocaine disposition in humans after intravenous injection, nasal insufflation (snorting), or smoking \| journal = Drug Metabolism and Disposition \| volume = 17 \| issue = 2 \| pages = 153–9 \| year = 1989 \| doi = 10.1016/S0090-9556(25)08737-9 \| pmid = 2565204 }}</ref> * [[Nasal spray]]: 25<ref name="Wilkinson_1980">{{Cite journal \| vauthors = Wilkinson P, Van Dyke C, Jatlow P, Barash P, Byck R \| title = Intranasal and oral cocaine kinetics \| journal = Clinical Pharmacology and Therapeutics \| volume = 27 \| issue = 3 \| pages = 386–94 \| date = March 1980 \| pmid = 7357795 \| doi = 10.1038/clpt.1980.52 \| s2cid = 29851205 }}</ref>–43%<ref name="Fattinger_2000" />}} \| protein_bound = \| metabolism = [[Liver]], [[CYP3A4]] \| metabolites = [[Norcocaine]], [[benzoylecgonine]], [[cocaethylene]] (when consumed with [[alcohol (drug)\|alcohol]]) \| onset = Seconds to minutes<ref name="Zimmerman_2012">{{Cite journal \| vauthors = Zimmerman JL \| title = Cocaine intoxication \| journal = Critical Care Clinics \| volume = 28 \| issue = 4 \| pages = 517–26 \| date = October 2012 \| pmid = 22998988 \| doi = 10.1016/j.ccc.2012.07.003 }}</ref> \| duration_of_action = 20 to 90 minutes<ref name="Zimmerman_2012" /> \| excretion = [[Kidney]] <!-- Identifiers -->\| index_label = \| index2_label = \| CAS_number_Ref = {{cascite\|correct\|CAS}} \| CAS_number = 50-36-2 \| CAS_supplemental = \| PubChem = 446220 \| IUPHAR_ligand = 2286 \| DrugBank_Ref = {{drugbankcite\|correct\|drugbank}} \| DrugBank = DB00907 \| ChemSpiderID_Ref = {{chemspidercite\|correct\|chemspider}} \| ChemSpiderID = 10194104 \| UNII_Ref = {{fdacite\|correct\|FDA}} \| UNII = I5Y540LHVR \| KEGG_Ref = {{keggcite\|correct\|kegg}} \| KEGG = D00110 \| ChEBI_Ref = {{ebicite\|correct\|EBI}} \| ChEBI = 27958 \| ChEMBL_Ref = {{ebicite\|correct\|EBI}} \| ChEMBL = 370805 \| NIAID_ChemDB = \| PDB_ligand = COC \| synonyms = Benzoylmethylecogine \| IUPAC_name = Methyl (1''R'',2''R'',3''S'',5''S'')-3-(benzoyloxy)-8-methyl-8-azabicyclo[3.2.1]octane-2-carboxylate \| C = 17 \| H = 21 \| N = 1 \| O = 4 \| SMILES = CN1[C@H]2CC[C@@H]1[C@@H](C(OC)=O)[C@@H](OC(C3=CC=CC=C3)=O)C2 \| StdInChI_Ref = {{stdinchicite\|correct\|chemspider}} \| StdInChI = 1S/C17H21NO4/c1-18-12-8-9-13(18)15(17(20)21-2)14(10-12)22-16(19)11-6-4-3-5-7-11/h3-7,12-15H,8-10H2,1-2H3/t12-,13+,14-,15+/m0/s1 \| StdInChI_comment = \| StdInChIKey_Ref = {{stdinchicite\|correct\|chemspider}} \| StdInChIKey = ZPUCINDJVBIVPJ-LJISPDSOSA-N \| density = \| density_notes = \| melting_point = 98<!--Pubchem--> \| melting_high = \| melting_notes = \| boiling_point = 187 \| boiling_notes = \| solubility = 1.8 \| sol_units = g/L (22 °C)<!--YALKOWSKY,SH & DANNENFELSER,RM (1992) via Pubchem--> \| specific_rotation = }} <!-- Definition and effects --> '''Cocaine''' (or '''crack''' in its impure [[freebase]] form) is a [[crystalline]] [[tropane]] [[alkaloid]] that is obtained from the leaves of the [[coca]] plant. It is a [[stimulant]] of the [[central nervous system]] and an [[appetite suppressant]], giving rise to what has been described as a euphoric sense of happiness and increased energy, and post production. It is most often used recreationally for this effect. Nonetheless, cocaine is formally used in medicine as a topical [[anesthesia\|anesthetic]], specifically in [[eye surgery\|eye]], nose and throat [[surgery]]. '''Cocaine''' is a central nervous system [[stimulant]] and [[tropane alkaloid]] derived primarily from the leaves of two [[coca]] species native to South America: ''[[Erythroxylum coca]]'' and ''[[Erythroxylum novogranatense\|E. novogranatense]]''.<ref name="EUDA">{{cite web \|title=Cocaine and crack drug profile {{!}} www.euda.europa.eu \|url=https://www.euda.europa.eu/publications/drug-profiles/cocaine_en \|website=www.euda.europa.eu}}</ref><ref>{{cite web \|title=Cocaine - Alcohol and Drug Foundation \|url=https://adf.org.au/drug-facts/cocaine/ \|website=adf.org.au \|language=en}}</ref><ref>{{Cite journal \| title=The identification of coca (Erythroxylum species) \| journal=Botanical Journal of the Linnean Society \| doi=10.1111/j.1095-8339.1982.tb00368.x}}</ref><ref name="Pom_2012">{{Cite journal \| vauthors = Pomara C, Cassano T, D'Errico S, Bello S, Romano AD, Riezzo I, Serviddio G \| title = Data available on the extent of cocaine use and dependence: biochemistry, pharmacologic effects and global burden of disease of cocaine abusers \| journal = Current Medicinal Chemistry \| volume = 19 \| issue = 33 \| pages = 5647–57 \| date = 2012 \| pmid = 22856655 \| doi = 10.2174/092986712803988811 }}</ref><ref name="Andean_full_report.pdf">{{cite web \| title = Coca Cultivation in the Andean Region \| publisher = UNODC \| date = June 2006 \|url=https://www.unodc.org/pdf/andean/Andean_full_report.pdf}}</ref> Coca leaves are processed into [[cocaine paste]], a crude mix of [[coca alkaloids]] which cocaine base is isolated and converted to cocaine hydrochloride, commonly known as "cocaine".<ref name="Andean_full_report.pdf" /> Cocaine was once a standard [[topical medication]] as a [[local anesthetic]] with intrinsic [[vasoconstriction\|vasoconstrictor]] activity, but its high abuse potential, adverse effects, and cost have limited its use and led to its replacement by other medicines.<ref name="Latorre_1999" /><ref name="Bremner_2019" /><ref name="Armbuster_2021">{{cite journal \| vauthors = Armbuster YC, Banas BN, Feickert KD, England SE, Moyer EJ, Christie EL, Chughtai S, Giuliani TJ, Halden RU, Graham JH, McCall KL, Piper BJ \| title = Decline and Pronounced Regional Disparities in Medical Cocaine Usage in the United States \| journal = The Journal of Pharmacy Technology \| volume = 37 \| issue = 6 \| pages = 278–285 \| date = December 2021 \| pmid = 34790964 \| pmc = 8592245 \| doi = 10.1177/87551225211035563 }}</ref> "Cocaine and its combinations" are formally excluded from the [[WHO Model List of Essential Medicines]].<ref name="WHO-MHP-HPS-EML-2023.02">{{cite web \|title=WHO Model List of Essential Medicines - 23rd list, 2023 \|url=https://www.who.int/publications/i/item/WHO-MHP-HPS-EML-2023.02 \|website=www.who.int \|language=en}}</ref> <!-- Pharmacokinetics/Pharmacodynamics --> There is controversy among treatment professionals over whether cocaine is psychologically or physically [[addiction\|addictive]] or both.<ref>For years treatment professionals told us cocaine was not physically addictive (some still do). Cocaine addicts were offered little support and frequently accused of being ‘weak willed' or of imagining withdrawal symptoms. Unlike heroin, alcohol or tranquillizers that have a dramatic withdrawal syndrome, inducing obvious physical symptoms, the physical addiction to cocaine takes place in the mostly in the brain. Physical withdrawal is not dangerous, and is in fact restorative. Over time with repeated use, your brain becomes addicted to cocaine. Cocaine attaches its self to the receptor sites in your brain where the pleasurable neurochemicals (dopamine especially) are stored, they then wash around in your system for a while making you feel high, before being excreted from your body and lost. The net result is that you are left with a shortage of dopamine, without enough dopamine you feel miserable and irritable and in extreme cases can experience [[anhedonia]], a near inability to experience pleasure from normally pleasurable activities and objects. [http://www.cocaine-addiction.co.uk/q&a.htm]</ref> Street cocaine is commonly [[Nasal administration\|snorted]], [[injection (medicine)\|injected]], or smoked as [[crack cocaine]], with effects lasting up to 90 minutes depending on the route.<ref name="Zimmerman_2012" /><ref name="smokablecocaine_eng_web-def.pdf">{{cite book \| vauthors = Cortés E, Metaal P \| title = Smokable cocaine markets in Latin America and the Caribbean \|url=https://www.tni.org/files/publication-downloads/tni-smokablecocaine_eng_web-def.pdf}}</ref> Cocaine acts pharmacologically as a [[serotonin–norepinephrine–dopamine reuptake inhibitor]] (SNDRI),<ref name="Azizi_2022" /><ref name="Cheng_2015">{{Cite journal \| vauthors = Cheng MH, Block E, Hu F, Cobanoglu MC, Sorkin A, Bahar I \| title = Insights into the Modulation of Dopamine Transporter Function by Amphetamine, Orphenadrine, and Cocaine Binding \| journal = Frontiers in Neurology \| volume = 6 \| pages = 134 \| date = 2015 \| pmid = 26106364 \| pmc = 4460958 \| doi = 10.3389/fneur.2015.00134 \| doi-access = free }}</ref><ref name="Pom_2012" /> producing reinforcing effects such as [[euphoria]], increased [[alertness]], [[Attentional_control\|concentration]], [[aphrodisiac\|libido]], and reduced fatigue and [[Anorectic\|appetite]].<ref name="Roque_2022">{{cite journal \| vauthors = Roque Bravo R, Faria AC, Brito-da-Costa AM, Carmo H, Mladěnka P, Dias da Silva D, Remião F \| title = Cocaine: An Updated Overview on Chemistry, Detection, Biokinetics, and Pharmacotoxicological Aspects including Abuse Pattern \| journal = Toxins \| volume = 14 \| issue = 4 \| page = 278 \| date = April 2022 \| pmid = 35448887 \| pmc = 9032145 \| doi = 10.3390/toxins14040278 \| doi-access = free }}</ref> <!-- Side effects --> The stimulating qualities of the coca leaf were known to the ancient peoples of Peru and other pre-Columbian Andean societies. In modern Western countries, cocaine has been a feature of the [[counterculture]] for over a century. There is a long list of prominent intellectuals, artists, politicians, and musicians who have used the drug — ranging from [[Sir Arthur Conan Doyle]] and [[Sigmund Freud]] to U.S. Presidents [[Ulysses S. Grant]] and [[George W. Bush substance abuse controversy\|allegedly]] [[George W. Bush]]. Cocaine could be found in trace amounts in the [[Coca-Cola]] beverage for several decades after the beverage's release, though that is no longer the case.<ref>[http://www.snopes.com/cokelore/cocaine.asp snopes.com]</ref> Cocaine has numerous [[adverse effect]]s. Acute use can cause [[vasoconstriction]], [[tachycardia]], [[hypertension]], [[hyperthermia]], seizures, while overdose may lead to [[stroke]], [[myocardial infarction\|heart attack]], or [[sudden cardiac death]].<ref name="Pom_2012" /><ref name="Zimmerman_2012" /><ref name="Sordo_2014">{{Cite journal \|vauthors=Sordo L, Indave BI, Barrio G, Degenhardt L, de la Fuente L, Bravo MJ \|title=Cocaine use and risk of stroke: a systematic review \|journal=Drug and Alcohol Dependence \|volume=142 \|pages=1–13 \|date=September 2014 \|pmid=25066468 \|doi=10.1016/j.drugalcdep.2014.06.041 \|type=Systematic Review \|doi-access=free}}</ref> Cocaine also produces a spectrum of [[psychiatric symptoms]] including agitation, paranoia, anxiety, irritability, [[stimulant psychosis]], hallucinations, delusions, violence, as well as [[suicidal ideation\|suicidal]] and homicidal thinking.<ref name="Morton_1999" /><ref name="Pom_2012" /> [[Prenatal cocaine exposure\|Prenatal exposure]] poses risks to fetal development.<ref name="Buckingham-Howes_2013" /><ref name="Lambert_2012" /><ref name="McCarthy_2014" /><ref name="Eiden_2009" /> Chronic use may result in [[cocaine dependence]], withdrawal symptoms, [[neurotoxicity]], and [[#Cocaine nose\|nasal damage]], including [[cocaine-induced midline destructive lesions]].<ref name="Gawin_1989" /><ref name="Sofuoglu_2005" /><ref name="Clare_2024" /><ref name="Berberi_2024" /><ref name="Nitro_2022" /><ref name="Di_Cosola_2021" /> No approved medication exists for cocaine dependence, so psychosocial treatment is primary.<ref name="Minozzi2015" /><ref name="Kampman_2019" /> Cocaine is frequently [[Lacing (drugs)\|laced]] with levamisole to increase bulk.<ref name="Buchanan_2010">{{cite journal \| vauthors = Buchanan JA, Oyer RJ, Patel NR, Jacquet GA, Bornikova L, Thienelt C, Shriver DA, Shockley LW, Wilson ML, Hurlbut KM, Lavonas EJ \| title = A confirmed case of agranulocytosis after use of cocaine contaminated with levamisole \| journal = Journal of Medical Toxicology \| volume = 6 \| issue = 2 \| pages = 160–164 \| date = June 2010 \| pmid = 20358411 \| pmc = 3550277 \| doi = 10.1007/s13181-010-0060-3 }}</ref><ref name="Vonmoos_2018" /> This is linked to [[vasculitis]] ({{Abbr\|CLIV\|cocaine and levamisole induced vasculitis}}) and [[Autoimmunity\|autoimmune]] conditions ({{Abbr\|CLAAS\|cocaine/levamisole-associated autoimmune syndrome}}).<ref name="Gill_2021" /><ref name="Cascio_2018" /> <!-- Sources --> Its possession, cultivation, and distribution are illegal for non-medicinal and non-government sanctioned purposes in virtually all parts of the world. The name comes from the name of the ''coca'' plant in addition to the alkaloid suffix ''-ine'', forming ''Cocaine''. Today, although its free commercialization is illegal and has been severely penalized in virtually all countries, its use worldwide remains widespread in many social, cultural, and personal settings. Coca cultivation and its subsequent processes occur primarily [[Latin America]], especially in the [[Andes]] of Bolivia, Peru, and Colombia, though cultivation is expanding into [[Central America]], including Honduras, Guatemala, and Belize.<ref name="Andean_full_report.pdf" /><ref name="Murillo-Sandoval_2024">{{cite journal \| vauthors = Murillo-Sandoval PJ, Sesnie SE, Ordoñez Armas ME, Magliocca N, Tellman B, Devine JA, Nielsen E, McSweeney K \| title = Central America's agro-ecological suitability for cultivating coca, Erythroxylum spp \| journal = Environmental Research Letters \| volume = 19 \| issue = 10 \| pages = 104068 \| date = 1 October 2024 \| doi = 10.1088/1748-9326/ad7276 \| bibcode = 2024ERL....19j4068M }}</ref><ref name="plantaciones-laboratorios-y-narcorutas-de-coca-en-honduras-LJ17693091">{{cite news \|title=Plantaciones, laboratorios y narcorutas de coca en Honduras \|url=https://www.elheraldo.hn/elheraldoplus/interactivos/plantaciones-laboratorios-y-narcorutas-de-coca-en-honduras-LJ17693091 \|work=www.elheraldo.hn \|language=es-HN}}</ref><ref name="uatemala-registra-record-produccion-coca-no-cocaina">{{cite news \| vauthors = Papadovassilakis A, Voss G \|title=Guatemala registra récord en producción de coca, pero no de cocaína \|url=https://insightcrime.org/es/noticias/guatemala-registra-record-produccion-coca-no-cocaina/ \|work=InSight Crime \|date=10 February 2023 \|language=es-ES}}</ref><ref name="police-find-half-a-million-coca-plants-in-southern-belize">{{cite news \|title=Police find half a million coca plants in Southern Belize \|url=https://www.breakingbelizenews.com/2023/08/31/police-find-half-a-million-coca-plants-in-southern-belize/ \|work=Belize News and Opinion on www.breakingbelizenews.com \|date=31 August 2023}}</ref> Violence linked to the cocaine trade continues to affect [[Latin America and the Caribbean]] and is expanding into [[Western Europe]], [[Asia]], and [[Africa]] as [[transnational organized crime]] groups compete globally.<ref name="WDR25_Special_points_of_interest.pdf" /><ref name="ow-the-drug-wars-impact-latin-america-and-the-caribbean-development" /> Cocaine remains the world’s fastest-growing [[illegal drug trade\|illicit drug market]].<ref name="Press_release_WDR_2025_English.pdf" /><ref>{{cite news \|title=Cocaine Market Booming as Meth Trafficking Spreads, UN Report Says \|url=https://www.voanews.com/a/cocaine-market-booming-as-meth-trafficking-spreads-un-report-says/7152417.html \|work=Voice of America \|date=25 June 2023 \|language=en}}</ref> Coca chewing dates back at least 8,000 years in South America.<ref>{{cite journal\| vauthors = Dillehay TD, Rossen J, Ugent D, Karathanasis A, Vásquez V, Netherly PJ \|year=2010\|title=Early Holocene coca chewing in northern Peru\|journal=[[Antiquity (journal)\|Antiquity]]\|volume=84\|issue=326\|pages=939–953\|doi=10.1017/S0003598X00067004\|s2cid=162889680}}</ref> Large-scale cultivation occurred in [[Taiwan]] and [[Java]] prior to [[World War II]].<ref name="Lu_2024" /><ref name="Musto_1998" /> Decades later, the [[cocaine boom]] marked a sharp rise in illegal cocaine production and trade, beginning in the late 1970s and peaking in the 1980s.<ref>{{cite web \|url=https://www.pbs.org/newshour/arts/what-it-was-really-like-to-be-in-miami-in-the-crazy-cocaine-years \|title=What it was really like to be in Miami during the crazy cocaine boom \| vauthors = Flock E \|date= 21 January 2017 \|website=pbs.org}}</ref> Cocaine is regulated under [[international drug control conventions]], though [[legal status of cocaine\|national laws vary]]: several countries have decriminalized small quantities.<ref name="Housego_2004">{{cite news \| vauthors = Housego K \| title= As addiction rises, Colombia weighs rolling back decade-old drug legalization \| date=2004-04-05 \| work=[[The San Diego Union-Tribune]] \| url =http://www.signonsandiego.com/news/world/20040405-0915-legalizeddrugs.html \| agency =Associated Press \| access-date = 2009-08-09 }}</ref><ref name="Murphy_2004">{{cite news \| vauthors = Murphy J \| title=Colombia sinks in sea of legal cocaine, heroin \| date=2004-04-05 \| work=[[CBS News]] \| url =http://www.cbsnews.com/stories/2004/04/05/world/main610293.shtml \| archive-url =https://web.archive.org/web/20040405221943/http://www.cbsnews.com/stories/2004/04/05/world/main610293.shtml \| url-status =dead \| archive-date =April 5, 2004 \| access-date = 2009-08-09 }}</ref><ref name="independent">{{cite web\|url=https://www.independent.co.uk/news/world/americas/heroin-and-cocaine-now-legal-in-mexico-ndash-in-small-doses-1776792.html\|title=Heroin and cocaine now legal in Mexico – in small doses \| Americas \| News \| The Independent\|date=23 October 2011\|work=The Independent\|access-date=2016-05-15}}</ref><ref name="Greenwald_2009">{{Cite book\| vauthors = Greenwald G, Reuter P, Lynch T \|author-link=Glenn Greenwald \| contribution=Lessons for Creating Fair and Successful Drug Policies\| title=Drug Decriminalization in Portugal\| publisher=Cato Institute\| date=2009-04-03\| contribution-url=http://www.cato.org/pubs/wtpapers/greenwald_whitepaper.pdf}}</ref> {{TOC limit}} ~~== Pharmacology ==~~ ~~=== Appearance ===~~ ~~[[Image:CocaineHydrochloridePowder.jpg\|right\|thumb\|A pile of cocaine hydrochloride]]~~ Cocaine in its purest form is a white, pearly product. Cocaine appearing in powder form is a [[salt]], typically cocaine [[hydrochloride]] ([[CAS registry number\|CAS]] 53-21-4). Street market cocaine is frequently adulterated or “cut” with various powdery fillers to increase its weight; the substances most commonly used in this process are [[baking soda]]; sugars, such as [[lactose]], [[dextrose]], [[inositol]], and [[mannitol]]; and local anesthetics, such as [[lidocaine]] or [[benzocaine]], which mimic or add to cocaine's numbing effect on mucous membranes. Cocaine may also be "cut" with other stimulants such as [[methamphetamine]]. <ref>[http://designer-drugs.com/pte/12.162.180.114/dcd/chemistry/psychedelicchemistry/chapter8.html Psychedelic Chemistry: Cocaine]</ref> Adulterated cocaine is often a white, off-white or pinkish powder. == Uses == The color of [[crack cocaine\|“crack” cocaine]] depends upon several factors including the origin of the cocaine used, the method of preparation – with [[ammonia]] or [[sodium bicarbonate]] – and the presence of impurities, but will generally range from white to a yellowish cream to a light brown. Its texture will also depend on the adulterants, origin and processing of the powdered cocaine, and the method of converting the base. It ranges from a crumbly texture, sometimes extremely oily, to a hard, almost crystalline nature. Coca leaves have been used by [[Andean civilizations]] since [[Andean civilizations\|ancient times]].<ref name="Goldstein_2009">{{Cite journal \| vauthors = Goldstein RA, DesLauriers C, Burda AM \| title = Cocaine: history, social implications, and toxicity--a review \| journal = Disease-a-Month \| volume = 55 \| issue = 1 \| pages = 6–38 \| date = January 2009 \| pmid = 19081448 \| doi = 10.1016/j.disamonth.2008.10.002 }}</ref> In ancient [[Wari culture]],<ref name="Valdez_2015">{{Cite journal \| vauthors = Valdez LM, Taboada J, Valdez JE \|title=Ancient Use of Coca Leaves in the Peruvian Central Highlands \|journal=Journal of Anthropological Research \|date=June 2015 \|volume=71 \|issue=2 \|pages=231–258 \|doi=10.3998/jar.0521004.0071.204\|s2cid=163842955 \|hdl=2027/spo.0521004.0071.204 \|hdl-access=free }}</ref> [[Quechua people\|Inca]] culture, and through modern successor [[Indigenous peoples\|indigenous]] cultures of the [[Andes mountains]], coca leaves are chewed, taken orally in the form of a [[Coca tea\|tea]], or alternatively, prepared in a sachet wrapped around alkaline burnt ashes, and held in the [[buccal pouch\|mouth against the inner cheek]]; it has traditionally been used as an [[anorectic]] and to combat the effects of cold and [[altitude sickness]],<ref name="Martin_1970">{{Cite journal \| vauthors = Martin RT \|title=The role of coca in the history, religion, and medicine of South American Indians \|journal=Economic Botany \|date=October 1970 \|volume=24 \|issue=4 \|pages=422–438 \|doi=10.1007/BF02860746\|bibcode=1970EcBot..24..422M \|s2cid=34523519 }}</ref><ref name="Plant_2008">{{Cite journal \| vauthors = Plant T, Aref-Adib G \| title = Travelling to new heights: practical high altitude medicine \| journal = British Journal of Hospital Medicine \| volume = 69 \| issue = 6 \| pages = 348–352 \| date = June 2008 \| pmid = 18646420 \| doi = 10.12968/hmed.2008.69.6.29626 }}</ref> although its actual effectiveness has never been systematically studied.<ref name="Luks_2014">{{cite journal \| vauthors = Luks AM, McIntosh SE, Grissom CK, Auerbach PS, Rodway GW, Schoene RB, Zafren K, Hackett PH \| title = Wilderness Medical Society practice guidelines for the prevention and treatment of acute altitude illness: 2014 update \| journal = Wilderness & Environmental Medicine \| volume = 25 \| issue = 4 Suppl \| pages = S4–14 \| date = December 2014 \| pmid = 25498261 \| doi = 10.1016/j.wem.2014.06.017 }}</ref> Globally, in 2019, cocaine was used by an estimated 20 million people (0.4% of adults aged 15 to 64 years). The highest prevalence of cocaine use was in [[Australia]] and [[New Zealand]] (2.1%), followed by [[North America]] (2.1%), [[Western Europe\|Western]] and [[Central Europe]] (1.4%), and [[South America\|South]] and [[Central America]] (1.0%).<ref name="WDR2021">{{Cite book \|title=World Drug Report 2021: Booklet 4 \|date= 2021 \|publisher=United Nations Office on Drugs and Crime \|___location=[S.l.]\| page = 35\|isbn=978-92-1-148361-1 \|url=https://www.unodc.org/res/wdr2021/field/WDR21_Booklet_4.pdf \|archive-url=https://web.archive.org/web/20210624081524/https://www.unodc.org/res/wdr2021/field/WDR21_Booklet_4.pdf \|archive-date=24 June 2021 \|url-status=live}}</ref> Since 1961, the [[Single Convention on Narcotic Drugs]] has required countries to make recreational use of cocaine a [[crime]].<ref>{{Cite journal \| vauthors = Room R, Reuter P \| title = How well do international drug conventions protect public health? \| journal = Lancet \| volume = 379 \| issue = 9810 \| pages = 84–91 \| date = January 2012 \| pmid = 22225673 \| doi = 10.1016/s0140-6736(11)61423-2 \| quote = The international treaties have also constrained national policy experimentation because they require nation states to criminalise drug use \| s2cid = 23386203 }}</ref> In the United States, cocaine is regulated as a [[Schedule II Controlled Substance\|Schedule II]] drug under the [[Controlled Substances Act]], meaning that it has a high potential for abuse but has an accepted medical use.<ref>{{Cite web \|title=Drug Fact Sheet: Cocaine \|url=https://www.dea.gov/sites/default/files/2020-06/Cocaine-2020_1.pdf \|archive-url=https://web.archive.org/web/20200621183713/https://www.dea.gov/sites/default/files/2020-06/Cocaine-2020_1.pdf \|archive-date=21 June 2020 \|url-status=live \|publisher=Drug Enforcement Agency \|access-date=17 June 2022}}</ref> While rarely used medically today, its accepted uses include serving as a topical local anesthetic for the upper [[respiratory tract]] and as an [[antihemorrhagic]] agent to stop bleeding in the mouth, throat, and nasal cavities.<ref>{{cite web \|url=https://www.dea.gov/sites/default/files/2020-06/Cocaine-2020_1.pdf \|title=Drug Fact Sheet: Cocaine \|publisher=US Department for Justice and Drug Enforcement Administration \|access-date=29 June 2024 \|archive-date=21 June 2020 \|archive-url=https://web.archive.org/web/20200621183713/https://www.dea.gov/sites/default/files/2020-06/Cocaine-2020_1.pdf \|url-status=live }}</ref> ~~=== Forms of cocaine ===~~ ~~==== Cocaine sulfate ====~~ === Traditional medicine === Cocaine sulfate is produced by macerating coca leaves along with [[water]] that has been acidulated with sulfuric acid, or an aromatic-based solvent, like kerosene or [[benzene]]. This is often accomplished by putting the ingredients into a vat and stamping on it, in a manner similar to the traditional method for crushing [[grape]]s. After the maceration is completed, the water is evaporated to yield a pasty mass of impure cocaine sulfate. ==== Coca leaves ==== The sulfate salt itself is an intermediate step to producing cocaine hydrochloride. In [[South America]], it is commonly sold to consumers as such, and smoked along with tobacco, also known as ''pasta,'' ''basuco,'' ''basa,'' ''pitillo,'' ''paco'' or simply ''paste.'' It is also gaining popularity as a cheap drug (30 to 70 U.S. cents per "hit" or dose) in many South American countries. {{Main\|Coca}} [[File:Llipta on coca leaf.jpeg\|thumb\|''Llipta'' is used to improve extraction when chewing coca (Museo de la Coca, [[Cusco]], Peru).]] ~~==== Freebase ====~~ ~~{{main\|Freebase}}~~ As the name implies, “freebase” is the [[Base (chemistry)\|base]] form of cocaine, as opposed to the [[salt]] form of cocaine hydrochloride. Whereas cocaine hydrochloride is extremely [[soluble]] in [[water]], cocaine base is insoluble in water and is therefore not suitable for drinking, snorting or injecting. Whereas cocaine hydrochloride is not well-suited for smoking because the [[temperature]] at which it [[evaporation\|vaporizes]] is very high, and close to the temperature at which it [[combustion\|burns]]; however, cocaine base [[evaporation\|vaporizes]] at a much lower temperature, which makes it suitable for inhalation. It is legal for people to use [[coca]] leaves in the [[Andean Community]], such as [[Peru]] and [[Bolivia]], where they are chewed, consumed in the form of tea, or are sometimes incorporated into food products.<ref>{{Cite web\|url=https://www.pri.org/stories/2011-04-01/tradition-chewing-coca\|title=The tradition of chewing coca\|date=15 August 2013 \|access-date=6 May 2021\|archive-date=6 May 2021\|archive-url=https://web.archive.org/web/20210506205057/https://www.pri.org/stories/2011-04-01/tradition-chewing-coca\|url-status=live}}</ref> Coca leaves are typically mixed with an alkaline substance (such as [[calcium hydroxide\|slaked lime]]) and chewed into a wad that is retained in the [[buccal pouch]] (mouth between gum and cheek, much the same as [[chewing tobacco]] is chewed) and sucked of its juices. The juices are absorbed slowly by the [[mucous membrane]] of the inner cheek and by the [[gastrointestinal tract]] when swallowed. Smoking freebase is preferred by many users because the cocaine is absorbed immediately into [[blood]] via the [[lungs]], where it reaches the [[brain]] in about five seconds. The rush is much more intense than sniffing the same amount of cocaine nasally, but the effects do not last as long. The peak of the freebase rush is over almost as soon as the user exhales the vapor, but the high typically lasts 5–10 minutes afterward. What makes freebasing particularly dangerous is that users typically don't wait that long for their next hit and will continue to smoke freebase until none is left. These effects are similar to those that can be achieved by injecting or “slamming” cocaine hydrochloride, but without the risks associated with [[intravenous]] drug use (though there are other serious risks associated with smoking freebase). ===== Coca tea ===== Freebase cocaine is produced by first dissolving cocaine hydrochloride in water. Once dissolved in water, cocaine hydrochloride (Coc HCl) dissociates into protonated cocaine [[ion]] (Coc-H<sup><small>+</small></sup>) and [[chloride]] ion (Cl<sup><small>–</small></sup>). Any [[solid]]s that remain in the [[solution]] are not cocaine (they are part of the cut) and are removed by [[Filter (chemistry)\|filtering]]. A base, typically [[ammonia]] (NH<sub><small>3</small></sub>), is added to the [[solution]]. The following net [[chemical reaction]] takes place: {{Main\|Coca tea}} [[File:Mate de coca Peru.jpg\|right\|thumb\|Two cups of coca tea]] ~~<div align="center" style="line-height: 2em;">Coc-H<sup><small>+</small><sup>Cl<sup><small>–</small><sup> + NH<sub><small>3</small></sub> → Coc + NH<sub><small>4</small></sub>Cl</div>~~ Coca herbal [[infusion]] (also referred to as [[coca tea]]) is used in coca-leaf producing countries much as any herbal medicinal infusion would elsewhere in the world. The free and legal commercialization of dried coca leaves under the form of filtration bags to be used as "coca tea" has been actively promoted by the governments of [[Peru]] and [[Bolivia]] for many years as a drink having [[alternative medicine\|medicinal powers]]. In Peru, the [[National Coca Company]], a state-run corporation, sells cocaine-infused teas and other medicinal products and also exports leaves to the U.S. for medicinal use.<ref>{{Cite web\|url=https://www.businessinsider.com/britain-is-the-worlds-biggest-exporter-of-legal-cocaine-and-heroin-2018-4\|title=It's legal to manufacture cocaine and heroin for medical use — and Britain is the world's biggest exporter\|vauthors=Embury-Dennis T\|website=Business Insider\|access-date=17 March 2019\|archive-date=28 July 2020\|archive-url=https://web.archive.org/web/20200728165239/https://www.businessinsider.com/britain-is-the-worlds-biggest-exporter-of-legal-cocaine-and-heroin-2018-4\|url-status=live}}</ref> The effects of drinking coca tea are mild stimulation and mood lift.<ref>{{Cite web\|url=https://www.drugs.com/illicit/cocaine.html\|title=Cocaine: Effects, Hazards & Warnings\|website=Drugs.com\|access-date=17 March 2019\|archive-date=28 July 2020\|archive-url=https://web.archive.org/web/20200728162727/https://www.drugs.com/illicit/cocaine.html\|url-status=live}}</ref> As freebase cocaine (Coc) is insoluble in water, it [[Precipitation (chemistry)\|precipitates]] and the solution becomes cloudy. To recover the freebase, a [[nonpolar]] solvent like [[diethyl ether]] is added to the solution: Because freebase is highly soluble in ether, a vigorous shaking of the mixture results in the freebase being dissolved in the ether. As [[ether]] is insoluble in water, it can be [[siphon]]ed off. The ether is then evaporated, leaving behind the cocaine base. In 1986 an article in the ''[[Journal of the American Medical Association]]'' revealed that U.S. [[health food store]]s were selling dried coca leaves to be prepared as an infusion as "Health Inca Tea". While the packaging claimed it had been "decocainized", no such process had actually taken place. The article stated that drinking two cups of the tea per day gave a mild [[stimulation]], increased [[heart rate]], and [[emotional mood\|mood]] elevation, and the tea was essentially harmless.<ref name="Siegel_1986">{{Cite journal \| vauthors = Siegel RK, Elsohly MA, Plowman T, Rury PM, Jones RT \| title = Cocaine in herbal tea \| journal = JAMA \| volume = 255 \| issue = 1 \| page = 40 \| date = January 1986 \| pmid = 3940302 \| doi = 10.1001/jama.1986.03370010042021 }}</ref> Handling diethyl ether is dangerous because ether is extremely [[flammable]], its vapors are heavier than air and can “creep” from an open bottle, and in the presence of oxygen it can form [[diethyl ether peroxide\|peroxide]]s, which can spontaneously combust. Demonstrative of the dangers of the practice, comedian [[Richard Pryor]] used to perform a skit in which he poked fun at himself over a 1980 incident in which he caused an explosion and ignited himself attempting to smoke “freebase”, presumably while still wet with ether. ===== Ypadu ===== Freebasing, while powerful, ultimately causes chronic paranoia and loss of sound judgment in the user. The rapid decline of porn actor [[John C. Holmes]] and his involvement in the 1981 massacre of the [[Wonderland Gang]] were among the first signs of the dangers of the then-growing freebase phenomenon. {{Main\|Ypadu}} ~~{{Fact\|date=February 2007}}~~ [[File:Mambe indigena coca colombia crista castellanos.jpg\|thumb\|Mambe or ypadu is made from toasted and ground coca leaves with ashes]] ~~==== Crack cocaine ====~~ ~~Main article: ''[[Crack cocaine]]''~~ [[Ypadu\|Ypadú]] or ypadu (also known as mambé) is an unrefined, unconcentrated [[Powder (substance)\|powder]] made from toasted [[coca]] leaves and the ash of various other plants. It is traditionally prepared and consumed by indigenous tribes in the Northwest Amazon.<ref>{{Cite journal \| vauthors = Schultes RE \|title=A New Method of Coca Preparation in the Colombian Amazon \|date=1957 \|url=https://www.jstor.org/stable/41762172 \|journal=Botanical Museum Leaflets, Harvard University \|volume=17 \|issue=9 \|pages=241–246 \|doi=10.5962/p.168505 \|jstor=41762172 \|issn=0006-8098}}</ref> Like coca teas consumed in [[Peru]] to adapt to sickness induced by high elevation, it has a long [[ethnobotanical]] history and cultural associations. ~~[[Image:Crack street dosage.jpg\|thumb\|right\|A pile of [[crack cocaine]] ‘rocks’.]]~~ Due to the dangers of using ether to produce pure freebase cocaine, cocaine producers began to omit the step of removing the freebase cocaine precipitate from the ammonia mixture. Typically, filtration processes are also omitted. The end result of this process is that the cut, in addition to the ammonium salt (NH<sub><small>4</small></sub>Cl), remains in the freebase cocaine after the mixture is evaporated. The “rock” that is thus formed also contains a small amount of water. Sodium bicarbonate ([[baking soda]]) is also preferred in preparing the freebase, for when commonly "cooked" the ratio is 50/50 to 40/60 percent cocaine/bicarbonate. This acts as a filler which extends the overall profitability of illicit sales. Crack cocaine may be reprocessed in small quantities with water (users refer to the resultant product as "cookback"). This removes the residual bicarbonate, and any adulterants or cuts that have been used in the previous handling of the cocaine and leaves a relatively pure, anhydrous cocaine base. === Medical === When the rock is heated, this water boils, making a crackling sound (hence the onomatopoeic “crack”). Baking soda is now most often used as a base rather than ammonia for reasons of lowered stench and toxicity; however, any weak base can be used to make crack cocaine. Strong bases, such as sodium hydroxide, tend to [[hydrolyze]] some of the cocaine into non-psychoactive [[ecgonine]]. [[Karl Koller (ophthalmologist)\|Karl Koller]]’s groundbreaking discovery of cocaine as a local anesthetic is regarded as the second most significant advance in the history of anesthesia. Although cocaine was once widely preferred for topical anesthesia, the search for replacement agents intensified due to rising costs, strict regulations, and its habit-forming potential.<ref name="Armbuster_2021" /> Cocaine is not included on the [[WHO Model List of Essential Medicines]]; the list formally excludes "cocaine and its combinations" as therapeutic alternatives to [[WHO Model List of Essential Medicines#Ophthalmological preparations\|ophthalmological preparations]].<ref name="WHO-MHP-HPS-EML-2023.02">{{cite web \|title=WHO Model List of Essential Medicines - 23rd list, 2023 \|url=https://www.who.int/publications/i/item/WHO-MHP-HPS-EML-2023.02 \|website=www.who.int \|language=en}}</ref> Today, the US [[Drug Enforcement Administration]] (DEA) classifies cocaine as a [[Schedule II drug]], recognizing its high potential for abuse but still permitting its limited use for medical purposes. However, current [[Pharmacoepidemiology\|pharmacoepidemiological]] trends suggest that cocaine may soon reach the point where, in practical terms, it is no longer used medically in health care as a Schedule II substance. This report may prompt some states (such as North Dakota) and institutions to reconsider whether further efforts to identify alternative agents are needed. As physician boards—but not pharmacy boards—continue to assess knowledge of licit cocaine, attention may shift toward drugs with more contemporary medical use.<ref name="Armbuster_2021" /> Crack cocaine was extremely popular in the mid- and late [[1980s]] in a period known as the [[Crack Epidemic]], especially in inner cities, though its popularity declined through the [[1990s]] in the United States. Cocaine is rarely prescribed in modern medicine due to its high potential for abuse and significant risk of adverse effects; its use is now almost exclusively limited to [[health facility\|health facilities]] for specific diagnostic procedures or surgeries. ~~==== Chewed/eaten ====~~ ====Topical==== Coca leaves typically are mixed with an alkaline substance (such as lime) and chewed into a wad that is retained in the mouth between gum and cheek and sucked of its juices. The juices are absorbed slowly by the mucous membrane of the inner cheek and by the gastro-intestinal tract when swallowed. Alternatively, coca leaves can be infused in liquid and consumed like tea. Ingesting coca leaves generally is an inefficient means of administering cocaine. Advocates of the consumption of the coca leaf, state that coca leaf consumption should not be criminalized as it is not actual cocaine, and consequently it is not properly the illicit drug. Because cocaine is hydrolyzed and rendered inactive in the acidic stomach, it is not readily absorbed when ingested alone. Only when mixed with a highly alkaline substance (such as lime) can it be absorbed into the bloodstream through the stomach. The efficiency of absorption of orally administered cocaine is limited by two additional factors. First, the drug is partly catabolized by the liver. Second, capillaries in the mouth and esophagus constrict after contact with the drug, reducing the surface area over which the drug can be absorbed. Nevertheless, cocaine metabolites can be detected in the urine of subjects that have sipped even one cup of coca leaf infusion. Therefore, this is an actual additional form of administration of cocaine albeit inefficient. Cocaine is used in medical practice as a [[topical medication]].<ref name="Armbuster_2021" /> Because it is not absorbed into the bloodstream in significant amounts when used this way, topical application does not produce the psychoactive effects associated with recreational cocaine use. =====Topical anesthetic===== Orally administered cocaine takes approximately 30 minutes to enter the bloodstream. Typically, only a third of an oral dose is absorbed, although absorption has been shown to reach 60 percent in controlled settings. Given the slow rate of absorption, maximum physiological and psychotropic effects are attained approximately 60 minutes after cocaine is administered by ingestion. While the onset of these effects is slow, the effects are sustained for approximately 60 minutes after their peak is attained. {{See also\|Moffett's solution}} [[File:Cocaine hydrochloride CII for medicinal use.jpg\|thumb\|upright\|Cocaine [[hydrochloride]]]] Cocaine is sometimes used in [[otorhinolaryngology]] as a [[topical anesthetic]] and [[vasoconstrictor]] to help control pain and bleeding during surgery of the nose, mouth, throat, or [[lacrimal duct]]. It is also used for topical airway anaesthesia for procedures such as awake fibreoptic [[bronchoscopy]] or [[intubation]]. Although some absorption and systemic effects may occur, the use of cocaine as a topical anesthetic and vasoconstrictor is generally safe, rarely causing [[cardiovascular]] toxicity, [[glaucoma]], and [[mydriasis\|pupil dilation]].<ref name="Dwyer_2016">{{Cite journal \| vauthors = Dwyer C, Sowerby L, Rotenberg BW \| title = Is cocaine a safe topical agent for use during endoscopic sinus surgery? \| journal = The Laryngoscope \| volume = 126 \| issue = 8 \| pages = 1721–1723 \| date = August 2016 \| pmid = 27075241 \| doi = 10.1002/lary.25836 \| type = Review \| doi-access = free }}</ref><ref name="Latorre_1999">{{Cite journal \| vauthors = Latorre F, Klimek L \| title = Does cocaine still have a role in nasal surgery? \| journal = Drug Safety \| volume = 20 \| issue = 1 \| pages = 9–13 \| date = January 1999 \| pmid = 9935273 \| doi = 10.2165/00002018-199920010-00002 \| s2cid = 40598106 }}</ref> Occasionally, cocaine is mixed with [[adrenaline]] and [[sodium bicarbonate]] and used topically for surgery, a formulation called [[Moffett's solution]].<ref>{{Cite journal \| vauthors = Benjamin E, Wong DK, Choa D \| title = 'Moffett's' solution: a review of the evidence and scientific basis for the topical preparation of the nose \| journal = Clinical Otolaryngology and Allied Sciences \| volume = 29 \| issue = 6 \| pages = 582–587 \| date = December 2004 \| pmid = 15533141 \| doi = 10.1111/j.1365-2273.2004.00894.x \| doi-access = free }}</ref> It is occasionally used in surgeries involving the [[pharynx]] or [[nasopharynx]] to reduce pain, bleeding, and [[laryngospasm\|vocal cord spasm]].<ref>{{Cite book \|vauthors=Hamdan AL, Sataloff RT, Hawkshaw MJ \|title=Office-Based Laryngeal Surgery \|chapter=Topical Anesthesia in Office-Based Laryngeal Surgery \|chapter-url=https://link.springer.com/chapter/10.1007/978-3-030-91936-8_6 \|date=2022 \|pages=123–137 \|publisher=Springer \|___location=USA \|doi=10.1007/978-3-030-91936-8_6 \|isbn=978-3-030-91935-1 \|access-date=18 July 2022 \|archive-date=18 July 2022 \|archive-url=https://web.archive.org/web/20220718085028/https://link.springer.com/chapter/10.1007/978-3-030-91936-8_6 \|url-status=live }}</ref> Contrary to popular belief, both ingestion and insufflation result in approximately the same proportion of the drug being absorbed: 30 to 60 percent. Compared to ingestion, the faster absorption of insufflated cocaine results in quicker attainment of maximum drug effects. Snorting cocaine produces maximum physiological effects within 40 minutes and maximum psychotropic effects within 20 minutes, however, a more realistic activation period is closer to 5 to 10 minutes, which is similar to ingestion of cocaine. Physiological and psychotropic effects from nasally insufflated cocaine are sustained for approximately 40 - 60 minutes after the peak effects are attained.<ref>G. Barnett, R. Hawks and R. Resnick, "Cocaine Pharmacokinetics in Humans," 3 Journal of Ethnopharmacology 353 (1981); Jones, supra note 19; Wilkinson ''et al.'', Van Dyke ''et al.''</ref> Nasal solution cocaine hydrochloride ('''Goprelto'''), an ester used for intranasal application, was approved for medical use in the United States in December 2017, and is indicated for the introduction of topical anesthesia of the mucous membranes for diagnostic procedures and surgeries on or through the nasal cavities of adults.<ref>{{Cite web \| title=Drug Approval Package: Goprelto (cocaine hydrochloride) \| website=U.S. [[Food and Drug Administration]] (FDA) \| date=30 April 2018 \| url=https://www.accessdata.fda.gov/drugsatfda_docs/nda/2017/209963Orig1s000TOC.cfm \| access-date=30 April 2020 \| archive-date=28 July 2020 \| archive-url=https://web.archive.org/web/20200728161852/https://www.accessdata.fda.gov/drugsatfda_docs/nda/2017/209963Orig1s000TOC.cfm \| url-status=dead }}</ref><ref name="Goprelto FDA label">{{Cite web \| title=Goprelto – cocaine hydrochloride solution \| website=DailyMed \| date=3 January 2020 \| url=https://dailymed.nlm.nih.gov/dailymed/drugInfo.cfm?setid=689750b7-8e51-47d9-a428-078f3f6c9dec \| access-date=30 April 2020 \| archive-date=30 July 2020 \| archive-url=https://web.archive.org/web/20200730202926/https://dailymed.nlm.nih.gov/dailymed/drugInfo.cfm?setid=689750b7-8e51-47d9-a428-078f3f6c9dec \| url-status=live }}</ref> Cocaine hydrochloride ('''Numbrino''') was approved for medical use in the United States in January 2020.<ref>{{Citation-attribution\|1={{Cite web \| title=Numbrino: FDA-Approved Drugs \| website=U.S. [[Food and Drug Administration]] (FDA) \| url=https://www.accessdata.fda.gov/scripts/cder/daf/index.cfm?event=overview.process&ApplNo=209575 \| access-date=30 April 2020 \| archive-date=28 July 2020 \| archive-url=https://web.archive.org/web/20200728172108/https://www.accessdata.fda.gov/scripts/cder/daf/index.cfm?event=overview.process&ApplNo=209575 \| url-status=live }} }}</ref><ref name="Numbrino FDA label">{{Cite web \| title=Numbrino – cocaine hydrochloride nasal solution \| website=DailyMed \| date=28 February 2020 \| url=https://dailymed.nlm.nih.gov/dailymed/drugInfo.cfm?setid=94f9b3f8-bce5-41ed-9453-c54ed1d6c269 \| access-date=30 April 2020 \| archive-date=30 July 2020 \| archive-url=https://web.archive.org/web/20200730063812/https://dailymed.nlm.nih.gov/dailymed/drugInfo.cfm?setid=94f9b3f8-bce5-41ed-9453-c54ed1d6c269 \| url-status=live }}</ref> Headache and [[epistaxis]] are the most frequently reported adverse reactions with Goprelto,<ref name="Goprelto FDA label" /> while hypertension and tachycardia-including [[sinus tachycardia]]-are most common with Numbrino.<ref name="Numbrino FDA label" /> ''[[Mate de coca]]'' or coca-leaf infusion is also a traditional method of consumption and is often recommended in coca producing countries, like Peru and Bolivia, to ameliorate some symptoms of [[altitude sickness]]. This method of consumption has been practiced for many centuries by the native tribes of South America. One specific purpose of ancient coca leaf consumption was to increase energy and reduce fatigue in messengers who made multi-day quests to other settlements. =====Ophthalmological use===== In [[1986]] an article in the ''[[Journal of the American Medical Association]]'' revealed that U.S. health food stores were selling dried coca leaves to be prepared as an infusion as “Health Inca Tea.”<ref>{{cite journal \| author=Siegel RK, Elsohly MA, Plowman T, Rury PM, Jones RT \| title=Cocaine in herbal tea \| journal=Journal of the American Medical Association \| year=January 3, 1986 \| volume=255\|issue=1\| pages=40 \| url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=3940302&query_hl=3&itool=pubmed_docsum \|curly=true}}</ref> While the packaging claimed it had been “decocainized,” no such process had actually taken place. The article stated that drinking two cups of the tea per day gave a mild [[stimulation]], increased [[heart rate]], and [[Emotional mood\|mood]] elevation, and the tea was essentially harmless. Despite this, the [[Drug Enforcement Agency\|DEA]] seized several shipments in [[Hawaii]], [[Chicago\|Chicago, Illinois]], [[Georgia (U.S. state)\|Georgia]], and several locations on the [[East Coast of the United States]], and the product was removed from the shelves.<ref name="dominic_streatfeild"/> Nevertheless, today coca leaf teabags (named "mate de coca") illegally smuggled into the U.S. can be readily purchased online via Internet stores and even [[eBay]]. Cocaine [[eye drop]]s have traditionally been used by [[Neurology\|neurologists]] when examining people suspected of having [[Horner's syndrome\|Horner syndrome]]. In Horner syndrome, [[sympathetic innervation]] to the eye is blocked. In a healthy eye, cocaine stimulates the [[sympathetic nervous system]] (SNS) by inhibiting norepinephrine reuptake, causing the [[pupil]] to dilate. In patients with Horner syndrome, sympathetic innervation to the eye is disrupted, so the affected pupil does not dilate in response to cocaine and remains constricted, or dilates to a lesser extent than the unaffected eye, which also receives the eye drop test. If both eyes dilate equally, the patient does not have Horner syndrome.<ref>{{Cite book \| vauthors = Berkowitz AL \|title=Clinical Neurology & Neuroanatomy: A Localization-Based Approach \|publisher=McGraw Hill \|year=2022 \|isbn=978-1260453362 \|edition=2nd \|chapter=Chapter 10: Pupillary Control & Approach to Anisocoria: Cranial Nerves 2 & 3 \|type=Digital}}</ref> However, [[apraclonidine]] has largely replaced cocaine as the first-line pharmacologic agent for the diagnosis of Horner syndrome in routine clinical practice.<ref>{{cite journal \| vauthors = Smit D \| title = Pharmacologic testing in Horner's syndrome - a new paradigm. \| journal = South African Medical Journal = Suid-Afrikaanse Tydskrif vir Geneeskunde \| volume = 100 \| issue = 11 \| pages = 738–740 \| date = 9 November 2010 \| pmid = 21081027 \| doi = 10.7196/samj.3773 }}</ref><ref>{{cite journal \| vauthors = Freedman K, Brown S \| title = Topical apraclonidine in the diagnosis of suspected Horner syndrome. \| journal = Journal of Neuro-Ophthalmology \| volume = 25 \| issue = 2 \| pages = 83–85 \| date = June 2005 \| pmid = 15937427 \| doi = 10.1097/01.wno.0000165108.31731.36 }}</ref><ref name="Bremner_2019">{{cite journal \| vauthors = Bremner F \| title = Apraclonidine Is Better Than Cocaine for Detection of Horner Syndrome. \| journal = Frontiers in Neurology \| volume = 10 \| article-number = 55 \| date = 2019 \| pmid = 30804875 \| pmc = 6371044 \| doi = 10.3389/fneur.2019.00055 \| doi-access = free }}</ref> === Recreational === {{For\|Cocaine or crack cocaine combined with other drugs\|List of polysubstance combinations}} [[File:Peruvian Flake Cocaine.jpg\|thumb\|Peruvian flake cocaine on a metal milligram [[weighing scale\|scale]] tray]] Recreational cocaine is typically not taken by mouth due to its poor bioavailability, instead it is usually [[Nasal administration\|snorted]] or [[injection (medicine)\|injected]]. Cocaine hydrochloride can also be chemically converted into its [[free base]] form, [[crack cocaine]], which can be vaporized. Cocaine is a [[central nervous system]] [[stimulant]].<ref name="WHO2004">{{Cite book\|author=World Health Organization\|year=2004\|url=https://books.google.com/books?id=G9OhG-dZdAwC&pg=PA89\|title=Neuroscience of psychoactive substance use and dependence\|page=89\|publisher=World Health Organization \|isbn=978-9241562355\|url-status=live\|archive-url=https://web.archive.org/web/20160430122452/https://books.google.com/books?id=G9OhG-dZdAwC&pg=PA89\|archive-date=30 April 2016}}</ref> Its effects can last from 15 minutes to an hour. The duration of cocaine's effects depends on the amount taken and the route of administration.<ref name="WHO2007">{{Cite book\|author=World Health Organization\|year=2007\|url=https://books.google.com/books?id=ptVjyRs7AdsC&pg=PA242\|title=International medical guide for ships\|page=242\|publisher=World Health Organization \|isbn=978-9241547208\|url-status=live\|archive-url=https://web.archive.org/web/20160430152905/https://books.google.com/books?id=ptVjyRs7AdsC&pg=PA242\|archive-date=30 April 2016}}</ref> Cocaine can be in the form of fine white powder and has a bitter taste. [[Crack cocaine]] is a smokeable form of cocaine made into small "rocks" by processing cocaine with [[sodium bicarbonate]] (baking soda) and water.<ref name="Zimmerman_2012" /><ref name="Sordo_2014"/> Cocaine use leads to increases in alertness, feelings of well-being and [[euphoria]], increased energy and [[motor control\|motor]] activity, and increased feelings of competence and [[Human sexuality\|sexuality]].<ref name="Donroe_2017">{{Cite journal \| vauthors = Donroe JH, Tetrault JM \| title = Substance Use, Intoxication, and Withdrawal in the Critical Care Setting \| journal = Critical Care Clinics \| volume = 33 \| issue = 3 \| pages = 543–558 \| date = July 2017 \| pmid = 28601134 \| doi = 10.1016/j.ccc.2017.03.003 \| type = Review }}</ref> Expectations about cocaine's effects—both positive and negative—can influence how people feel after using it. Surprisingly, expecting negative effects may increase the drug's perceived positive impact, making quitting or avoiding cocaine more difficult for some individuals.<ref>{{cite journal \| vauthors = Lundahl LH, Lukas SE \| title = Negative cocaine effect expectancies are associated with subjective response to cocaine challenge in recreational cocaine users \| journal = Addictive Behaviors \| volume = 32 \| issue = 6 \| pages = 1262–1271 \| date = June 2007 \| pmid = 17110052 \| pmc = 4315184 \| doi = 10.1016/j.addbeh.2006.09.001 }}</ref> Analysis of the [[Correlation and dependence\|correlation]] between the use of 18 various [[psychoactive substance]]s shows that cocaine use correlates with other "[[Club drug\|party drugs]]" (such as [[MDMA]] or [[amphetamines]]), as well as with [[heroin]] and [[benzodiazepine]]s use, and can be considered as a bridge between the use of different groups of drugs.<ref>{{Cite book \| vauthors = Fehrman E, Egan V, Gorban AN, Levesley J, Mirkes EM, Muhammad AK \|date= 2019\|title= Personality Traits and Drug Consumption. A Story Told by Data\|doi= 10.1007/978-3-030-10442-9\|publisher= Springer, Cham\|isbn=978-3-030-10441-2 \|arxiv= 2001.06520 \|s2cid= 151160405}}</ref> ==== Insufflation ==== [[File:Cocaine lines 2.jpg\|thumb\|left\|Lines of cocaine prepared for snorting. [[Contaminated currency]] such as banknotes might serve as a [[fomite]] of diseases like hepatitis C<ref name="LV">{{cite web \|url=http://cocaine.org/cokemoney/banknotes.html \|title='Shared banknote' health warning to cocaine users \|access-date=26 July 2008 \| vauthors = Veevers L \|date=1 October 2006 \|work=The Observer }}</ref>]] Nasal [[insufflation (medicine)\|insufflation]] (known colloquially as "snorting", "sniffing", or "blowing") is a common method of ingestion of recreational powdered cocaine.<ref>{{Cite web\|title=DrugFacts: Cocaine\|url=https://www.drugabuse.gov/publications/drugfacts/cocaine\|publisher=National Institute on Drug Abuse\|access-date=11 July 2015\|date=April 2013\|url-status=live\|archive-url=https://web.archive.org/web/20150711234545/https://www.drugabuse.gov/publications/drugfacts/cocaine\|archive-date=11 July 2015}}</ref> The drug coats and is absorbed through the mucous membranes lining the [[nasal passages]]. Cocaine's desired euphoric effects are delayed when snorted through the nose by about five minutes. This occurs because cocaine's absorption is slowed by its constricting effect on the blood vessels of the nose.<ref name="Zimmerman_2012" /> Insufflation of cocaine also leads to the longest duration of its effects (60–90 minutes).<ref name="Zimmerman_2012" /> When insufflating cocaine, absorption through the nasal membranes is approximately 30–60%<ref>{{Cite web\|title=The Dangers Of Snorting Cocaine (Insufflation)\|url=https://vertavahealth.com/cocaine/insufflation/\|access-date=25 February 2022\|website=Vertava Health\|archive-date=8 April 2022\|archive-url=https://web.archive.org/web/20220408044303/https://vertavahealth.com/cocaine/insufflation/\|url-status=live}}</ref> [[Insufflation]] (known colloquially as “snorting," “sniffing," or "blowing") is the most common method of ingestion of recreational powder cocaine in the Western world. Contrary to widespread belief, cocaine is not actually inhaled using this method. The drug coats and is absorbed through the [[mucous membrane]]s lining the [[Paranasal sinus\|sinuses]]. When insufflating cocaine, absorption through the nasal membranes is approximately 30-60 percent, with higher doses leading to increased absorption efficiency. Any material not directly absorbed through the mucous membranes is collected in [[mucus]] and swallowed (this "drip" is considered pleasant by some and unpleasant by others). In a study<ref name="Volkow">{{cite journal ~~\| author = [[Nora D. Volkow]] ''et al.''~~ ~~\| title = Effects of route of administration on cocaine induced dopamine transporter blockade in the human brain~~ ~~\| pmid = 10983846~~ ~~\| year=2000~~ ~~\| journal = [[Life Sci.]]~~ ~~\| month = August~~ ~~\| volume = 67~~ ~~\| issue = 12~~ ~~\| pages = 1507-1515~~ }}</ref> of cocaine users, the average time taken to reach peak subjective effects was 14.6 minutes. Chronic use results in ongoing [[rhinitis]] and [[necrosis]] of the nasal membranes.{{fact}} Many users report a burning sensation in the nares (nostrils) after cocaine's anesthetic effects wear off. Any damage to the inside of the nose is because cocaine highly constricts blood vessels — and therefore blood & oxygen/nutrient flow-- to that area. If this restriction of adequate blood supply is severe enough and, especially prolonged enough, the tissue there can die.{{fact}} In a study of cocaine users, the average time taken to reach peak subjective effects was 14.6 minutes.<ref name="Volkow_2000">{{Cite journal \| vauthors = Volkow ND, Wang GJ, Fischman MW, Foltin R, Fowler JS, Franceschi D, Franceschi M, Logan J, Gatley SJ, Wong C, Ding YS, Hitzemann R, Pappas N \| title = Effects of route of administration on cocaine-induced dopamine transporter blockade in the human brain \| journal = Life Sciences \| volume = 67 \| issue = 12 \| pages = 1507–1515 \| date = August 2000 \| pmid = 10983846 \| doi = 10.1016/S0024-3205(00)00731-1 }}</ref> Any damage to the inside of the nose is due to cocaine constricting blood vessels—and therefore restricting blood and oxygen/nutrient flow—to that area, which, after chronic use, may cause "[[#Cocaine nose\|cocaine nose]]." Prior to insufflation, cocaine powder must be divided into very fine particles. Cocaine of high purity breaks into fine dust very easily, except when it is moist (not well stored) and forms “chunks,” which reduces the efficiency of nasal absorption. Most [[Contaminated currency\|banknotes have traces of cocaine]] on them; this has been confirmed by studies done in several countries.<ref>{{cite web \| vauthors = Mikkelson B \|url= http://www.snopes.com/business/money/cocaine.asp\|title=Drug Money \|date=9 July 2002 \|accessdate=2008-07-23 \|publisher=Snopes}}</ref> In 1994, the [[United States Court of Appeals for the Ninth Circuit\|U.S. 9th Circuit Court of Appeals]] cited findings that in Los Angeles, three out of four banknotes were tainted by cocaine or another illicit drug.<ref>{{cite news \| vauthors = Abrahamson A \|title=Prevalence of Drug-Tainted Money Voids Case Law: Court cites findings that more than 75% of currency in L.A. bears traces of cocaine or other illegal substances \|url=https://pqasb.pqarchiver.com/latimes/access/59564073.html?dids=59564073:59564073&FMT=ABS&FMTS=ABS:FT&type=current&date=Nov+13%2C+1994&author=ALAN+ABRAHAMSON&pub=Los+Angeles+Times+(pre-1997+Fulltext)&edition=&startpage=1&desc=Prevalence+of+Drug-Tainted+Money+Voids+Case+Law%3A+Court+cites+findings+that+more+than+75%25+of+currency+in+L.A.+bears+traces+of+cocaine+or+other+illegal+substances. \|work=Los Angeles Times \|date=13 November 1994 \|accessdate=2008-07-23 \|archive-date=2011-06-04 \|archive-url=https://web.archive.org/web/20110604092358/http://pqasb.pqarchiver.com/latimes/access/59564073.html?dids=59564073:59564073&FMT=ABS&FMTS=ABS:FT&type=current&date=Nov+13,+1994&author=ALAN+ABRAHAMSON&pub=Los+Angeles+Times+(pre-1997+Fulltext)&edition=&startpage=1&desc=Prevalence+of+Drug-Tainted+Money+Voids+Case+Law:+Court+cites+findings+that+more+than+75%+of+currency+in+L.A.+bears+traces+of+cocaine+or+other+illegal+substances. \|url-status=dead }}</ref><ref>{{cite news \| vauthors = Price DM \|title=Use of Drug-Sniffing Dogs Challenged;ACLU Backs Complaint by Men Whose Pocket Cash Was Seized \|url=https://pqasb.pqarchiver.com/washingtonpost/access/72586089.html?dids=72586089:72586089&FMT=ABS&FMTS=ABS:FT&date=May+6%2C+1990&author=Debbie+M.+Price&pub=The+Washington+Post+(pre-1997+Fulltext)&edition=&startpage=d.01&desc=Use+of+Drug-Sniffing+Dogs+Challenged%3BACLU+Backs+Complaint+by+Men+Whose+Pocket+Cash+Was+Seized \|archive-url=https://web.archive.org/web/20110604092431/http://pqasb.pqarchiver.com/washingtonpost/access/72586089.html?dids=72586089:72586089&FMT=ABS&FMTS=ABS:FT&date=May+6,+1990&author=Debbie+M.+Price&pub=The+Washington+Post+(pre-1997+Fulltext)&edition=&startpage=d.01&desc=Use+of+Drug-Sniffing+Dogs+Challenged%3BACLU+Backs+Complaint+by+Men+Whose+Pocket+Cash+Was+Seized \|url-status=dead \|archive-date=June 4, 2011 \|newspaper=The Washington Post \|date=6 May 1990 \|accessdate=2008-07-23 }}</ref> Rolled up [[currency\|banknotes]], hollowed-out [[pen]]s, cut [[drinking straw\|straw]]s, pointed ends of keys, and specialized [[cocaine spoon\|spoon]]s are often used to insufflate cocaine. Such devices are often called "tooters" by users. The cocaine typically is poured onto a flat, hard surface (such as a [[mirror]]) and divided into "lines" or "rails", and then insufflated. The amount of cocaine in a line varies widely from person to person and occasion to occasion (the purity of the cocaine is also a factor), but one line is generally considered to be a single dose and is typically 35mg-100mg. As tolerance builds rapidly in the short-term (hours), many lines are often snorted to produce greater effects. [[Snuff spoon]]s, hollowed-out [[pen]]s, cut [[drinking straw\|straws]], pointed ends of keys,<ref>{{Cite web \| vauthors = Rossen J \|date=19 March 2021\|title=Sniffing Around the History of the McDonald's 'Cocaine Spoon'\|url=https://www.mentalfloss.com/article/642413/mcdonalds-cocaine-spoon-controversy\|access-date=14 June 2021\|website=www.mentalfloss.com\|archive-date=8 July 2024\|archive-url=https://web.archive.org/web/20240708191807/https://www.mentalfloss.com/article/642413/mcdonalds-cocaine-spoon-controversy\|url-status=live}}</ref> long [[fingernails]] or [[artificial nails]], and (clean) [[tampon]] applicators are also used to insufflate cocaine. The cocaine typically is poured onto a flat, hard surface (such as a mobile phone screen, [[Plate (dishware)\|plate]], mirror, CD case or book) and divided into "bumps", "lines" or "rails", and then insufflated.<ref>{{Cite web \|url=https://www.cesar.umd.edu/cesar/drugs/cocaine.asp#Terminology \|title=Cocaine terminology \| work = Center for Substance use and Addiction Research – CESAR \| publisher = University of Maryland \|url-status=live \|archive-url=https://web.archive.org/web/20070709115212/https://www.cesar.umd.edu/cesar/drugs/cocaine.asp#Terminology \|archive-date=9 July 2007 }}</ref> A 2001 study reported that the sharing of straws used to "snort" cocaine can spread blood diseases such as [[hepatitis C]].<ref>{{Cite journal \| vauthors = Bonkovsky HL, Mehta S \| title = Hepatitis C: a review and update \| journal = Journal of the American Academy of Dermatology \| volume = 44 \| issue = 2 \| pages = 159–182 \| date = February 2001 \| pmid = 11174373 \| doi = 10.1067/mjd.2001.109311 }}</ref> ~~==== Injected ====~~ ===== Cocaine spoon ===== [[Drug injection]] provides the highest blood levels of drug in the shortest amount of time. Upon injection, cocaine reaches the brain in a matter of seconds, and the exhilarating rush that follows can be so intense that it induces some users to vomit uncontrollably. In a study<ref name="Volkow" /> of cocaine users, the average time taken to reach peak subjective effects was 3.1 minutes. The euphoria passes quickly. Aside from the toxic effects of cocaine, there is also danger of circulatory [[embolism\|emboli]] from the insoluble substances that may be used to cut the drug. There is also a risk of serious infection associated with the use of contaminated needles. [[File:Stopper, snuff bottle (AM 687402-2).jpg\|thumb\|Chinese snuff bottle stopper with a spoon]] Historically, [[snuff spoon]]s were used for cocaine in the 20th century, hence the names "cocaine spoon" and "coke spoon". Some local statutes in the US treat spoons that are too small and thus "unsuited for the typical, lawful uses of a spoon" as [[drug paraphernalia]].<ref>{{cite web \|title=Code of ordinances village of Dundee, Michigan. Chapter 51. \|url=https://library.municode.com/mi/dundee/codes/code_of_ordinances?nodeId=PTIICOOR_CH51DRARNUPR_ARTIDRPA_S51-1DE \|publisher=[[Dundee, Michigan\|Village of Dundee]]}}</ref><ref>{{Cite web \|title=Code of Ordinances{{snd}}Clark County, NV \|url=https://library.municode.com/nv/clark_county/codes/code_of_ordinances?nodeId=TIT12PUPESAMO_CH12.06DRPA \|archive-url=https://web.archive.org/web/20240913094223/https://library.municode.com/nv/clark_county/codes/code_of_ordinances?nodeId=TIT12PUPESAMO_CH12.06DRPA \|archive-date=2024-09-13 \|access-date=2024-09-13 \|website=Municode Library}}</ref><ref>{{Cite web \|title=Township of Middlesex, PA Drugs and Drug Paraphernalia \|url=https://ecode360.com/11231035#11231037 \|archive-url=https://web.archive.org/web/20240913094426/https://ecode360.com/11231035#11231037 \|archive-date=2024-09-13 \|access-date=2024-09-13 \|website=eCode360}}</ref> An injected mixture of cocaine and [[heroin]], known as “[[speedball (drug)\|speedball]]” or “moonrock”, is a particularly popular and dangerous combination, as the converse effects of the drugs actually complement each other, but may also mask the symptoms of an overdose. It has been responsible for numerous deaths, particularly in and around [[Los Angeles]], including celebrities such as [[John Belushi]], [[Chris Farley]] (in [[Chicago)]], [[River Phoenix]] and [[Layne Staley]] (in Seattle). ==== Injection ==== Experimentally, cocaine injections can be delivered to animals such as fruit flies to study the mechanisms of cocaine addiction.<ref>{{Cite journal\|author=Dimitrijevic N, Dzitoyeva S, Manev H\|title=An automated assay of the behavioral effects of cocaine injections in adult Drosophila\|journal=J Neurosci Methods\|year=2004\|month=August\|volume=137\|issue=2\|pages=181–184\|url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=15262059&query_hl=21\|curly=1}}</ref> Subjective effects not commonly shared with other methods of administration include a ringing in the ears moments after injection (usually when over 120 milligrams) lasting 2 to 5 minutes including [[tinnitus]] and audio distortion. This is colloquially referred to as a "bell ringer". In a study of cocaine users, the average time taken to reach peak subjective effects was 3.1 minutes.<ref name="Volkow_2000" /> The euphoria passes quickly. Aside from the toxic effects of cocaine, there is also the danger of circulatory [[embolism\|emboli]] from the insoluble substances that may be used to cut the drug. As with all injected [[illicit substances]], there is a risk of the user contracting [[Blood-borne disease\|blood-borne infections]] if sterile injecting equipment is not available or used. ==== ~~Smoked~~Inhalation ==== ~~: ''See also: [[Cocaine#Crack cocaine\|crack cocaine]] above.''~~ ===== Cocaine paste ===== Smoking freebase or crack cocaine is most often accomplished using a pipe made from a small glass tube about one quarter-inch (about 6 mm) in diameter and on the average, four inches long. These are sometimes called "stems", "horns", "blasters" and "straight shooters," readily available in convenience stores or smoke shops. They will sometimes contain a small paper flower and are promoted as a romantic gift. Buyers usually ask for a "rose" or a "flower." An alternate method is to use a small length of a radio antenna or similar metal tube. To avoid burning the user's fingers and lips on the metal pipe, a small piece of paper or cardboard (such as a piece torn from a matchbook cover) is wrapped around one end of the pipe and held in place with either a rubber band or a piece of adhesive tape. A popular (usually pejorative) term for crack pipes is "glass dick." Tire pressure gauges have also been used by breaking off their tops and removing their numbered sticks. These can be purchased at most convenience stores or gas stations. {{Main\|Cocaine paste}} [[Coca paste]] (paco, basuco, oxi, pasta) is a crude [[extract]] of the [[coca leaf]] which contains 40% to 91% [[cocaine freebase]] along with companion coca alkaloids and varying quantities of [[benzoic acid]], [[methanol]], and [[kerosene]]. The caustic reactions associated with the local application of coca paste prevents its use by oral, intranasal, mucosal, intramuscular, intravenous or subcutaneous routes. Coca paste can only be smoked when combined with a combustible material such as tobacco or cannabis.<ref name="Arif_1987">{{cite book \| veditors = Arif A \| title=Adverse health consequences of cocaine abuse \| ___location = Geneva \| publisher=World Health Organization \| year=1987 \| url=http://apps.who.int/iris/bitstream/10665/37270/1/9241561076.pdf}}</ref> A small piece (approximately one inch) of heavy steel or stainless steel scouring pad (copper is never used as it can make the lungs bleed)—often called a [[Brillo Pad\|"brillo"]] or [[Chore Boy\|"chore"]], from the scouring pads of the same name—is placed into one end of the tube and carefully packed down to approximately three-quarter inch. Prior to insertion, the "brillo" is burnt off to remove any oily coatings that may be present. It then serves as a reduction base and flow modulator in which the "rock" can be melt and boiled to vapor. [[Stainless steel]] television cable are also used, with its metal acting as a screen. Crude cocaine preparation intermediates are marketed as cheaper alternatives to pure cocaine to local markets while the more expensive end product is exported to United States and European markets. [[Freebase cocaine]] paste preparations can be smoked. The psychological and physiological effects of the ''paco'' are quite severe.<ref name="Jeri_1984">{{cite journal \| vauthors = Jeri F \| title = Coca-paste smoking in some Latin American countries: a severe and unabated form of addiction \| journal = Bulletin on Narcotics \| volume = 36 \| issue = 2 \| year = 1984 }}</ref><ref name="Phillips_2009">{{cite journal \| vauthors = Phillips K, Luk A, Soor GS, Abraham JR, Leong S, Butany DJ \| title = Cocaine Cardiotoxicity \| journal = American Journal of Cardiovascular Drugs: Drugs, Devices, and Other Interventions \| volume = 9 \| issue = 3 \| pages = 177–196 \| date = June 2009 \| pmid = 19463023 \| doi = 10.1007/bf03256574 \| s2cid = 70385136 }}</ref> Media usually report that it is extremely toxic and addictive.<ref name="Mcdonnell_2007">{{cite web \| vauthors = Mcdonnell PJ \| title = Argentina confronts plague named Paco \| date = 2007-05-25 \| url = https://www.latimes.com/archives/la-xpm-2007-may-25-fg-paco25-story.html \| work = Los Angeles Times \| access-date = 2009-04-05 }}</ref><ref name="Legrand_2009">{{cite news \| vauthors = Legrand C \| title = En Argentine, des mères se mobilisent contre le "paco", la drogue des pauvres – Amériques \| date = 2009-03-26 \| url = http://www.lemonde.fr/ameriques/article/2009/03/26/en-argentine-des-meres-se-mobilisent-contre-le-paco-la-drogue-des-pauvres_1172844_3222.html#ens_id=1170226 \| newspaper = Le Monde.fr \| accessdate = 2009-04-05 }}</ref><ref name="Navai_2008">{{cite news \| vauthors = Navai R \| title = Cocaine's lethal leftovers take violent grip on slum children \| ___location = London \| date = 2008-04-28 \| url = http://www.timesonline.co.uk/tol/news/world/us_and_americas/article3828309.ece \| archive-url = https://web.archive.org/web/20080726120712/http://www.timesonline.co.uk/tol/news/world/us_and_americas/article3828309.ece \| url-status = dead \| archive-date = 26 July 2008 \| work = The Times \| accessdate = 2009-04-05 }} {{Registration required}}</ref> According to a study by Intercambios, media appear to exaggerate the effects of ''paco''. These stereotypes create a sense that nothing can be done to help a ''paco'' addict and thus stand in the way of rehabilitation programs.<ref>{{cite web \| vauthors = Valente M \| title = DRUGS-ARGENTINA: 'Pasta Base' Destructive but Not Invincible \| date = 2006-09-12 \| url = http://ipsnews.net/news.asp?idnews=34692 \| publisher = Ipsnews.net \| accessdate = 2009-04-05 \| archive-url = https://web.archive.org/web/20090213162639/http://www.ipsnews.net/news.asp?idnews=34692 \| archive-date = 2009-02-13 \| url-status = dead }}</ref> Another method is to use a deep socket, typically 12mm, wrapped with electrical tape. Instead of [[Chore Boy]], users typically employ high grade (very fine) [[speaker wire]] rolled into a ball as the filter medium. A [[Zippo]] lighter is often used because of its stronger flame, but the taste of [[naphtha]] is quite noticeable. However, the socket is practically indestructible and inconspicuous. ===== Crack cocaine ===== A less sophisticated but common method is to use a discarded [[soda can]] and puncture several small holes on the side of the can near its bottom. [[Tobacco]] ash is then placed in the divot created with the drug placed on top. The mouthpiece is the original opening of the can, creating a cost-effective alternative to a proper crack pipe. {{Further\|Crack cocaine}} [[File:Man smoking crack cocaine in Bogotá, Colombia..jpg\|thumb\|Man smoking crack cocaine in Bogotá, Colombia]] To smoke the "rock" it is placed at the end of the pipe, closest to the filter. The other end is then placed in the user's mouth and a flame from a [[cigarette lighter]] or hand-held [[torch]] is held under the "rock". As the "rock" is heated, it melts and burns away to vapor, which the user inhales as smoke. Powder cocaine (cocaine hydrochloride) must be heated to a high temperature (about 197 °C), and considerable decomposition/burning occurs at these high temperatures. This effectively destroys some of the cocaine and yields a sharp, acrid, and foul-tasting smoke. Cocaine base/crack can be smoked because it vaporizes with little or no decomposition at {{convert\|98\|°C\|0\|abbr=on}},<ref>{{Cite book \| vauthors = Ries RK, Miller SC, Fiellin DA \|title=Principles of addiction medicine \|url=https://books.google.com/books?id=j6GGBud8DXcC&pg=PT166 \|access-date=5 January 2014 \|year=2009 \|publisher=[[Lippincott Williams & Wilkins]] \|isbn=978-0-7817-7477-2 \|page=137 \|url-status=live \|archive-url=https://web.archive.org/web/20140404151454/https://books.google.com/books?id=j6GGBud8DXcC&pg=PT166 \|archive-date=4 April 2014 }}</ref> which is below the boiling point of water. The effects, felt almost immediately after smoking, are very intense and do not last long—usually five to fifteen minutes. In a study<ref name="Volkow" /> performed on crack cocaine users, the average time taken for them to reach their peak subjective "high" was 1.4 minutes. Most (especially frequent) users crave more immediately after the peak. "[[Crack house]]s" depend on these cravings by providing a place for smoking crack to its users, and a ready supply of small bags for sale. ==Contraindications== A heavily-used crack pipe tends to fracture at its end due to overheating from the flame used to heat the crack, typically because users attempt to inhale every last bit of the drug on the metal wool filter. The end is often broken further as users "push" the pipe. "Pushing" is a technique used to partially recover crack that hardens on the inside wall of the pipe as the pipe cools. This is accomplished by pushing the metal wool filter through the pipe from one end to the other in order to collect the build-up inside the pipe, which is a very pure and potent form of the base. The ends of the pipe can be broken by the object used to push the filter—frequently a small screwdriver or stiff piece of wire. Users will often remove the most jagged edges and continue using the pipe until it becomes so short that it burns their lips and fingers. To continue using the pipe, users will sometimes wrap a small piece of paper or cardboard around its one end and hold it in place with a rubber band or adhesive tape. Of course, not all crack cocaine users will allow it to get that short, and will instead opt for a new or different pipe. The telltale signs of a used crack pipe are a glass tube with burn marks at one or both ends and a clump of metal wool inside. The language referring to paraphernalia and practices of smoking cocaine vary across the United States, as do the packaging methods in the street level sale. {{For\|harm caused by the freebase form\|Crack cocaine#Contraindications}} Cocaine should not be used in individuals with a known allergy or [[hypersensitivity]] to the drug or any components of its topical formulation. It is also contraindicated in [[Geriatrics\|elderly patients]] and those with a history of hypertension or [[cardiovascular disease]].<ref name="Richards_2023">{{cite book \| vauthors = Richards JR, Laurin EG \| chapter = Cocaine \| date = June 2023 \| title = StatPearls [Internet]. \| ___location = Treasure Island (FL) \| publisher = StatPearls Publishing \| pmid=28613520}}</ref> When smoked, cocaine is sometimes combined with other drugs, such as [[cannabis (drug)\|cannabis]]; often rolled into a joint or [[Blunt (drug culture)\|blunt]]. This combination is known as "[[primo]]", "chronic", "hype", "shake and bake", a "turbo", a "yolabowla", "SnowCaps", "Canadian Health Care", "B-51er", a "cocoapuff", a "dirty", a "woo", or "geeking." Crack smokers who are being drug tested may also make their "primo" with cigarette tobacco instead of cannabis, since a crack smoker can test clean within two to three days of use, if only urine (and not hair) is being tested. ===Pregnancy=== Powder cocaine is sometimes smoked, but it is inefficient as the heat involved destroys much of the chemical. One way of smoking powder is to put a "bump" into the end of an unlit cigarette, smoking it in one go as the user lights the cigarette normally. This cigarette is then referred to as a "Jimmy". Alternatively, cocaine powder may be sprinkled onto the marijuana in a blunt or possibly a joint and then smoked. This is known as a "Chewy" or may also be referred to by one of the names mentioned above for crack-laced marijuana. When a marijuana [[Bowl (drug culture)\|bowl]] is laced with cocaine powder, it is often refered to as a "SnowCap" because the marijuana is "capped" with cocaine on top. {{Main\|Prenatal cocaine exposure\|Teratology#Cocaine}} [[Prenatal cocaine exposure]] (PCE) may occur when a pregnant woman uses cocaine.<ref name="Buckingham-Howes_2013">{{cite journal \| vauthors = Buckingham-Howes S, Berger SS, Scaletti LA, Black MM \| title = Systematic Review of Prenatal Cocaine Exposure and Adolescent Development \| journal = Pediatrics \| volume = 131 \| issue = 6 \| pages = e1917–e1936 \| date = 2013 \| pmid = 23713107 \| pmc = 3666107 \| doi = 10.1542/peds.2012-0945 }}</ref><ref name="Lambert_2012">{{cite journal \| vauthors = Lambert B, Bauer C \| title = Developmental and behavioral consequences of prenatal cocaine exposure: a review \| journal = Journal of Perinatology \| volume = 32 \| issue = 11 \| pages = 819–828 \| date = November 2012 \| pmid = 22791278 \| pmc = 4143247 \| doi = 10.1038/jp.2012.90 }}</ref><ref name="McCarthy_2014">{{cite book \| vauthors = McCarthy DM, Kabir ZD, Bhide PG, Kosofsky BE \| chapter = Effects of prenatal exposure to cocaine on brain structure and function \| title = Progress in Brain Research \| volume = 211 \| pages = 277–289 \| year = 2014 \| pmid = 24968785 \| doi = 10.1016/B978-0-444-63425-2.00012-X \| isbn = 978-0-444-63425-2 }}</ref><ref name="Eiden_2009">{{cite journal \| vauthors = Eiden RD, McAuliffe S, Kachadourian L, Coles C, Colder C, Schuetze P \| title = Effects of prenatal cocaine exposure on infant reactivity and regulation \| journal = Neurotoxicology and Teratology \| volume = 31 \| issue = 1 \| pages = 60–68 \| date = January 2009 \| pmid = 18822371 \| pmc = 2631277 \| doi = 10.1016/j.ntt.2008.08.005 \| bibcode = 2009NTxT...31...60E }}</ref> ~~==== Coca leaf infusions ====~~ Under the former FDA [[pregnancy category]] system, cocaine was classified as a Category C drug. Its potential to cause harm to the fetus is not fully known, so it should only be administered to pregnant women if clearly necessary.<ref name="Richards_2023" /> Coca herbal [[infusion]] (also referred to as coca tea) is used in coca-leaf producing countries much as any herbal medicinal infusion would elsewhere in the world. The free and legal commercialization of dried coca leaves under the form of filtration bags to be used as "coca tea" has been actively promoted by the governments of [[Peru]] and [[Bolivia]] for many years as a drink having medicinal powers. Visitors to the city of [[Cuzco]] in Peru, and [[La Paz]] in Bolivia are greeted with the offering of coca leaf infusions (prepared in tea pots with whole coca leaves) purportedly to help the newly-arrived traveler overcome the malaise of high altitude sickness. The effects of drinking coca tea are a mild stimulation and mood lift. It does not produce any significant numbing of the mouth nor does it give a rush like snorting cocaine. In order to prevent the demonization of this product, its promoters publicize the unproven concept that much of the effect of the ingestion of coca leaf infusion would come from the secondary alkaloids, as being not only quantitatively different from pure cocaine but also qualitatively different. Cocaine can act as a [[teratogen]], having various effects on the developing fetus.<ref name="ASU">{{Cite encyclopedia \|title=Cocaine as a Teratogen \| encyclopedia = Embryo Project Encyclopedia \|url=https://embryo.asu.edu/pages/cocaine-teratogen \|access-date=2025-04-07 \| publisher = Arizona State University \|language=en}}</ref> Some common teratogenic defects caused by cocaine include [[hydronephrosis]], [[Cleft lip and cleft palate\|cleft palate]], [[polydactyly]], and [[down syndrome]].<ref name="ASU" /> Cocaine as a drug has a low molecular weight and high water and lipid solubility which enables it to cross the [[placenta]] and fetal blood-brain barrier.<ref>{{cite journal \| vauthors = Singer L, Arendt R, Minnes S \| title = Neurodevelopmental effects of cocaine \| journal = Clinics in Perinatology \| volume = 20 \| issue = 1 \| pages = 245–262 \| date = March 1993 \| pmid = 8458168 \| pmc = 4181371 \| doi = 10.1016/S0095-5108(18)30422-6 }}</ref> Because cocaine is able to pass through the placenta and enter the fetus, the fetus' circulation can be negatively affected. With restriction of fetal circulation, the development of organs in the fetus can be impacted, even resulting in [[Gastroschisis\|intestines developing outside]] of the fetus' body.<ref name="ASU" /> Cocaine use during pregnancy can also result in [[obstetric labor complication]]s such as, [[placental abruption]],<ref>{{cite journal \| vauthors = Flowers D, Clark JF, Westney LS \| title = Cocaine intoxication associated with abruptio placentae \| journal = Journal of the National Medical Association \| volume = 83 \| issue = 3 \| pages = 230–232 \| date = March 1991 \| pmid = 2038082 \| pmc = 2627035 }}</ref> [[preterm birth]] or delivery, [[uterine rupture]], [[miscarriage]], and [[stillbirth]].<ref name="ASU" /><ref>{{cite journal \| vauthors = Cain MA, Bornick P, Whiteman V \| title = The maternal, fetal, and neonatal effects of cocaine exposure in pregnancy \| journal = Clinical Obstetrics and Gynecology \| volume = 56 \| issue = 1 \| pages = 124–132 \| date = March 2013 \| pmid = 23314714 \| doi = 10.1097/GRF.0b013e31827ae167 }}</ref> Prenatal cocaine exposure may cause subtle cognitive deficits and lower the chance of above-average IQ by age 4, but supportive caregiving can significantly improve outcomes.<ref>{{cite journal \| vauthors = Singer LT, Minnes S, Short E, Arendt R, Farkas K, Lewis B, Klein N, Russ S, Min MO, Kirchner HL \| title = Cognitive outcomes of preschool children with prenatal cocaine exposure \| journal = JAMA \| volume = 291 \| issue = 20 \| pages = 2448–2456 \| date = May 2004 \| pmid = 15161895 \| pmc = 1901972 \| doi = 10.1001/jama.291.20.2448 }}</ref> It has been promoted as an adjuvant for the treatment of cocaine dependence. In one controversial study, coca leaf infusion was used -in addition to counseling- to treat 23 addicted coca-paste smokers in [[Lima]], [[Peru]]. Relapses fell from an average of four times per month before treatment with coca tea to one during the treatment. The duration of abstinence increased from an average of 32 days prior to treatment to 217 days during treatment. These results suggest that the administration of coca leaf infusion plus counseling would be an effective method for preventing relapse during treatment for cocaine addiction.<ref>{{cite journal\|author=Teobaldo, Llosa\|title=The Standard Low Dose of Oral Cocaine: Used for Treatment of Cocaine Dependence\|journal=Substance Abuse\|year=1994\|volume=15\|issue=4\|pages=215–220\|curly=true}}</ref> Importantly, these results also suggest strongly that the primary pharmacologically active metabolite in coca leaf infusions is actually cocaine and not the secondary alkaloids. ===Breastfeeding=== ~~The cocaine metabolite [[benzoylecgonine]] can be detected in the urine of people a few hours after drinking one cup of coca leaf infusion.~~ Mothers utilizing recreational drugs, such as cocaine, methamphetamines, PCP, and heroin, should not [[Breastfeeding\|breastfeed]].<ref name="CDC-2021e">{{cite web \|date=10 August 2021\|title=When breastfeeding or feeding expressed milk is not recommended.\|url=https://www.cdc.gov/breastfeeding/breastfeeding-special-circumstances/contraindications-to-breastfeeding.html\|access-date=14 November 2021\|website=Centers for Disease Control and Prevention\|language=en-us}}</ref><ref name="Eglash_2020">{{cite book\| title=The Little Green Book of Breastfeeding Management for Physicians & Other Healthcare Providers\| vauthors= Eglash A, Leeper K\| publisher=The Institute for the Advancement of Breastfeeding and Lactation Education\| year=2020\|isbn=978-0-9987789-0-7\|edition=7\|___location=Madison, WI}}</ref>{{rp\|13}} The [[March of Dimes]] said "it is likely that cocaine will reach the baby through breast milk," and advises the following regarding cocaine use during pregnancy: ~~==== Oral ====~~ {{Blockquote\|Cocaine use during pregnancy can affect a pregnant woman and her unborn baby in many ways. During the early months of pregnancy, it may increase the risk of [[miscarriage]]. Later in pregnancy, it can trigger [[Preterm birth\|preterm labor]] (labor that occurs before 37 weeks of pregnancy) or cause the baby to grow poorly. As a result, cocaine-exposed babies are more likely than unexposed babies to be born with [[low birth weight]] (less than {{convert\|5.5\|lb\|kg\|disp=or\|abbr=on}}). Low-birthweight babies are 20 times more likely to die in their first month of life than normal-weight babies, and face an increased risk of [[developmental disability\|lifelong disabilities]] such as mental retardation and [[cerebral palsy]]. Cocaine-exposed babies also tend to have smaller heads, which generally reflect smaller brains. Some studies suggest that cocaine-exposed babies are at increased risk of birth defects, including urinary tract defects and, possibly, heart defects. Cocaine also may cause an unborn baby to have a [[stroke]], irreversible [[brain injury]], or a [[myocardial infarction]].<ref name="mod">{{Cite web \|url=http://www.marchofdimes.org/pregnancy/illicit-drug-use-during-pregnancy.aspx \|title=Street Drugs and pregnancy \|work=March of Dimes \|access-date=26 May 2009 \|archive-date=5 September 2015 \|archive-url=https://web.archive.org/web/20150905080845/http://www.marchofdimes.org/pregnancy/illicit-drug-use-during-pregnancy.aspx \|url-status=dead }}</ref>}} == Adverse effects == Cocaine has been used medically and informally as an oral anesthetic. Many users rub the powder along the gum line, or onto a cigarette filter which is then smoked, which numbs the gums and teeth - hence the colloquial names of "numbies," or "gummy," for this type of administration. This is commonly done with the small amounts of cocaine remaining on a surface after insufflation. Another oral method is to wrap up some cocaine in rolling paper and swallow it. This is called "parachuting". {{For\|harm caused by the freebase form\|Crack cocaine#Adverse effects}} {{See also\|Cocaine#Lacing}} {{Gallery ~~=== Physical mechanisms ===~~ \| title = \| align = \| footer = \| style = \| state = \| height = \| width = 400 \| perrow = \| mode = \| whitebg = \| noborder = \| captionstyle = \| HarmCausedByDrugsTable.svg \| A 2010 study ranking various illegal and legal drugs based on statements by drug-harm experts in the UK. Crack cocaine and cocaine were found to be the third and fifth overall most dangerous drugs respectively.<ref>{{Cite journal \| vauthors = Nutt DJ, King LA, Phillips LD \| title = Drug harms in the UK: a multicriteria decision analysis \| journal = Lancet \| volume = 376 \| issue = 9752 \| pages = 1558–65 \| date = November 2010 \| pmid = 21036393 \| doi = 10.1016/S0140-6736(10)61462-6 \| s2cid = 5667719 \| citeseerx = 10.1.1.690.1283 }}</ref> \| Rational harm assessment of drugs bar plot.svg \| 2007 [[Delphi method\|delphic analysis]] regarding 20 popular recreational drugs based on expert opinion in the UK. Cocaine was ranked the 2nd in dependence and physical harm and 3rd in social harm.<ref name="Nutt_2007">{{Cite journal\|vauthors = Nutt D, King LA, Saulsbury W, Blakemore C\|title = Development of a rational scale to assess the harm of drugs of potential misuse\|journal = Lancet\|volume = 369\|issue = 9566\|pages = 1047–53\|date = March 2007\|pmid = 17382831\|doi = 10.1016/S0140-6736(07)60464-4\|s2cid = 5903121\|author-link4 = Colin Blakemore\|author-link1 = David Nutt }}</ref> }} === Cardiac complications === The pharmacodynamics of cocaine are complex. One significant effect of cocaine on the [[central nervous system]] is the blockage of the [[dopamine transporter]] protein (DAT). Dopamine [[transmitter]] released during neural signaling is normally recycled via the transporter; i.e., the transporter binds the transmitter and pumps it out of the synaptic cleft back into the pre-synaptic neuron, where it is taken up into storage [[Vesicle (biology)\|vesicle]]s. Cocaine binds tightly at the DAT forming a complex that blocks the transporter's function. The DAT can no longer perform its reuptake function, and thus [[dopamine]] accumulates in the extracellular space (synaptic cleft). This results in an enhanced and prolonged post-synaptic effect of dopaminergic signalling at dopamine receptors on the receiving neuron. Prolonged exposure to cocaine, as occurs with habitual use, leads to homeostatic dysregulation of normal (i.e., without cocaine) dopaminergic signaling via downregulation of D1 receptors and enhanced [[signal transduction]]. The decreased dopaminergic signalling after chronic cocaine use may contribute to depressive mood disorders and sensitize this important brain reward circuit to the reinforcing effects of cocaine (e.g., enhanced dopaminergic signalling only when cocaine is self-administered). This sensitization contributes to the intractable nature of addiction and relapse. Cocaine use can cause serious heart problems like sudden death, heart inflammation, [[Arrhythmia\|arrhythmias]], and heart attacks. It triggers coronary artery spasms, increases blood clot risk, and accelerates [[atherosclerosis]], especially with long-term use. The severity of heart disease often relates to how long and how often cocaine is used.<ref>{{cite journal \| vauthors = Talarico GP, Crosta ML, Giannico MB, Summaria F, Calò L, Patrizi R \| title = Cocaine and coronary artery diseases: a systematic review of the literature \| journal = Journal of Cardiovascular Medicine \| volume = 18 \| issue = 5 \| pages = 291–294 \| date = May 2017 \| pmid = 28306693 \| doi = 10.2459/JCM.0000000000000511 }}</ref> It can also become a serious risk at high doses due to cocaine's blocking effect on cardiac sodium channels.<ref name="O'Leary_2010" /> ===Levamisole syndromes=== Dopamine-rich brain regions such as the ventral tegmental area (VTA), [[nucleus accumbens]] (nAC), and prefrontal [[Cerebral cortex\|cortex]] (PFC) are frequent targets of cocaine addiction research. Of particular interest is the pathway consisting of dopaminergic neurons originating in the VTA that terminate in the nAC. This projection functions as a "reward center" in that it shows activation is response to drugs of abuse like cocaine in addition to natural rewards like food or sex (R Spanagel and F Weiss, The dopamine hypothesis of reward: past and current status. Trends Neurosci 22 (1999), pp. 521–527). While the precise role of DA in the subjective experience of reward is controversial among neuroscientists, the release of DA in the nAC is widely considered to be responsible for cocaine's rewarding effects. This conclusion is largely based on laboratory data involving rats that are trained to self-administer cocaine intravenously (i.v.). If DA antagonists are infused directly into the nAC, well-trained rats self-administering cocaine will undergo extinction (i.e., initially increase responding only to stop completely) thereby indicating that cocaine is no longer reinforcing (i.e., rewarding) the drug-seeking behavior. <!-- which of these are the pleasure centers? --> [[Levamisole]] is one of the most common adulterants found in illicit cocaine, with studies showing that between 2009 and 2016, 50–70% of all cocaine specimens worldwide contained levamisole, reflecting similar high rates of contamination across North America and Europe.<ref name="Vonmoos_2018">{{cite journal \| vauthors = Vonmoos M, Hirsiger S, Preller KH, Hulka LM, Allemann D, Herdener M, Baumgartner MR, Quednow BB \| title = Cognitive and neuroanatomical impairments associated with chronic exposure to levamisole-contaminated cocaine \| journal = Translational Psychiatry \| volume = 8 \| issue = 1 \| article-number = 235 \| date = October 2018 \| pmid = 30368522 \| pmc = 6204136 \| doi = 10.1038/s41398-018-0279-3 }}</ref> Before trafficking to the United States, the cocaine is frequently adulterated with levamisole.<ref name="Buchanan_2010">{{cite journal \| vauthors = Buchanan JA, Oyer RJ, Patel NR, Jacquet GA, Bornikova L, Thienelt C, Shriver DA, Shockley LW, Wilson ML, Hurlbut KM, Lavonas EJ \| title = A confirmed case of agranulocytosis after use of cocaine contaminated with levamisole \| journal = Journal of Medical Toxicology \| volume = 6 \| issue = 2 \| pages = 160–164 \| date = June 2010 \| pmid = 20358411 \| pmc = 3550277 \| doi = 10.1007/s13181-010-0060-3 }}</ref> By October 2017, this figure had risen further, with the DEA reporting that 87% of seized and analyzed cocaine bricks in the United States contained levamisole, making it the most common adulterant in cocaine at that time.<ref name="DIR-040-17_2017-NDTA.pdf">{{cite web \|title=2017 National Drug Threat Assessment \|url=https://www.dea.gov/sites/default/files/2018-07/DIR-040-17_2017-NDTA.pdf \|publisher= Drug Enforcement Administration \|date=1 October 2017 \|access-date= 17 June 2025}}</ref> In the body, levamisole is converted into [[aminorex]], a substance with [[amphetamine]]-like stimulant effects and a long duration of action.<ref>{{cite journal \| vauthors = Solomon N, Hayes J \| title = Levamisole: A High Performance Cutting Agent \| journal = Academic Forensic Pathology \| volume = 7 \| issue = 3 \| pages = 469–476 \| date = September 2017 \| pmid = 31239995 \| pmc = 6474566 \| doi = 10.23907/2017.039 }}</ref> Levamisole-adulterated cocaine is associated with cocaine- and levamisole-induced [[vasculitis]] (CLIV) and cocaine/levamisole-associated [[autoimmune disease\|autoimmune syndrome]] (CLAAS).<ref name="Gill_2021" /><ref name="Cascio_2018" /> [[List of reagent testing color charts\|Reagent testing kits]] can be used to detect the presence of cocaine and levamisole.<ref name="DS_Instructions_Reagents_v17Spring24.pdf">{{cite web \| title = How to Test Your Drugs With Reagents\| work = DanceSafe \|url=https://dancesafe.org/wp-content/uploads/2024/05/DS_Instructions_Reagents_v17Spring24.pdf}}</ref> Cocaine is also a less potent blocker of the [[monoamine transporter\|norepinephrine transporter]] (NET) and [[serotonin transporter]] (SERT). Cocaine also blocks [[ion channel\|sodium channels]], thereby interfering with the propagation of [[action potential]]s; thus, like [[lignocaine]] and [[novocaine]], it acts as a local anesthetic. Cocaine also causes [[vasoconstriction]], thus reducing bleeding during minor surgical procedures. The locomotor enhancing properties of cocaine may be attributable to its enhancement of dopaminergic transmission from the [[substantia nigra]]. Recent research points to an important role of circadian mechanisms<ref>{{cite journal \| author = Uz T, Akhisaroglu M, Ahmed R, Manev H \| title = The pineal gland is critical for circadian Period1 expression in the striatum and for circadian cocaine sensitization in mice. \| journal = Neuropsychopharmacology \| volume = 28 \| issue = 12 \| pages = 2117-23 \| year = 2003 \| id = PMID 12865893}}</ref> and clock genes<ref>{{cite journal \| author = McClung C, Sidiropoulou K, Vitaterna M, Takahashi J, White F, Cooper D, Nestler E \| title = Regulation of dopaminergic transmission and cocaine reward by the Clock gene. \| journal = Proc Natl Acad Sci U S A \| volume = 102 \| issue = 26 \| pages = 9377-81 \| year = 2005 \| id = PMID 15967985}}</ref> in behavioral actions of cocaine. ====Levamisole-induced necrosis syndrome==== Because [[nicotine]] increases the levels of dopamine in the brain, many cocaine users find that consumption of [[tobacco]] products during cocaine use enhances the euphoria. This, however, may have undesirable consequences, such as uncontrollable [[chain smoking]] during cocaine use (even users who don't normally smoke [[cigarettes]] have been known to chain smoke when using cocaine), in addition to the detrimental health effects and the additional strain on the cardiovascular system caused by tobacco. {{Main\|Levamisole-induced necrosis syndrome}} [[Levamisole-induced necrosis syndrome]] (LINES) is a complication characterized by [[necrosis]] resulting from exposure to [[levamisole]], a medication with immunomodulatory properties. While LINES can occur with levamisole use alone, most reported cases are associated with the use of cocaine adulterated with levamisole as a cutting agent. This syndrome is marked by skin necrosis, often affecting areas such as the ears, face, and extremities, and is thought to result from levamisole’s effects on blood vessels and the immune system.<ref>{{cite journal \| vauthors = Fredericks C, Yon JR, Alex G, Morton M, Messer T, Bokhari F, Poulakidas S \| title = Levamisole-induced Necrosis Syndrome: Presentation and Management \| journal = Wounds \| volume = 29 \| issue = 3 \| pages = 71–76 \| date = March 2017 \| pmid = 28355139 }}</ref> In addition to irritability, mood disturbances, restlessness, paranoia, and auditory hallucinations, crack can cause several dangerous physical conditions. It can lead to disturbances in heart rhythm and heart attacks, as well as chest pains or even respiratory failure. In addition, strokes, seizures and headaches are common in heavy users. ====Cocaine/levamisole-associated syndromes==== ~~Cocaine can often cause reduced food intake, many chronic users lose their appetite and can experience severe malnourishment and significant weight loss.~~ The skin necrosis associated with levamisole toxicity ranges from [[leukocytoclastic vasculitis]] to occlusive [[vasculopathy]]. Several cases of severe agranulocytosis associated with cocaine use have been reported since 2006. With the recently recognized dermal disease, the face and ears are commonly affected, especially the bilateral [[helix (ear)\|helices]] and cheeks. However, there have also been case reports of involvement of the abdomen, chest, lower buttocks and legs.<ref name="Morris_2012">{{cite journal \| vauthors = Morris GW, Mason BC, Harris Sprunger R, Hake Harris H, White LA, Patterson DA \| title = Levamisole-adulterated cocaine: a case series \| journal = Journal of the American Board of Family Medicine \| volume = 25 \| issue = 4 \| pages = 531–535 \| year = 2012 \| pmid = 22773722 \| doi = 10.3122/jabfm.2012.04.110287 \| doi-access = free }}</ref><ref name="lee2012">{{cite journal \| vauthors = Lee KC, Ladizinski B, Federman DG \| title = Complications associated with use of levamisole-contaminated cocaine: an emerging public health challenge \| journal = Mayo Clinic Proceedings \| volume = 87 \| issue = 6 \| pages = 581–586 \| date = June 2012 \| pmid = 22677078 \| pmc = 3498128 \| doi = 10.1016/j.mayocp.2012.03.010 }}</ref> During the mid-2010s, levamisole was found in most cocaine products available in both the United States and Europe.<ref>{{cite web \|title=Cocaine retail markets: multiple indicators suggest continued growth and diversification {{!}} www.euda.europa.eu \|url=https://www.euda.europa.eu/publications/eu-drug-markets/cocaine/retail-markets_en \|website=www.euda.europa.eu}}</ref> Levamisole is known to cause an acute condition involving a severe and dangerous lowered white blood cell count, known as [[agranulocytosis]], in cocaine users, and may also accentuate cocaine's effects.<ref>{{cite journal \| vauthors = Chang A, Osterloh J, Thomas J \| title = Levamisole: a dangerous new cocaine adulterant \| journal = Clinical Pharmacology and Therapeutics \| volume = 88 \| issue = 3 \| pages = 408–411 \| date = September 2010 \| pmid = 20668440 \| doi = 10.1038/clpt.2010.156 \| s2cid = 31414939 }}</ref><ref>{{cite journal \| vauthors = Tallarida CS, Egan E, Alejo GD, Raffa R, Tallarida RJ, Rawls SM \| title = Levamisole and cocaine synergism: a prevalent adulterant enhances cocaine's action in vivo \| journal = Neuropharmacology \| volume = 79 \| pages = 590–595 \| date = April 2014 \| pmid = 24440755 \| pmc = 3989204 \| doi = 10.1016/j.neuropharm.2014.01.002 }}</ref><ref name="chang2010">{{cite journal \| vauthors = Chang A, Osterloh J, Thomas J \| title = Levamisole: a dangerous new cocaine adulterant \| journal = Clinical Pharmacology and Therapeutics \| volume = 88 \| issue = 3 \| pages = 408–411 \| date = September 2010 \| pmid = 20668440 \| doi = 10.1038/clpt.2010.156 \| s2cid = 31414939 }}</ref> ~~The mixture of cocaine and alcohol is the most common two-drug combination that results in drug related death.{{Fact\|date=February 2007}}~~ Clinical studies have shown that taking levamisole at doses of 50–200 mg per day can lead to agranulocytosis in approximately 0.08–5% of patients.<ref>{{cite web \|title=697. Levamisole \| work = WHO Food Additives Series 27 \| publisher = INCHEM; International Programme on Chemical Safety (IPCS); World Health Organization \|url=https://www.inchem.org/documents/jecfa/jecmono/v27je04.htm }}</ref> ~~=== Metabolism and excretion ===~~ =====Cocaine- and levamisole-induced vasculitis===== Cocaine is extensively [[metabolism\|metabolized]], primarily in the [[liver]], with only about 1% excreted unchanged in the urine. The metabolism is dominated by [[hydrolysis\|hydrolytic]] [[ester]] cleavage, so the eliminated metabolites consist mostly of [[benzoylecgonine]], the major [[metabolite]], and in lesser amounts ecgonine methyl ester and ecgonine. {{See also\|Desomorphine#Toxicity of krokodil}} Cocaine- and levamisole-induced vasculitis (CLIV) is often used as an umbrella term for the vasculitic and necrotic complications seen with levamisole-adulterated cocaine, including both LINES and CLAAS.<ref name="Gill_2021">{{cite journal \| vauthors = Gill H, Trinh D, Anderson DJ, Li N, Madenberg D \| title = Cocaine and Levamisole Induced Vasculitis \| journal = Cureus \| volume = 13 \| issue = 8 \| pages = e17192 \| date = August 2021 \| pmid = 34548986 \| pmc = 8439268 \| doi = 10.7759/cureus.17192 \| doi-access = free }}</ref> If taken with [[ethanol\|alcohol]], cocaine combines with the ethanol in the [[liver]] to form [[cocaethylene]], which is both more [[euphoria\|euphorigenic]] and has higher [[cardiovascular]] toxicity than cocaine by itself. It is precisely this characteristic that since the early 20th century has prompted heavily inebriated persons to snort cocaine to relieve them of the depressive effects of alcohol abuse. Cocaine and levamisole-adulterated cocaine (LAC) can cause cocaine-induced [[vasculitis]] (CIV) that mimics primary [[anti-neutrophil cytoplasmic antibody\|anti-neutrophil cytoplasmic antibody (ANCA)]]-associated vasculitis (AAV), presenting as [[cocaine-induced midline destructive lesions]], LAC vasculopathy, or CIV. These conditions involve immune activation through [[neutrophil extracellular traps#NETosis\|NETosis]] and ANCA formation, leading to [[injury\|tissue damage]]. Diagnosis is challenging due to symptom overlap and undisclosed drug use, making clinical suspicion and drug history essential for proper management.<ref>{{cite journal \| vauthors = Iorio L, Davanzo F, Cazzador D, Codirenzi M, Fiorin E, Zanatta E, Nicolai P, Doria A, Padoan R \| title = Cocaine- and Levamisole-Induced Vasculitis: Defining the Spectrum of Autoimmune Manifestations \| journal = Journal of Clinical Medicine \| volume = 13 \| issue = 17 \| page = 5116 \| date = August 2024 \| pmid = 39274328 \| pmc = 11396482 \| doi = 10.3390/jcm13175116 \| doi-access = free }}</ref> Depending on liver and kidney function, cocaine metabolites are detectable in urine. Benzoylecgonine can be detected in urine within four hours after cocaine intake and remains detectable in concentrations greater than 150 ng/ml typically for up to eight days after cocaine is used. Detection of accumulation of cocaine metabolites in hair is possible in regular users until the sections of hair grown during use are cut or fall out. ======Cocaine/levamisole-associated autoimmune syndrome====== ~~=== Effects and health issues ===~~ The broader cocaine/levamisole-associated autoimmune syndrome (CLAAS) includes LINES as a subset and is also common, but LINES is more specifically and frequently cited in the context of street cocaine adulteration.<ref name="Cascio_2018">{{cite journal \| vauthors = Cascio MJ, Jen KY \| title = Cocaine/levamisole-associated autoimmune syndrome: a disease of neutrophil-mediated autoimmunity \| journal = Current Opinion in Hematology \| volume = 25 \| issue = 1 \| pages = 29–36 \| date = January 2018 \| pmid = 29211697 \| doi = 10.1097/MOH.0000000000000393 }}</ref> ~~==== Acute ====~~ Levamisole has become a common additive to illicit cocaine. It is thought to intensify the "high" by releasing [[dopamine]] in the brain, acts as a bulking agent, and is a difficult adulterant to recognize. Potential risks of levamisole-laced cocaine include [[autoimmune disease]], [[neutropenia]], [[arthralgias]], [[retiform purpura]], skin [[necrosis]], and [[fever]].<ref>{{Cite journal \| vauthors = Cascio MJ, Jen KY \| title = Cocaine/levamisole-associated autoimmune syndrome: a disease of neutrophil-mediated autoimmunity \| journal = Current Opinion in Hematology \| volume = 25 \| issue = 1 \| pages = 29–36 \| date = January 2018 \| pmid = 29211697 \| doi = 10.1097/MOH.0000000000000393 \| s2cid = 23795272 }}</ref> ~~Cocaine is a potent [[central nervous system]] [[stimulant]]. Its effects can last from 20 minutes to several hours, depending upon the dosage of cocaine taken, purity, and method of administration.~~ === Mortality === The initial signs of stimulation are hyperactivity, restlessness, increased [[blood pressure]], increased [[heart rate]] and [[euphoria]]. The euphoria is sometimes followed by feelings of discomfort and depression and a craving to experience the drug again. Sexual interest and pleasure can be amplified. Side effects can include twitching, [[paranoia]], and impotence, which usually increases with frequent usage. Persons with regular or problematic use of cocaine have a significantly higher [[mortality rate]], and are specifically at higher risk of traumatic deaths and deaths attributable to infectious disease.<ref>{{Cite journal \| vauthors = Peacock A, Tran LT, Larney S, Stockings E, Santo T, Jones H, Santomauro D, Degenhardt L \| title = All-cause and cause-specific mortality among people with regular or problematic cocaine use: a systematic review and meta-analysis \| journal = Addiction \| volume = 116 \| issue = 4 \| pages = 725–742 \| date = April 2021 \| pmid = 32857457 \| pmc = 7914269 \| doi = 10.1111/add.15239 }}</ref> In 2025, the Liberty House Clinic in the United Kingdom noted that chronic cocaine usage in fact had a higher risk of death than [[alcoholism]].<ref>{{cite web\|url=https://www.libertyhouseclinic.co.uk/blog/substance-abuse/cocaine-or-alcohol-whats-worse/\|title=Cocaine or alcohol, what's worse?\|publisher=Liberty House Clinic\|date=17 February 2025\|access-date=19 April 2025}}</ref> === Neurotoxicity === ~~With excessive dosage the drug can produce [[itch]]ing, [[tachycardia]], [[hallucination]]s, and [[formication\|paranoid delusions]].~~ Cocaine is considered [[neurotoxic]] due to its damaging effects on the brain and nervous system.<ref>{{cite journal \| vauthors = Sharma HS, Muresanu D, Sharma A, Patnaik R \| title = Cocaine-induced breakdown of the blood-brain barrier and neurotoxicity \| journal = International Review of Neurobiology \| volume = 88 \| pages = 297–334 \| date = 2009 \| pmid = 19897082 \| doi = 10.1016/S0074-7742(09)88011-2 \| isbn = 978-0-12-374504-0 }}</ref><ref>{{cite journal \| vauthors = Pereira RB, Andrade PB, Valentão P \| title = A Comprehensive View of the Neurotoxicity Mechanisms of Cocaine and Ethanol \| journal = Neurotoxicity Research \| volume = 28 \| issue = 3 \| pages = 253–267 \| date = October 2015 \| pmid = 26105693 \| doi = 10.1007/s12640-015-9536-x }}</ref><ref name="Clare_2024" /><ref name="Nicolucci_2020">{{cite journal \| vauthors = Nicolucci C, Pais ML, Santos AC, Ribeiro FM, Encarnação PM, Silva AL, Castro IF, Correia PM, Veloso JF, Reis J, Lopes MZ, Botelho MF, Pereira FC, Priolli DG \| title = Single Low Dose of Cocaine-Structural Brain Injury Without Metabolic and Behavioral Changes \| journal = Frontiers in Neuroscience \| volume = 14 \| article-number = 589897 \| date = 2020 \| pmid = 33584173 \| pmc = 7874143 \| doi = 10.3389/fnins.2020.589897 \| doi-access = free }}</ref><ref>{{cite journal \| vauthors = Hofmaier T, Luf A, Seddik A, Stockner T, Holy M, Freissmuth M, Ecker GF, Schmid R, Sitte HH, Kudlacek O \| title = Aminorex, a metabolite of the cocaine adulterant levamisole, exerts amphetamine like actions at monoamine transporters \| journal = Neurochemistry International \| volume = 73 \| issue = 100 \| pages = 32–41 \| date = July 2014 \| pmid = 24296074 \| pmc = 4077236 \| doi = 10.1016/j.neuint.2013.11.010 }}</ref><ref name="Little_2009">{{Cite journal \| vauthors = Little KY, Ramssen E, Welchko R, Volberg V, Roland CJ, Cassin B \| title = Decreased brain dopamine cell numbers in human cocaine users \| journal = Psychiatry Research \| volume = 168 \| issue = 3 \| pages = 173–80 \| date = August 2009 \| pmid = 19233481 \| doi = 10.1016/j.psychres.2008.10.034 \| s2cid = 27618292 }}</ref> Research has shown that both acute and chronic cocaine use can lead to significant reductions in cerebral blood flow, disrupt neurovascular interactions, and impair brain function. These changes are associated with [[nerve injury]], cognitive deficits, and an increased risk of cerebrovascular accidents such as strokes. Brain imaging studies consistently report that individuals who misuse cocaine exhibit structural and functional abnormalities compared to non-users, supporting the classification of cocaine as a neurotoxic substance.<ref name="Clare_2024">{{cite journal \| vauthors = Clare K, Park K, Pan Y, Lejuez CW, Volkow ND, Du C \| title = Neurovascular effects of cocaine: relevance to addiction \| journal = Frontiers in Pharmacology \| volume = 15 \| article-number = 1357422 \| date = 2024 \| pmid = 38455961 \| pmc = 10917943 \| doi = 10.3389/fphar.2024.1357422 \| doi-access = free }}</ref> Cocaine use damages [[gray matter]] in brain regions critical for memory, attention, and emotion, leading to cognitive and behavioral impairments. It also disrupts dopamine levels and blood flow, accelerating [[aging brain\|brain aging]] and causing long-term neurological harm.<ref>{{cite journal \| vauthors = Beheshti I \| title = Cocaine Destroys Gray Matter Brain Cells and Accelerates Brain Aging \| journal = Biology \| volume = 12 \| issue = 5 \| page = 752 \| date = May 2023 \| pmid = 37237564 \| pmc = 10215125 \| doi = 10.3390/biology12050752 \| doi-access = free }}</ref> ~~Overdose causes [[cardiac arrhythmia\|tachyarrhythmias]] and a marked elevation of blood pressure. These can be life-threatening, especially if the user has existing cardiac problems.~~ ===Psychiatric symptoms=== The [[LD50\|LD<sub>50</sub>]] of cocaine when administered to mice is 95.1 mg/kg.<ref>{{Cite journal\|author=Bedford JA, Turner CE, Elsohly HN\|title=Comparative lethality of coca and cocaine\|journal=Pharmacol Biochem Behav\|volume=17\|issue=5\|year=1982\|pages=1087–1088\|curly=true}}</ref> Toxicity results in seizures, followed by respiratory and circulatory depression of medullar origin. This may lead to death from [[respiratory failure]], [[stroke]], [[cerebral hemorrhage]], or [[heart]]-failure. Cocaine is also highly pyrogenic, because the stimulation and increased muscular activity cause greater heat production. Heat loss is inhibited by the intense [[vasoconstriction]]. Cocaine-induced [[hyperthermia]] may cause muscle cell destruction and [[myoglobinuria]] resulting in [[renal failure]]. There is no specific [[antidote]] for cocaine overdose. Cocaine produces a spectrum of [[psychiatric symptoms]] including agitation, paranoia, anxiety, irritability, [[psychosis]], hallucinations, delusions, violence, as well as suicidal and homicidal thinking.<ref name="Morton_1999">{{cite journal \| vauthors = Morton WA \| title = Cocaine and Psychiatric Symptoms \| journal = Primary Care Companion to the Journal of Clinical Psychiatry \| volume = 1 \| issue = 4 \| pages = 109–113 \| date = August 1999 \| pmid = 15014683 \| pmc = 181074 \| doi = 10.4088/pcc.v01n0403 }}</ref><ref name="Pom_2012" /> A considerable proportion of cocaine addicts exhibit [[hypomanic]] personality traits that are [[ego-syntonic]] with their pattern of cocaine abuse.<ref>{{cite journal \| vauthors = Lemere F, Smith JW \| title = Hypomanic personality trait in cocaine addiction \| journal = British Journal of Addiction \| volume = 85 \| issue = 4 \| pages = 575–576 \| date = April 1990 \| pmid = 2346798 \| doi = 10.1111/j.1360-0443.1990.tb01679.x }}</ref> Cocaine's primary acute effect on brain chemistry is to raise the amount of dopamine and serotonin in the [[nucleus accumbens]] (the pleasure center in the brain); this effect ceases, due to metabolism of cocaine to inactive compounds and particularly due to the depletion of the transmitter resources ([[tachyphylaxis]]). This can be experienced acutely as feelings of depression, as a "crash" after the initial high. Further mechanisms occur in chronic cocaine use. [[Cocaine intoxication]] mirrors core traits of [[narcissism]]—both involve a dopamine-driven, compulsive drive for reward. Just as cocaine produces a brief high that temporarily enhances the sense of worth, narcissists rely on external [[admiration]] to feed an addiction to their [[self-esteem]], resulting in a [[positive feedback\|self-reinforcing feedback]] cycle.<ref>{{cite journal \| vauthors = Kastner-Bosek A, Dajic I, Mikus N, Weidenauer A, Willeit M \| title = Addicted to Self-esteem: Understanding the neurochemistry of narcissism by using cocaine as a pharmacological model \| journal = Journal of Experimental Psychopathology \| volume = 12 \| issue = 3 \| date = July 2021 \| article-number = 20438087211044362 \| doi = 10.1177/20438087211044362 }}</ref> ~~==== Chronic ====~~ The misuse of cocaine has a high correlation with [[suicide]].<ref name="Vijayakumar_2011">{{cite journal \| vauthors = Vijayakumar L, Kumar MS, Vijayakumar V \| title = Substance use and suicide \| journal = Current Opinion in Psychiatry \| volume = 24 \| issue = 3 \| pages = 197–202 \| date = May 2011 \| pmid = 21430536 \| doi = 10.1097/YCO.0b013e3283459242 \| s2cid = 206143129 }}</ref><ref>{{cite journal \| vauthors = Moçambique M, Hoffmann A, Roglio V, Kessler F, Dalbosco C, Schuch J, Pechansky F \| title = Prevalence of suicide in cocaine users accessing health services: a systematic review and meta-analysis. \| journal = Revista Brasileira de Psiquiatria \| ___location = Sao Paulo, Brazil \| volume = 44 \| issue = 4 \| pages = 441–448 \| date = 24 June 2022 \| pmid = 35751594 \| pmc = 9375660 \| doi = 10.47626/1516-4446-2021-2207 }}</ref> In those who use cocaine, the risk is greatest during the [[Cocaine withdrawal\|withdrawal phase]].<ref>{{cite book \| vauthors = Ayd FJ \| title = Lexicon of psychiatry, neurology, and the neurosciences \| ___location = Philadelphia [u.a.] \| pages = 256 \| year = 2000 \| url = https://books.google.com/books?id=ea_QVG2BFy8C&q=256 \| publisher = Lippincott Williams & Wilkins \| isbn = 978-0-7817-2468-5 \| edition = 2nd }}</ref> Cocaine use has been linked to homicide, with up to 31% of homicide victims testing positive for the drug.<ref name="Morton_1999" /> In 1989 Fulton County, 40% of [[homicide]] victims had cocaine metabolites, especially Black and firearm victims.<ref>{{cite journal \| vauthors = Hanzlick R, Gowitt GT \| title = Cocaine metabolite detection in homicide victims \| journal = JAMA \| volume = 265 \| issue = 6 \| pages = 760–761 \| date = February 1991 \| pmid = 1990194 \| doi = 10.1001/jama.1991.03460060092031 }}</ref> Chronic cocaine intake causes brain cells to adapt functionally <!-- like muscles grow and degenerate --> to strong imbalances of transmitter levels in order to compensate extremes. Thus, receptors<!-- includes transporters --> disappear from the cell surface or reappear on it, resulting more or less in an "off" or "working mode" respectively, or they change their susceptibility for binding partners (ligands) – mechanisms called [[downregulation\|down-]]/[[upregulation]]. Chronic cocaine use leads to a DAT upregulation{{verify source}}, further contributing to depressed mood states. Physical withdrawal is not dangerous, and is in fact restorative. The experience of insatiable hunger, aches, insomnia/oversleeping, lethargy, and persistent runny nose are often described as very unpleasant. Depression with suicidal ideation may develop in very heavy users. Finally, a loss of [[vesicular monoamine transporter]]s, neurofilament proteins, and other morphological changes appear to indicate a long term damage of dopamine neurons. A 2020 study found that men with cocaine use disorder have greater difficulty identifying [[emotional expression]] in female faces, affecting relationships and suggesting a target for intervention.<ref>{{cite journal \| vauthors = Bland AR, Ersche KD \| title = Deficits in recognizing female facial expressions related to social network in cocaine-addicted men \| journal = Drug and Alcohol Dependence \| volume = 216 \| pages = 108247 \| date = November 2020 \| pmid = 32896724 \| pmc = 7616971 \| doi = 10.1016/j.drugalcdep.2020.108247 \| article-number = 108247 }}</ref> A 2021 study found that cocaine use disorder impairs emotion recognition, especially for happiness and fear, with improvement after long-term abstinence.<ref>{{cite journal \| vauthors = Rabin RA, Parvaz MA, Alia-Klein N, Goldstein RZ \| title = Emotion recognition in individuals with cocaine use disorder: the role of abstinence length and the social brain network \| journal = Psychopharmacology \| volume = 239 \| issue = 4 \| pages = 1019–1033 \| date = April 2022 \| pmid = 34089343 \| pmc = 8689230 \| doi = 10.1007/s00213-021-05868-x }}</ref> All these effects contribute a rise in tolerance thus requiring a larger dosage to achieve the same effect. The lack of normal amounts of serotonin and dopamine in the brain is the cause of the dysphoria and depression felt after the initial high. The diagnostic criteria for cocaine withdrawal is characterized by a dysphoric mood, fatigue, unpleasant dreams, insomnia or hypersomnia, E.D., increased appetite, psychomotor retardation or agitation, and anxiety. [[Depression (mood)\|Depression]] is modestly linked to current drug use in cocaine users but does not clearly predict treatment participation or future use.<ref>{{cite journal \| vauthors = Conner KR, Pinquart M, Holbrook AP \| title = Meta-analysis of depression and substance use and impairment among cocaine users \| journal = Drug and Alcohol Dependence \| volume = 98 \| issue = 1–2 \| pages = 13–23 \| date = November 2008 \| pmid = 18585871 \| pmc = 2570759 \| doi = 10.1016/j.drugalcdep.2008.05.005 }}</ref> For people who use cocaine, stress and craving can make each other worse. This may help explain why stress can lead to [[relapse]] in people trying to stop using cocaine.<ref>{{cite journal \| vauthors = Kexel AK, Kluwe-Schiavon B, Baumgartner MR, Engeli EJ, Visentini M, Kirschbaum C, Seifritz E, Ditzen B, Soravia LM, Quednow BB \| title = Cue-induced cocaine craving enhances psychosocial stress and vice versa in chronic cocaine users \| journal = Translational Psychiatry \| volume = 12 \| issue = 1 \| article-number = 443 \| date = October 2022 \| pmid = 36220809 \| pmc = 9554190 \| doi = 10.1038/s41398-022-02204-5 }}</ref> Cocaine abuse also has multiple physical health consequences. It is associated with a lifetime risk of [[myocardial infarction\|heart attack]] that is seven times that of non-users. During the hour after cocaine is used, [[myocardial infarction\|heart attack]] risk rises 24-fold <ref>{{cite journal \|quotes=no \|last=Vascia \|first=Gabriella \|authorlink= \|coauthors=Christopher C. Tennant \|year=2002 \|month= \|title=Cocaine use and cardiovascular complications\|journal=MJA \|volume=177 \|issue=5 \|pages=260-262 \|id= \|url=http://www.mja.com.au/public/issues/177_05_020902/vas10632_fm.html \|accessdate= }}</ref> ====Psychosis==== Side effects from chronic smoking of cocaine include chest pain, lung trauma, shortness of breath, sore throat, hoarse voice, [[dyspnea]], and an aching, [[flu]]-like syndrome. A common misconception is that the smoking of cocaine chemically breaks down [[tooth enamel]] and causes [[tooth decay]]. However, cocaine does often cause involuntary tooth grinding, known as [[bruxism]], which can deteriorate tooth enamel and lead to [[gingivitis]].<ref>{{cite journal \|quotes=no \|last=Baigent \|first=Michael \|authorlink= \|coauthors= \|year=2003 \|month= \|title=Physical complications of substance abuse: what the pychiatrist needs to know \|journal=Curr Opin Psychiatry \|volume=16 \|issue=3 \|pages=291-296 \|id= \|url= http://www.medscape.com/viewarticle/452724_7\|accessdate= }}</ref> Cocaine has a similar potential to induce temporary psychosis<ref name="Brady_1991">{{cite journal \| vauthors = Brady KT, Lydiard RB, Malcolm R, Ballenger JC \| title = Cocaine-induced psychosis \| journal = The Journal of Clinical Psychiatry \| volume = 52 \| issue = 12 \| pages = 509–512 \| date = December 1991 \| pmid = 1752853 }}</ref> with more than half of cocaine abusers reporting at least some psychotic symptoms at some point.<ref name="Thirthalli_2006">{{cite journal \| vauthors = Thirthalli J, Benegal V \| title = Psychosis among substance users \| journal = Current Opinion in Psychiatry \| volume = 19 \| issue = 3 \| pages = 239–245 \| date = May 2006 \| pmid = 16612208 \| doi = 10.1097/01.yco.0000218593.08313.fd \| s2cid = 13350537 }}</ref> Typical symptoms include paranoid delusions that they are being followed and that their drug use is being watched, accompanied by hallucinations that support the delusional beliefs.<ref name="Thirthalli_2006" /> [[Delusional parasitosis]] with [[formication]] ('cocaine bugs') is also a fairly common symptom.<ref name="Elliott_2012">{{cite journal \| vauthors = Elliott A, Mahmood T, Smalligan RD \| title = Cocaine bugs: a case report of cocaine-induced delusions of parasitosis \| journal = The American Journal on Addictions \| volume = 21 \| issue = 2 \| pages = 180–181 \| year = 2012 \| pmid = 22332864 \| doi = 10.1111/j.1521-0391.2011.00208.x }}</ref> Cocaine-induced psychosis shows [[drug sensitization\|sensitization]] toward the psychotic effects of the drug. This means that psychosis becomes more severe with repeated intermittent use.<ref name="Thirthalli_2006" /><ref>{{cite journal \| vauthors = DiSclafani II A, Hall RC, Gardner ER \| title = Drug-induced psychosis: emergency diagnosis and management \| journal = Psychosomatics \| volume = 22 \| issue = 10 \| pages = 845–50, 855 \| date = October 1981 \| pmid = 7313045 \| doi = 10.1016/s0033-3182(81)73092-5 \| doi-access = }}</ref> Chronic intranasal usage can degrade the [[cartilage]] separating the [[nostril]]s (the [[septum nasi]]), leading eventually to its complete disappearance. Due to the absorption of the cocaine from cocaine hydrochloride, the remaining hydrochloride forms a dilute hydrochloric acid.<ref name="pagliaros"/> === Short-term effects === Cocaine may also greatly increase this risk of developing rare autoimmune or connective tissue diseases such as [[lupus]], [[Goodpasture's disease]], [[vasculitis]], [[glomerulonephritis]], [[Stevens-Johnson syndrome]] and other diseases.<ref>[http://www.scienceblog.com/community/older/1999/A/199900322.html scienceblog.com]</ref><ref>{{cite journal \| author = Trozak D, Gould W \| title = Cocaine abuse and connective tissue disease. \| journal = J Am Acad Dermatol \| volume = 10 \| issue = 3 \| pages = 525 \| year = 1984 \| id = PMID 6725666}}</ref><ref>[http://content.karger.com/ProdukteDB/produkte.asp?Aktion=ShowFulltext&ProduktNr=223854&Ausgabe=224772&ArtikelNr=45328 karger.com]</ref><ref>[http://jnnp.bmjjournals.com/cgi/content/full/65/1/10 jnnp.bmjjournals.com]</ref> It can also cause a wide array of kidney diseases and renal failure.<ref>[http://cjasn.asnjournals.org/cgi/content/abstract/1/4/655 cjasn.asnjournals.org]</ref><ref>[http://ndt.oxfordjournals.org/cgi/content/full/15/3/299 ndt.oxfordjournals.org]</ref> While these conditions are normally found in chronic use they can also be caused by short term exposure in susceptible individuals. Insufflating (snorting) cocaine commonly causes increased [[mucus]] production due to irritation and inflammation of the nasal passages. This irritation leads to symptoms such as a [[Rhinorrhea\|runny nose]], [[nasal congestion]], and excessive or thickened mucus. Acute exposure to cocaine has many effects on humans, including euphoria, increases in heart rate and blood pressure, and increases in cortisol secretion from the adrenal gland.<ref>{{Cite journal \| vauthors = Heesch CM, Negus BH, Keffer JH, Snyder RW, Risser RC, Eichhorn EJ \| title = Effects of cocaine on cortisol secretion in humans \| journal = The American Journal of the Medical Sciences \| volume = 310 \| issue = 2 \| pages = 61–4 \| date = August 1995 \| pmid = 7631644 \| doi = 10.1097/00000441-199508000-00004 \| s2cid = 11042810 }}</ref> In humans with acute exposure followed by continuous exposure to cocaine at a constant blood concentration, the acute tolerance to the [[chronotropic]] cardiac effects of cocaine begins after about 10 minutes, while acute tolerance to the euphoric effects of cocaine begins after about one hour.<ref name="Ambre_1988">{{Cite journal \| vauthors = Ambre JJ, Belknap SM, Nelson J, Ruo TI, Shin SG, Atkinson AJ \| title = Acute tolerance to cocaine in humans \| journal = Clinical Pharmacology and Therapeutics \| volume = 44 \| issue = 1 \| pages = 1–8 \| date = July 1988 \| pmid = 3390996 \| doi = 10.1038/clpt.1988.104 \| s2cid = 44253676 }}</ref><ref>{{Cite journal \| vauthors = Pudiak CM, KuoLee R, Bozarth MA \| title = Tolerance to cocaine in brain stimulation reward following continuous cocaine infusions \| journal = Pharmacology, Biochemistry, and Behavior \| volume = 122 \| pages = 246–52 \| date = July 2014 \| pmid = 24768900 \| doi = 10.1016/j.pbb.2014.04.006 \| s2cid = 207332822 }}</ref><ref>{{Cite journal \| vauthors = Gullapalli BT, Natarajan A, Angarita GA, Malison RT, Ganesan D, Rahman T \|title=On-body Sensing of Cocaine Craving, Euphoria and Drug-Seeking Behavior Using Cardiac and Respiratory Signals \|journal=Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies \|date=21 June 2019 \|volume=3 \|issue=2 \|pages=1–31 \|doi=10.1145/3328917\|s2cid=195357215 }}</ref><ref>{{Cite journal \| vauthors = Calipari ES, Ferris MJ, Jones SR \| title = Extended access of cocaine self-administration results in tolerance to the dopamine-elevating and locomotor-stimulating effects of cocaine \| journal = Journal of Neurochemistry \| volume = 128 \| issue = 2 \| pages = 224–32 \| date = January 2014 \| pmid = 24102293 \| pmc = 3947316 \| doi = 10.1111/jnc.12452 }}</ref> With excessive or prolonged use, the drug can cause [[itch]]ing, [[tachycardia\|fast heart rate]], and [[formication\|paranoid delusions or sensations of insects crawling on the skin]].<ref name="Weizhao_2008">{{Cite book \|title=Mechanisms Mediating Sex Differences in the Effects of Cocaine \| vauthors = Zhao W \|year=2008 \|isbn=978-0-549-99458-9 \|page=3 \| publisher = University of Michigan \|access-date=25 September 2012 \|url=https://books.google.com/books?id=AF8zjRBtSuIC&pg=PA3 \|url-status=live \|archive-url=https://web.archive.org/web/20140404151302/https://books.google.com/books?id=AF8zjRBtSuIC&pg=PA3 \|archive-date=4 April 2014 }}</ref> Cocaine can induce [[psychosis]] characterized by [[paranoia]], impaired [[reality testing]], [[hallucinations]], irritability, and physical aggression. [[Cocaine intoxication]] can cause hyperawareness, [[hypervigilance]], [[psychomotor agitation]], and [[delirium]]. Consumption of large doses of cocaine can cause violent outbursts, especially by those with preexisting psychosis.<ref>{{Cite journal \| vauthors = Boles SM, Miotto K \|title=Substance abuse and violence: A review of the literature \|journal=Aggression and Violent Behavior \|date=March–April 2003 \|volume=8 \|issue=2 \|pages=155–174 \|doi=10.1016/S1359-1789(01)00057-X }}</ref> Acute exposure may induce [[arrhythmia]], including [[atrial fibrillation]], [[supraventricular tachycardia]], [[ventricular tachycardia]], and [[ventricular fibrillation]]. Acute exposure may also lead to [[angina]], [[myocardial infarction\|heart attack]], and [[congestive heart failure]].<ref>{{Cite journal \| vauthors = Pergolizzi JV, Magnusson P, LeQuang JA, Breve F, Varrassi G \| title = Cocaine and Cardiotoxicity: A Literature Review \| journal = Cureus \| volume = 13 \| issue = 4 \| pages = e14594 \| date = April 2021 \| pmid = 34036012 \| pmc = 8136464 \| doi = 10.7759/cureus.14594 \| issn=2168-8184 \| doi-access = free }}</ref> Cocaine overdose may cause [[seizures]], [[hyperthermia\|abnormally high body temperature]] and a marked elevation of blood pressure, which can be life-threatening,<ref name="Weizhao_2008" /> [[Heart arrhythmia\|abnormal heart rhythms]],<ref name="O'Leary_2010">{{Cite journal \| vauthors = O'Leary ME, Hancox JC \| title = Role of voltage-gated sodium, potassium and calcium channels in the development of cocaine-associated cardiac arrhythmias \| journal = British Journal of Clinical Pharmacology \| volume = 69 \| issue = 5 \| pages = 427–42 \| date = May 2010 \| pmid = 20573078 \| pmc = 2856043 \| doi = 10.1111/j.1365-2125.2010.03629.x }}</ref> and death.<ref name="O'Leary_2010" /> Anxiety, paranoia, and restlessness can also occur, especially during the [[Comedown (drugs)\|comedown]]. With excessive dosage, [[tremor]]s, [[convulsion]]s, and [[Hypothermia\|increased body temperature]] are observed.<ref name="WHO2004" /> There have been published studies{{Fact\|date=February 2007}} reporting that cocaine causes changes in the [[frontal lobe]] of the [[brain]]. The full extent of possible brain deterioration from cocaine use is not known. === ~~Cocaine~~Long-term ~~as a local anesthetic~~effects === [[File:Side effects of chronic use of Cocaine.png\|class=skin-invert-image\|thumb\|upright=1.4\|Side effects of chronic cocaine use]] Cocaine is highly addictive and has poor bioavailability when taken orally. Individuals often engage in repeated use by either insufflating it [[intranasally]] or converting it to [[crack cocaine]] for vaporization. Cocaine's effects last longest when insufflated (60–90 minutes),<ref name="Zimmerman_2012" /> but the drug itself has a short [[biological half-life]] of about 0.7–1.5 hours.<ref name="Treadwell_2007">{{cite journal \| vauthors = Treadwell SD, Robinson TG \| title = Cocaine use and stroke \| journal = Postgraduate Medical Journal \| volume = 83 \| issue = 980 \| pages = 389–394 \| date = June 2007 \| pmid = 17551070 \| pmc = 2600058 \| doi = 10.1136/pgmj.2006.055970 }}</ref> Repeated use raises the risk of developing "[[#Cocaine nose\|cocaine nose]]," referring to severe nasal tissue damage from intranasal use, as well as "[[#Crack lung\|crack lung]]," a condition involving lung tissue damage caused by inhaling crack cocaine. Cocaine was historically useful as a topical anesthetic in eye and nasal surgery, although it is now predominantly used for nasal and [[lacrimal duct]] surgery. The major disadvantages of this use are cocaine's intense [[vasoconstrictor]] activity and potential for [[cardiovascular]] toxicity. Cocaine has since been largely replaced in Western medicine by synthetic local anaesthetics such as [[benzocaine]], [[proparacaine]], and [[tetracaine]] though it remains available for use if specified. If vasoconstriction is desired for a procedure (as it reduces bleeding), the anesthetic is combined with a vasoconstrictor such as [[phenylephrine]] or [[epinephrine]]. In [[Australia]] it is currently prescribed for use as a local anesthetic for conditions such as mouth and lung [[ulcers]]. Some Australian [[ENT]] specialists occasionally use cocaine within the practice when performing procedures such as nasal [[cauterization]]. In this scenario dissolved cocaine is soaked into a ball of cotton wool, which is placed in the nostril for the 10-15 minutes immediately prior to the procedure, thus performing the dual role of both numbing the area to be cauterized and also vasoconstriction. Even when used this way, some of the used cocaine may be absorbed through oral or nasal mucosa and give systemic effects. Cocaine use leads to an increased risk of hemorrhagic and ischemic [[stroke]]s.<ref name="Sordo_2014"/> Cocaine use also increases the risk of having a [[myocardial infarction\|heart attack]].<ref name="Havakuk_2017">{{Cite journal \| vauthors = Havakuk O, Rezkalla SH, Kloner RA \| title = The Cardiovascular Effects of Cocaine \| journal = Journal of the American College of Cardiology \| volume = 70 \| issue = 1 \| pages = 101–113 \| date = July 2017 \| pmid = 28662796 \| doi = 10.1016/j.jacc.2017.05.014 \| type = Review \| doi-access = free}}</ref> ~~==History==~~ The cocaine [[alkaloid]] was first isolated by the [[Germany\|German]] chemist [[Friedrich Gaedcke]] in [[1855]]. In [[1859]] [[Albert Niemann]], a Ph.D. student at the [[University of Göttingen]] in [[Germany]] developed an improved purification process. He named the alkaloid “cocaine”. In [[1879]] cocaine began to be used to treat [[morphine]] [[addiction]]. Cocaine was introduced into clinical use as a [[local anaesthetic]] in [[Germany]] in [[1884]]. In [[1884]] [[Sigmund Freud]] wrote the article ''Über Coca'', where he described the therapeutic uses of cocaine.[http://www.ispub.com/ostia/index.php?xmlFilePath=journals/ijn/vol3n1/freud.xml] In [[1885]] the U.S. manufacturer [[Parke-Davis]] sold cocaine in various forms, including cigarettes, powder, and even a cocaine mixture that could be injected directly into the user’s veins with the included needle. The company promised that its cocaine products would “supply the place of food, make the coward brave, the silent eloquent and ... render the sufferer insensitive to pain.” In [[1886]] [[Coca-Cola]] is invented and its original formula includes cocaine.<ref>[http://www.snopes.com/cokelore/cocaine.asp Snopes.com]</ref> Around [[1903]] cocaine is eliminated as a direct ingredient of [[Coca-Cola]]. In [[1914]] the [[Harrison Narcotics Tax Act]] outlawed the use of cocaine in the [[United States]]. This law incorrectly referred to cocaine as a [[narcotic]], and the misclassification passed into popular culture. Cocaine is a [[stimulant]], not a [[narcotic]]. In [[1961]] the [[Single Convention on Narcotic Drugs]] was signed in [[New York]]. It banned the production and trade of cocaine, [[cannabis]] and [[opium]] and its derivatives. It went into effect in [[1964]]. In [[1970]] the [[United States Congress]] passed the [[Controlled Substances Act]] which today still regulates the manufacture, importation, possession, and distribution of cocaine in the [[United States]]. In the [[1970s]] cocaine regained popularity as a recreational drug and was glamorized in the U.S. popular media (for example, in songs like [[J.J. Cale]]'s [[Cocaine (song)\|Cocaine]] and the movie [[Scarface]]), and by the [[disco music]] culture that emerged around [[discotheques]] like [[Studio 54]]. [http://www.pbs.org/wgbh/pages/frontline/shows/drugs/buyers/socialhistory.html] The [[Medellín Cartel\|Medellín]] and [[Cali Cartel]]s were founded in [[Colombia]] to meet the new demand for cocaine. In [[1985]] the [[crack epidemic]] began and lasted to about [[1990]]. In [[Late 1993]] [[Pablo Escobar]], the founder of the [[Medellín Cartel]] is gunned down by [[Colombian National Police]]. The [[Cali Cartel]] becomes the number one cocaine trafficker. In [[1995]] the [[Cali Cartel]] is dismantled by [[Colombian National Police]], only to be replaced by the [[Norte del Valle Cartel]]. Today, Cocaine in its various forms comes in second only to [[cannabis]] as the most popular illegal [[recreational drug]] in the [[United States]], and is number one in street value sold each year, exceeding $35 billion in [[2003]].{{cn}} Cocaine use also promotes the [[thrombosis\|formation of blood clots]].<ref name="Zimmerman_2012" /> This increase in blood clot formation is attributed to cocaine-associated increases in the activity of [[Plasminogen activator inhibitor-1\|plasminogen activator inhibitor]], and an increase in the number, activation, and aggregation of [[platelet]]s.<ref name="Zimmerman_2012" /> ~~== Prohibition currently==~~ ~~{{main\|Legal status of cocaine}}~~ The production, distribution and sale of cocaine products is restricted (and illegal in most contexts) in most countries as regulated by the [[Single Convention on Narcotic Drugs]], and the [[United Nations Convention Against Illicit Traffic in Narcotic Drugs and Psychotropic Substances]]. In the [[United States]] the manufacture, importation, possession, and distribution of cocaine is additionally regulated by the [[1970]] [[Controlled Substances Act]]. Cocaine [[Vasoconstriction\|constricts blood vessels]], [[Mydriasis\|dilates pupils]], and increases body temperature, heart rate, and blood pressure. It can also cause headaches and gastrointestinal complications such as abdominal pain and nausea. Chronic users may lose their [[appetite]] and experience severe [[malnutrition]], leading to being [[underweight]]. Some countries, such as [[Peru]] and [[Bolivia]] permit the cultivation of [[coca\|coca leaf]] for traditional consumption by the local [[Indigenous peoples of the Americas\|indigenous population]], but nevertheless prohibit the production, sale and consumption of cocaine. A 2014 study found that increased cocaine use is linked to greater [[cognitive impairment]], particularly in working memory, while reduced or ceased use can lead to partial or full recovery of cognitive function. These findings suggest that some cocaine-related cognitive deficits are reversible, especially if use begins later in life.<ref>{{cite journal \| vauthors = Vonmoos M, Hulka LM, Preller KH, Minder F, Baumgartner MR, Quednow BB \| title = Cognitive impairment in cocaine users is drug-induced but partially reversible: evidence from a longitudinal study \| journal = Neuropsychopharmacology \| volume = 39 \| issue = 9 \| pages = 2200–2210 \| date = August 2014 \| pmid = 24651468 \| pmc = 4104339 \| doi = 10.1038/npp.2014.71 }}</ref> A 2018 review found little evidence that chronic cocaine use causes widespread cognitive impairment.<ref>{{cite journal \| vauthors = Frazer KM, Richards Q, Keith DR \| title = The long-term effects of cocaine use on cognitive functioning: A systematic critical review \| journal = Behavioural Brain Research \| volume = 348 \| pages = 241–262 \| date = August 2018 \| pmid = 29673580 \| doi = 10.1016/j.bbr.2018.04.005 }}</ref> Exposure to cocaine may lead to the breakdown of the [[blood–brain barrier]].<ref>{{cite journal \| vauthors = Sharma HS, Muresanu D, Sharma A, Patnaik R \| title = Cocaine-induced breakdown of the blood-brain barrier and neurotoxicity \| journal = International Review of Neurobiology \| volume = 88 \| pages = 297–334 \| year = 2009 \| pmid = 19897082 \| doi = 10.1016/S0074-7742(09)88011-2 \| isbn = 978-0-12-374504-0 }}</ref><ref>{{Cite book\| vauthors = Karch SB \|title=Karch's pathology of drug abuse\|date=2009\|publisher=CRC Press\|___location=Boca Raton\|isbn=978-0-8493-7881-2\|page=70\|edition=4th \|url= https://books.google.com/books?id=G9E7gfJq0KkC&pg=PA70 \|url-status=live\|archive-url=https://web.archive.org/web/20170910234911/https://books.google.com/books?id=G9E7gfJq0KkC&pg=PA70 \|archive-date=10 September 2017 }}</ref> ~~Some parts of [[Europe]] and [[Australia]] allow processed cocaine for medicinal uses only.~~ Cocaine use is frequently associated with involuntary tooth grinding, known as [[bruxism]], which can cause [[dental attrition]] and [[gingivitis]].<ref>{{cite journal \| vauthors = Shekarchizadeh H, Khami MR, Mohebbi SZ, Ekhtiari H, Virtanen JI \| title = Oral Health of Drug Abusers: A Review of Health Effects and Care \| journal = Iranian Journal of Public Health \| volume = 42 \| issue = 9 \| pages = 929–940 \| date = September 2013 \| pmid = 26060654 \| pmc = 4453891 }}</ref><ref>{{Cite journal \| vauthors = Baigent M \| title = Physical complications of substance abuse: what the psychiatrist needs to know \| journal = Curr Opin Psychiatry \| volume = 16 \| issue = 3 \| pages = 291–296 \| year = 2003 \| doi = 10.1097/00001504-200305000-00004 }}</ref> Additionally, stimulants like cocaine, [[methamphetamine]], and even [[caffeine]] cause dehydration and [[Xerostomia\|dry mouth]]. In certain countries in the [[Middle East]] and [[Asia]], such as [[Singapore]], [[Saudi Arabia]] and [[Indonesia]], being in possession of cocaine can be punishable by death.<ref>[http://www.cocaineaddictiondrugrehab.com/crack-cocaine-laws.htm cocaineaddictiondrugrehab.com]</ref> ===~~Interdiction~~= Addiction ==== {{See also\|Epigenetics of cocaine addiction}} In 2004, according to the [[United Nations]], 589 [[metric ton]]s of cocaine were seized globally by law enforcement authorities. [[Colombia]] seized 188 tons, the [[United States]] 166 tons, [[Europe]] 79 tons, [[Peru]] 14 tons, Bolivia 9 tons, and the rest of the world 133 [[tons]]. [http://www.unodc.org/pdf/WDR_2006/wdr2006_chap4_cocaine.pdf] {{For\|harm caused by the freebase form\|Crack cocaine#Addiction}} Cocaine can induce [[Drug tolerance\|tolerance]] after a single dose, and repeated use frequently leads to the development of [[addiction]] and prolonged [[Cocaine dependence\|craving]].<ref name="Ambre_1988" /><ref>{{cite web \|title=Cocaine \|work= National Institute on Drug Abuse (NIDA) \| publisher = U.S. Department of Health and Human Services \|url=https://nida.nih.gov/research-topics/cocaine\|archive-url= https://web.archive.org/web/20220606183508/https://nida.nih.gov/research-topics/cocaine\|url-status=dead \|archive-date=6 June 2022}}</ref><ref>{{cite journal \| vauthors = Paludetto LS, Florence LL, Torales J, Ventriglio A, Castaldelli-Maia JM \| title = Mapping the Neural Substrates of Cocaine Craving: A Systematic Review \| journal = Brain Sciences \| volume = 14 \| issue = 4 \| pages = 329 \| date = March 2024 \| pmid = 38671981 \| pmc = 11048489 \| doi = 10.3390/brainsci14040329 \| doi-access = free }}</ref> Assessment tools like the Obsessive Compulsive Cocaine Use Scale (OCCUS) may be employed to quantify obsessive and compulsive thoughts related to cocaine consumption.<ref>{{cite journal \| vauthors = Hormes JM, Coffey SF, Drobes DJ, Saladin ME \| title = The Obsessive Compulsive Cocaine Use Scale: development and initial validation of a self-rated instrument for the quantification of thoughts about cocaine use \| journal = Drug and Alcohol Dependence \| volume = 120 \| issue = 1–3 \| pages = 250–254 \| date = January 2012 \| pmid = 21890282 \| pmc = 3245789 \| doi = 10.1016/j.drugalcdep.2011.07.024 }}</ref><ref>{{cite journal \| vauthors = Kirschner M, Sladky R, Haugg A, Stämpfli P, Jehli E, Hodel M, Engeli E, Hösli S, Baumgartner MR, Sulzer J, Huys QJ, Seifritz E, Quednow BB, Scharnowski F, Herdener M \| title = Self-regulation of the dopaminergic reward circuit in cocaine users with mental imagery and neurofeedback \| journal = eBioMedicine \| volume = 37 \| pages = 489–498 \| date = November 2018 \| pmid = 30377073 \| pmc = 6286189 \| doi = 10.1016/j.ebiom.2018.10.052 }}</ref> ~~== Illicit trade ==~~ Withdrawal symptoms include disrupted sleep, [[irritability]], [[Depression (mood)\|depression]], and reduced ability to experience pleasure ([[anhedonia]]).<ref>{{cite journal \| vauthors = Walsh SL, Stoops WW, Moody DE, Lin SN, Bigelow GE \| title = Repeated dosing with oral cocaine in humans: assessment of direct effects, withdrawal, and pharmacokinetics \| journal = Experimental and Clinical Psychopharmacology \| volume = 17 \| issue = 4 \| pages = 205–216 \| date = August 2009 \| pmid = 19653786 \| pmc = 2811070 \| doi = 10.1037/a0016469 }}</ref><ref name="Pom_2012" /> Chronic nasal use may cause destructive damage to the nasal septum, including [[cocaine-induced midline destructive lesions]] (CIMDL). Illicit cocaine is frequently adulterated with substances such as [[fentanyl]], [[levamisole]], or [[local anesthetics]], increasing its toxicity.<ref name="Goldstein_2009" /><ref>{{Cite web \| vauthors = Gold M \| date = 16 October 2022 \| work = Addiction Policy Forum \|url=https://www.addictionpolicy.org/post/fentanyl-adulterated-cocaine-strategies-to-address-the-new-normal\|title=Fentanyl-Adulterated Cocaine: Strategies To Address The New Normal\|access-date=17 December 2022\|archive-date=17 December 2022\|archive-url=https://web.archive.org/web/20221217214902/https://www.addictionpolicy.org/post/fentanyl-adulterated-cocaine-strategies-to-address-the-new-normal\|url-status=live}}</ref> Concurrent use with [[alcohol (drug)\|alcohol]] produces [[cocaethylene]], a metabolite that significantly increases the risk of sudden death. According to the [[Global Burden of Disease Study]], cocaine use is responsible for approximately 7,300 deaths annually.<ref>{{Cite journal \| vauthors = Roth GA, Abate D, Abate KH, Abay SM, Abbafati C, Abbasi N, Abbastabar H, Abd-Allah F, Abdela J, Abdelalim A, Abdollahpour I, etal \| collaboration = GBD 2017 Causes of Death Collaborators \| title = Global, regional, and national age-sex-specific mortality for 282 causes of death in 195 countries and territories, 1980–2017: a systematic analysis for the Global Burden of Disease Study 2017 \| journal = Lancet \| volume = 392 \| issue = 10159 \| pages = 1736–1788 \| date = November 2018 \| pmid = 30496103 \| pmc = 6227606 \| doi = 10.1016/S0140-6736(18)32203-7 \| doi-access = free }}</ref> ~~[[Image:Cocaine_bricks_scorpion_logo.jpg\|right\|thumb\|Bricks of cocaine, a form in which it is commonly transported.]]~~ Because of the extensive processing it undergoes during preparation, cocaine is generally treated as a '[[Hard_and_soft_drugs\|hard drug]]', with severe penalties for possession and trafficking. Demand remains high, and consequently black market cocaine is quite expensive. Unprocessed cocaine, such as [[coca leaves]], is occasionally bought and sold, but this is exceedingly rare as it is much easier and more profitable to conceal and smuggle it in powdered form. Cocaine abuse can trigger [[addiction-related structural neuroplasticity]] in the human brain, although the permanence of such changes remains uncertain.<ref name="Hamp_2019">{{cite journal \| vauthors = Hampton WH, Hanik I, Olson IR \| title = [Substance Abuse and White Matter: Findings, Limitations, and Future of Diffusion Tensor Imaging Research] \| journal = Drug and Alcohol Dependence \| volume = 197 \| issue = 4 \| pages = 288–298 \| year = 2019 \| pmid = 30875650 \| pmc = 6440853 \| doi = 10.1016/j.drugalcdep.2019.02.005}}</ref> [[Genealogy\|Family history]] is a known risk factor, as relatives of cocaine users have an increased likelihood of developing [[cocaine addiction]].<ref>{{Cite journal \| vauthors = Fernàndez-Castillo N, Cabana-Domínguez J, Corominas R, Cormand B \| title = Molecular genetics of cocaine use disorders in humans \| journal = Molecular Psychiatry \| volume = 27 \| issue = 1 \| pages = 624–639 \| date = January 2022 \| pmid = 34453125 \| doi = 10.1038/s41380-021-01256-1 \| pmc = 8960411 }}</ref> ~~=== Production ===~~ A key mechanism involves the overexpression of [[ΔFosB]] in the [[nucleus accumbens]], altering [[transcriptional regulation]] and reinforcing drug-seeking behavior.<ref name="Hope_1998">{{Cite journal \| vauthors = Hope BT \| title = Cocaine and the AP-1 transcription factor complex \| journal = Annals of the New York Academy of Sciences \| volume = 844 \| issue = 1 \| pages = 1–6 \| date = May 1998 \| pmid = 9668659 \| doi = 10.1111/j.1749-6632.1998.tb08216.x \| s2cid = 11683570 \| bibcode = 1998NYASA.844....1H \| url = https://zenodo.org/record/1230756 \| access-date = 30 June 2019 \| archive-date = 28 July 2020 \| archive-url = https://web.archive.org/web/20200728160757/https://zenodo.org/record/1230756 \| url-status = live }}</ref> Each dose of cocaine raises ΔFosB levels without a known saturation point. This elevation leads to increased [[brain-derived neurotrophic factor]] ([[BDNF]]) levels, which in turn enhance [[dendrite\|dendritic]] branching and [[dendritic spine\|spine]] density in neurons of the nucleus accumbens and [[prefrontal cortex]], potentially persisting for weeks after drug cessation.{{Citation needed\|date=June 2025}} In [[genetically modified mouse\|transgenic mice]] engineered to express ΔFosB in the nucleus accumbens and [[dorsal striatum]], heightened behavioral sensitization to cocaine has been observed.<ref name="Kelz_1999">{{Cite journal \|author-link13=D. James Surmeier \| vauthors = Kelz MB, Chen J, Carlezon WA, Whisler K, Gilden L, Beckmann AM, Steffen C, Zhang YJ, Marotti L, Self DW, Tkatch T, Baranauskas G, Surmeier DJ, Neve RL, Duman RS, Picciotto MR, Nestler EJ \| title = Expression of the transcription factor deltaFosB in the brain controls sensitivity to cocaine \| journal = Nature \| volume = 401 \| issue = 6750 \| pages = 272–6 \| date = September 1999 \| pmid = 10499584 \| doi = 10.1038/45790 \| bibcode = 1999Natur.401..272K \| s2cid = 4390717 }}</ref> These mice self-administer cocaine at lower doses and display a greater propensity for [[relapse]] after withdrawal<ref name="Colby_2003">{{Cite journal \| vauthors = Colby CR, Whisler K, Steffen C, Nestler EJ, Self DW \| title = Striatal cell type-specific overexpression of DeltaFosB enhances incentive for cocaine \| journal = The Journal of Neuroscience \| volume = 23 \| issue = 6 \| pages = 2488–93 \| date = March 2003 \| pmid = 12657709 \| doi = 10.1523/JNEUROSCI.23-06-02488.2003\| pmc = 6742034 }}</ref><ref name="Nestler_2011">{{Cite journal \| vauthors = Nestler EJ, Barrot M, Self DW \| title = DeltaFosB: a sustained molecular switch for addiction \| journal = Proceedings of the National Academy of Sciences of the United States of America \| volume = 98 \| issue = 20 \| pages = 11042–6 \| date = September 2001 \| pmid = 11572966 \| pmc = 58680 \| doi = 10.1073/pnas.191352698 \| quote = <!-- Although the ΔFosB signal is relatively long-lived, it is not permanent. ΔFosB degrades gradually and can no longer be detected in brain after 1–2 months of drug withdrawal ... Indeed, ΔFosB is the longest-lived adaptation known to occur in adult brain, not only in response to drugs of abuse, but to any other perturbation (that doesn't involve lesions) as well. --> \| bibcode = 2001PNAS...9811042N \| doi-access = free }}</ref> ΔFosB also enhances sensitivity to reward by upregulating the [[AMPA receptor]] subunit GluR2<ref name="Kelz_1999" /> and downregulating the expression of [[dynorphin]].<ref name="Nestler_2011">{{Cite journal \| vauthors = Nestler EJ, Barrot M, Self DW \| title = DeltaFosB: a sustained molecular switch for addiction \| journal = Proceedings of the National Academy of Sciences of the United States of America \| volume = 98 \| issue = 20 \| pages = 11042–6 \| date = September 2001 \| pmid = 11572966 \| pmc = 58680 \| doi = 10.1073/pnas.191352698 \| quote = <!-- Although the ΔFosB signal is relatively long-lived, it is not permanent. ΔFosB degrades gradually and can no longer be detected in brain after 1–2 months of drug withdrawal ... Indeed, ΔFosB is the longest-lived adaptation known to occur in adult brain, not only in response to drugs of abuse, but to any other perturbation (that doesn't involve lesions) as well. --> \| bibcode = 2001PNAS...9811042N \| doi-access = free }}</ref> By [[1999]], [[Colombia]] had become the world's leading producer of cocaine. Three-quarters of the world's annual yield of cocaine was produced there, both from cocaine base imported from [[Peru]] (primarily the [[Huallaga Valley]]) and [[Bolivia]], and from locally grown [[coca]]. There was a 28 percent increase from the amount of potentially harvestable [[coca]] plants which were grown in [[Colombia]] in [[1998]]. This, combined with crop reductions in [[Bolivia]] and [[Peru]], made [[Colombia]] the nation with the largest area of coca under cultivation after the mid-1990s. Coca grown for traditional purposes by indigenous communities, a use which is still present and is permitted by Colombian laws, only makes up a small fragment of total coca production, most of which is used for the illegal drug trade. Attempts to eradicate coca fields through the use of defoliants have devastated part of the farming economy in some coca growing regions of Colombia, and strains appear to have been developed that are more resistant or immune to their use. Whether these strains are natural mutations or the product of human tampering is unclear. These strains have also shown to be more potent than those previously grown, increasing profits for the drug cartels responsible for the exporting of cocaine. The cultivation of coca has become an attractive, and in some cases even necessary, economic decision on the part of many growers due to the combination of several factors, including the persistence of worldwide demand, the lack of other employment alternatives, the lower profitability of alternative crops in official crop substitution programs, the eradication-related damages to non-drug farms, and the spread of new strains of the coca plant. Cocaine use has also been shown to increase [[DNA damage (naturally occurring)\|DNA damage]] in the brains of rodents.<ref name="de_Souza_2014">{{Cite journal \| vauthors = de Souza MF, Gonçales TA, Steinmetz A, Moura DJ, Saffi J, Gomez R, Barros HM \| title = Cocaine induces DNA damage in distinct brain areas of female rats under different hormonal conditions \| journal = Clinical and Experimental Pharmacology & Physiology \| volume = 41 \| issue = 4 \| pages = 265–9 \| date = April 2014 \| pmid = 24552452 \| doi = 10.1111/1440-1681.12218 \| s2cid = 20849951 }}</ref><ref name="Alvarenga_2010">{{Cite journal \| vauthors = Alvarenga TA, Andersen ML, Ribeiro DA, Araujo P, Hirotsu C, Costa JL, Battisti MC, Tufik S \| title = Single exposure to cocaine or ecstasy induces DNA damage in brain and other organs of mice \| journal = Addiction Biology \| volume = 15 \| issue = 1 \| pages = 96–9 \| date = January 2010 \| pmid = 19878142 \| doi = 10.1111/j.1369-1600.2009.00179.x \| s2cid = 21347765 }}</ref> During subsequent [[DNA repair]], enduring alterations in [[chromatin]] structure may arise, such as [[DNA methylation]] and [[histone methylation\|methylation or acetylation of histones]] at the repair loci.<ref name="Dabin_2016">{{Cite journal \| vauthors = Dabin J, Fortuny A, Polo SE \| title = Epigenome Maintenance in Response to DNA Damage \| journal = Molecular Cell \| volume = 62 \| issue = 5 \| pages = 712–27 \| date = June 2016 \| pmid = 27259203 \| pmc = 5476208 \| doi = 10.1016/j.molcel.2016.04.006 }}</ref> These modifications may result in lasting [[epigenetics\|epigenetic "scars"]], which are believed to contribute to the persistent [[Epigenetics of cocaine addiction\|epigenetic changes]] observed in cocaine addiction. ~~<table class="wikitable" style="margin: 1em auto 1em auto">~~ <caption>Estimated Andean Region Coca Cultivation and Potential Pure Cocaine Production, 2000–2004.<ref>{{cite paper \| author=[[NDIC]] \| title=National Drug Threat Assessment 2006 \| date=2006 \| url=http://www.usdoj.gov/ndic/pubs11/18862/index.htm }}</ref><caption> ~~<tr><th></th><th>2000</th><th>2001</th><th>2002</th><th>2003</th><th>2004</th></tr>~~ ~~<tr><td>Net Cultivation ([[1 E9 m²\|km²]])</td><td>1875</td><td>2218</td><td>2007.5</td><td>1663</td><td>1662</td></tr>~~ ~~<tr><td>Potential Pure Cocaine Production ([[tonne]]s)</td><td>770</td><td>925</td><td>830</td><td>680</td><td>645</td></tr></table>~~ ==== ~~Trafficking~~Dependence and ~~distribution~~withdrawal ==== {{Further information\|Cocaine dependence}} [[Cocaine dependence]] develops after even brief periods of regular cocaine use.<ref name="Gawin_1989">{{Cite journal \|vauthors=Gawin FH, Ellinwood EH \|title=Cocaine dependence \|journal=Annual Review of Medicine \|volume=40 \|pages=149–61 \|date=1989 \|pmid=2658744 \|doi=10.1146/annurev.me.40.020189.001053}}</ref> [[Organized crime\|Organized criminal]] gangs operating on a large scale dominate the cocaine trade. Most cocaine is grown and processed in [[South America]], particularly in [[Colombia]] and [[Peru]], and smuggled into the [[United States]] and [[Europe]], where it is sold at huge markups; usually in the US at $100 for 3.5 grams (slang: 8 ball). About 25% of adults with [[attention deficit hyperactivity disorder]] (ADHD) use cocaine, and 10% develop a cocaine use disorder during their lifetime. Because cocaine use can worsen health outcomes, adults with ADHD should be screened for cocaine use disorder and referred for treatment if needed.<ref>{{cite journal \| vauthors = Oliva F, Mangiapane C, Nibbio G, Berchialla P, Colombi N, Vigna-Taglianti FD \| title = Prevalence of cocaine use and cocaine use disorder among adult patients with attention-deficit/hyperactivity disorder: A systematic review and meta-analysis \| journal = Journal of Psychiatric Research \| volume = 143 \| pages = 587–598 \| date = November 2021 \| pmid = 33199055 \| doi = 10.1016/j.jpsychires.2020.11.021 \| hdl-access = free \| hdl = 2318/1768539 }}</ref> Cocaine shipments from [[South America]] transported through [[Mexico]] or [[Central America]] are generally moved over land or by air to staging sites in northern Mexico. The cocaine is then broken down into smaller loads for smuggling across the [[US-Mexico border\|U.S.–Mexico border]]. The primary cocaine importation points in the [[United States]] are in [[Arizona]], southern [[California]], southern [[Florida]], and [[Texas]]. Typically, land vehicles are driven across the U.S.-Mexico border. Sixty Five percent of cocaine enters the United States through Mexico, and the vast majority of the rest enters through Florida.<ref>Jacobson, Robert. "Illegal Drugs: America's Anguish". Farmington Hills, MI: Thomson Gale, 2006</ref> Cocaine-dependent patients with high [[neuroticism]] scores are more likely to experience cocaine-induced psychotic symptoms, regardless of other drug use factors, making [[Personality test\|personality assessment]] important for risk identification and patient warning.<ref>{{cite journal \| vauthors = Roncero C, Daigre C, Barral C, Ros-Cucurull E, Grau-López L, Rodríguez-Cintas L, Tarifa N, Casas M, Valero S \| title = Neuroticism associated with cocaine-induced psychosis in cocaine-dependent patients: a cross-sectional observational study \| journal = PLOS ONE \| volume = 9 \| issue = 9 \| pages = e106111 \| date = 2014 \| pmid = 25254365 \| pmc = 4177812 \| doi = 10.1371/journal.pone.0106111 \| doi-access = free \| bibcode = 2014PLoSO...9j6111R }}</ref> Cocaine is also carried in small, concealed, kilogram quantities across the border by couriers known as “[[Mule (smuggling)\|mules]]” (or “burros”), who cross a border either legally, e.g. through a port or airport, or illegally through undesignated points along the border. The drugs may be strapped to the waist or legs or hidden in bags, or hidden in the body. If the mule gets through without being caught, the gangs will reap most of the profits. If he or she is caught however, gangs will sever all links and the mule will usually stand trial for trafficking by him/herself. Cocaine [[drug withdrawal\|withdrawal]] symptoms group into two types: depressive (e.g., [[Depression (mood)\|depression]], craving, insomnia) and somatic (e.g., increased appetite, fatigue). Depressive symptoms are linked to worse outcomes like longer depression, treatment, and risky behaviors.<ref name="Sofuoglu_2005">{{cite journal \| vauthors = Sofuoglu M, Dudish-Poulsen S, Poling J, Mooney M, Hatsukami DK \| title = The effect of individual cocaine withdrawal symptoms on outcomes in cocaine users \| journal = Addictive Behaviors \| volume = 30 \| issue = 6 \| pages = 1125–1134 \| date = July 2005 \| pmid = 15925122 \| doi = 10.1016/j.addbeh.2004.10.010 }}</ref> Cocaine traffickers from [[Colombia]], and recently [[Mexico]], have also established a labyrinth of [[smuggling]] routes throughout the [[Caribbean]], the [[Bahama]] Island chain, and South [[Florida]]. They often hire traffickers from [[Mexico]] or the [[Dominican Republic]] to transport the drug. The traffickers use a variety of smuggling techniques to transfer their drug to U.S. markets. These include airdrops of 500–700 kg in the [[Bahama Islands]] or off the coast of [[Puerto Rico]], mid-ocean boat-to-boat transfers of 500–2,000 kg, and the commercial shipment of tonnes of cocaine through the port of [[Miami]]. ===== Treatment ===== Bulk cargo ships are also used to smuggle cocaine to staging sites in the western [[Caribbean]]–[[Gulf of Mexico]] area. These vessels are typically 150–250 foot (50–80 m) coastal freighters that carry an average cocaine load of approximately 2.5 tonnes. Commercial fishing vessels are also used for smuggling operations. In areas with a high volume of recreational traffic, smugglers use the same types of vessels, such as [[go-fast boat]]s, as those used by the local populations. Because there are no medications with an approved [[Indication (medicine)\|indication]] for cocaine use disorder, psychosocial treatments are the current standard. Effective approaches include group and individual counseling, [[cognitive behavioral therapy]] (CBT), and [[motivational interviewing]] (MI). [[Contingency management]] (CM)—which rewards patients with vouchers for meeting treatment goals—has proven especially effective, particularly for helping patients achieve initial [[abstinence]] from cocaine.<ref name="Kampman_2019">{{cite journal \| vauthors = Kampman KM \| title = The treatment of cocaine use disorder \| journal = Science Advances \| volume = 5 \| issue = 10 \| article-number = eaax1532 \| date = October 2019 \| pmid = 31663022 \| pmc = 6795516 \| doi = 10.1126/sciadv.aax1532 \| bibcode = 2019SciA....5.1532K }}</ref> [[File:Cocaine Anonymous Chips.jpg\|thumb\|Cocaine Anonymous [[sobriety coin]]s]] ~~==== "Black cocaine" ====~~ [[Cocaine Anonymous]] (CA) is a [[twelve-step program]] formed in 18 November 1982 for people who seek recovery from drug [[Substance dependence\|addiction]]. It is patterned very closely after [[Alcoholics Anonymous]] (AA), although the two groups are unaffiliated. While many CA members have been addicted to cocaine, crack, speed or similar substances, CA accepts all who desire freedom from "cocaine and all other mind-altering substances" as members.<ref name="CAMIND2007">{{cite web \|author=Cocaine Anonymous \|title=And All Other Mind-Altering Substances \|accessdate=2007-11-15 \|date=2007-11-13 \|url=http://www.ca.org/literature/allothermas.htm \|url-status=dead \|archiveurl=https://web.archive.org/web/20090304202508/http://www.ca.org/literature/allothermas.htm \|archivedate=2009-03-04 }}</ref> Numerous medications have been investigated for use in cocaine dependence, but {{as of\|2015\|lc=y}}, none of them were considered to be effective.<ref name="Minozzi2015">{{cite journal \| vauthors = Minozzi S, Cinquini M, Amato L, Davoli M, Farrell MF, Pani PP, Vecchi S \| veditors = Minozzi S \| title = Anticonvulsants for cocaine dependence \| journal = The Cochrane Database of Systematic Reviews \| volume = 2015 \| issue = 4 \| pages = CD006754 \| date = April 2015 \| pmid = 25882271 \| pmc = 8812341 \| doi = 10.1002/14651858.CD006754.pub4 \| type = Systematic Review & Meta-Analysis }}</ref> Drugs which help to re-stabilize the glutamate system such as [[N-acetylcysteine\|''N''-acetylcysteine]] have been proposed for the treatment of addiction to cocaine, [[nicotine]], and [[Alcohol (drug)\|alcohol]].<ref name="McClure_2014">{{cite journal \| vauthors = McClure EA, Gipson CD, Malcolm RJ, Kalivas PW, Gray KM \| title = Potential role of N-acetylcysteine in the management of substance use disorders \| journal = CNS Drugs \| volume = 28 \| issue = 2 \| pages = 95–106 \| year = 2014 \| pmid = 24442756 \| pmc = 4009342 \| doi = 10.1007/s40263-014-0142-x }}</ref> However, none have sufficient evidence or regulatory approval for routine clinical use, so psychosocial interventions remain the mainstay of treatment.<ref name="Kampman_2019" /> Traffickers have also started using a method whereby a substance such as [[iron thiocyanate]],<ref name="pagliaros"/> a mixture of [[cobalt]] and [[ferric chloride]],<ref>{{cite paper \| author=[[Australian Bureau of Criminal Intelligence]] \| title=Australian Illicit Drug Report 1998–99 \| date=1999 \| url=http://www.crimecommission.gov.au/content/publications/aidr_2000/05_Cocaine.pdf \|curly=true}}</ref> or a mixture of [[charcoal]] and [[iron filings]] <ref name="stevemacko">{{cite news \| first=Steve \| last=Macko \| title=Colombia's new breed of drug trafficker \| date=Friday, July 17, 1998 \| publisher=Emergency Response and Research Institute, Chicago \| url=http://www.emergency.com/clmbdeal.htm }}</ref> is added to cocaine hydrochloride to produce “black cocaine.” The cocaine in this substance is not detected by standard chemical tests such as the [[Becton Dickinson test]] kit. The substance was first identified after a seizure in March 1998 in Germany, which was then tracked back to discover 250 lb of black cocaine ready for transport at [[Bogotá]]’s airport. <ref name="stevemacko"/> ==== ~~Availability~~Cocaine nose ==== {{Redirect\|Cocaine nose\|the Playboi Carti song\|Cocaine Nose (song)}} Cocaine is readily available in all major countries' metropolitan areas. According to the ''Summer 1998 Pulse Check,'' published by the U.S. [[Office of National Drug Control Policy]], cocaine use had stabilized across the country, with a few increases reported in [[San Diego]], [[Bridgeport, Connecticut\|Bridgeport]], [[Miami, Florida\|Miami]], and [[Boston, Massachusetts\|Boston]]. In the West, cocaine usage was lower, which was thought to be because some users were switching to [[methamphetamine]], which was cheaper and provides a longer-lasting high. Numbers of cocaine users are still very large, with a concentration among city-dwelling youth. [[File:Cocaine nose.jpg\|thumb\|200px\|[[Nasal septum perforation]] caused by cocaine insufflation (pictured) can progress to [[cocaine-induced midline destructive lesions]]]] "Cocaine nose" or "coke nose" are informal terms that refer to nose disorders resulting from repeated or chronic cocaine use.<ref name="Berberi_2024">{{cite journal \| vauthors = Berberi A, Azar E \| title = Oral Rehabilitation for a Patient with Cocaine-Induced Midline Destructive Lesions \| journal = Case Reports in Otolaryngology \| volume = 2024 \| article-number = 7109261 \| date = 2024 \| pmid = 38939732 \| pmc = 11208820 \| doi = 10.1155/2024/7109261 \| doi-access = free }}</ref><ref name="Jalali_2023">{{cite journal \| vauthors = Jalali A \| title = Cocaine Nose Correction: A Nonsurgical Approach Using a Novel Hyaluronic Acid Filler \| journal = Plastic and Reconstructive Surgery. Global Open \| volume = 11 \| issue = 10 \| pages = e5329 \| date = October 2023 \| pmid = 37817926 \| pmc = 10561808 \| doi = 10.1097/GOX.0000000000005329 }}</ref><ref name="Taams_2022">{{cite journal \| vauthors = Taams KO, Taams SJ \| title = The Bilateral Trans Alar Forehead Flap to Reconstruct the Cocaine Nose: A Case Report \| journal = Plastic and Reconstructive Surgery. Global Open \| volume = 10 \| issue = 1 \| pages = e4044 \| date = January 2022 \| pmid = 35083102 \| pmc = 8785930 \| doi = 10.1097/GOX.0000000000004044 }}</ref><ref name="Chatzaraki_2019">{{cite journal \| vauthors = Chatzaraki V, Schweitzer W, Thali MJ, Ampanozi G \| title = Nasal Septum Defects Detected on Postmortem Computed Tomography \| journal = The American Journal of Forensic Medicine and Pathology \| volume = 40 \| issue = 3 \| pages = 279–284 \| date = September 2019 \| pmid = 30985333 \| doi = 10.1097/PAF.0000000000000482 \| url = https://www.zora.uzh.ch/id/eprint/171280/1/thali_nasalseptum_verlag.pdf }}</ref> Cocaine is typically sold to users by the gram ($50-$120US) or eight ball (3.5 grams, or roughly 1/8th oz; hence the term "eight ball") ($100-$300). Quality and price can vary dramatically depending on demand and supply. About 30% of people who had snorted cocaine at least 25 times but less than daily, and 47% of daily users, reported experiencing nasal irritation, crusting or scabbing, and frequent nosebleeds. Cocaine use should be considered as a potential cause of persistent or unexplained [[rhinitis]], including in adolescent patients.<ref>{{cite journal \| vauthors = Schwartz R, Estroff T, Fairbanks D, Hoffmann N \| title = Nasal symptoms associated with cocaine abuse during adolescence. \| journal = Archives of Otolaryngology–Head & Neck Surgery \| volume = 115 \| issue = 1 \| pages = 63–64 \| date = January 1989 \| pmid = 2909232 \| doi = 10.1001/archotol.1989.01860250065028 }}</ref> ~~===Consumption===~~ ~~<font size = green size = 4>Usually about 5 lines a day shouldn't cause to much harm.~~ <font size = 2 color = black>World annual cocaine consumption currently stands at around 600 [[metric ton]]s, with the [[United States]] consuming around 300 metric tons, 50% of the total, Europe about 150 metric tons, 25% of the total, and the rest of the world the remaining 150 metric tons or 25%. [http://www.dod.mil/policy/sections/policy_offices/solic/cn/cocaine2.pdf] Because the nose is a prominent facial feature, such visible damage often leads to embarrassment, stigma, and negative reactions from others. As a result, individuals with cocaine-induced nasal damage frequently withdraw from social activities and relationships, leading to [[social isolation]]. In many cases, this isolation is not just likely but almost inevitable, as affected individuals may feel unable to face the outside world due to the noticeable and sometimes severe changes to their appearance.<ref name="fraser-nose-the-irreparable-damage-cocaine-use-can-do">{{cite web \|title=Fraser 'Nose' The Irreparable Damage Cocaine Use Can Do \| work = National Health Service (NHS) Lanarkshire \|url=https://www.nhslanarkshire.scot.nhs.uk/fraser-nose-the-irreparable-damage-cocaine-use-can-do/ }}</ref><ref name="BBC_2023">{{cite news \|title=Patients face losing noses due to cocaine use, medics warn \|url=https://www.bbc.com/news/uk-scotland-glasgow-west-64901125 \|date=9 March 2023 \| work = [[BBC]] }}</ref> According to the [[United Nations]] [[United Nations Office on Drugs and Crime\|Office on Drugs and Crime]] 2006 World Drug Report, the [[United States]] has the world's greatest rate of cocaine consumption by people aged 15 to 64, 2.8%. It is closely followed by [[Spain]] with 2.7%, and England & Wales with 2.4%. Most [[Western European]] countries have a consumption rate between 1% and 2%. [http://www.unodc.org/pdf/WDR_2006/wdr2006_volume2.pdf] Nose disorders associated with cocaine nose include: ~~== Usage ==~~ [[Cocaine-induced midline destructive lesions]] (CIMDL)<ref name="Di_Cosola_2021" /> ~~{{worldwide}}~~ * [[Nasal septum perforation]]<ref name="Di_Cosola_2021" /> * [[Palate]] perforation<ref>{{cite journal \| vauthors = Maloney B, Hinchion K, Conlon N, Omer O, Pierse D \| title = Cocaine-induced destruction of the palate: a diagnostic and management challenge \| journal = British Dental Journal \| volume = 237 \| issue = 6 \| pages = 465–471 \| date = September 2024 \| pmid = 39333814 \| pmc = 11436349 \| doi = 10.1038/s41415-024-7834-5 }}</ref><ref>{{cite journal \| vauthors = Trimarchi M, Bondi S, Della Torre E, Terreni MR, Bussi M \| title = Palate perforation differentiates cocaine-induced midline destructive lesions from granulomatosis with polyangiitis \| journal = Acta Otorhinolaryngologica Italica \| volume = 37 \| issue = 4 \| pages = 281–285 \| date = August 2017 \| pmid = 28663599 \| pmc = 5584099 \| doi = 10.14639/0392-100X-1586 }}</ref> * [[Saddle nose]]<ref name="Schreiber_2014">{{cite journal \| vauthors = Schreiber BE, Twigg S, Marais J, Keat AC \| title = Saddle-nose deformities in the rheumatology clinic \| journal = Ear, Nose, & Throat Journal \| volume = 93 \| issue = 4–5 \| pages = E45–E47 \| date = April–May 2014 \| pmid = 24817241 \| type = Review }}</ref> ===== Cocaine-induced midline destructive lesions ===== ~~=== In the United States ===~~ [[Cocaine-induced midline destructive lesions]] (CIMDL)<ref name="Nitro_2022">{{cite journal \| vauthors = Nitro L, Pipolo C, Fadda GL, Allevi F, Borgione M, Cavallo G, Felisati G, Saibene AM \| title = Distribution of cocaine-induced midline destructive lesions: systematic review and classification \| journal = European Archives of Oto-Rhino-Laryngology \| volume = 279 \| issue = 7 \| pages = 3257–3267 \| date = July 2022 \| pmid = 35138441 \| pmc = 9130192 \| doi = 10.1007/s00405-022-07290-1 }}</ref> is the progressive destruction of nasal architecture with the erosion of the [[palate]], [[Nasal Concha\|nasal conchae]], and [[ethmoid sinus]]es associated with prolonged [[Insufflation (medicine)\|insufflation]], colloquially 'snorting', of cocaine.<ref name="Di_Cosola_2021">{{cite journal \| vauthors = Di Cosola M, Ambrosino M, Limongelli L, Favia G, Santarelli A, Cortelazzi R, Lo Muzio L \| title = Cocaine-Induced Midline Destructive Lesions (CIMDL): A Real Challenge in Diagnosis \| journal = International Journal of Environmental Research and Public Health \| volume = 18 \| issue = 15 \| pages = 7831 \| date = July 2021 \| pmid = 34360121 \| pmc = 8345435 \| doi = 10.3390/ijerph18157831 \| doi-access = free }}</ref> ~~==== General usage ====~~ ~~<font color = red size = 4>Its pretty good for you.~~ ~~<gallery>~~ ~~Image:Example.jpg\|Caption1~~ ~~Image:Example.jpg\|Caption2~~ Chronic intranasal usage can degrade the [[cartilage]] separating the [[nostrils]] (the [[septum nasi]]), leading eventually to its complete disappearance.<ref name="Pagliaro_2004">{{Cite book\| vauthors = Pagliaro L, Pagliaro AM \|title=Pagliaros' Comprehensive Guide to Drugs and Substances of Abuse\|publisher=[[American Pharmacists Association]]\|___location=Washington, D.C.\|year=2004\|isbn=978-1-58212-066-9\|url=https://archive.org/details/pagliaroscompreh0000pagl}}</ref> ===== Causes ===== Cocaine has become the second most popular illegal recreational drug in the U.S.<ref>[http://www.erowid.org/chemicals/cocaine/cocaine.shtml erowid.org]</ref> Cocaine is commonly used in middle to upper class communities. It is also popular amongst college students, not just to aid in studying, but also as a party drug. Its users span over different ages, races, and professions. In the 1970s and 80's the drug became particularly popular in the [[disco]] culture as cocaine usage was very common and popular in many discos such as [[Studio 54]]. The cause of "cocaine nose" can be traced to the chemical process that occurs when cocaine hydrochloride is insufflated (snorted). As cocaine is absorbed through the [[nasal mucosa]], the remaining hydrochloride component forms a dilute [[hydrochloric acid]].<ref name="Pagliaro_2004" /> The short half-life of cocaine,<ref name="Treadwell_2007" /> combined with binge use, may expose the nasal tissues to this acidic environment more frequently, increasing the risk of irritation and damage. ===== Treatment ===== The National Household Survey on Drug Abuse (NHSDA) reported in [[1999]] that cocaine was used by 3.7 million Americans, or 1.7 percent of the household population age 12 and older. Estimates of the current number of those who use cocaine regularly (at least once per month) vary, but 1.5 million is a widely accepted figure within the research community. For people with cocaine abuse, mild symptoms may resolve completely with total abstinence from cocaine, making early involvement of addiction services essential.<ref>{{cite journal \| vauthors = Hansen FV, Kiehn OT, Lomholt AF, Ringdom H, Aanæs K \| title = [Not Available] \| journal = Ugeskrift for Laeger \| volume = 185 \| issue = 40 \| date = October 2023 \| pmid = 37874002 }}</ref> Repair may involve [[rhinoplasty]], which includes creating a new internal lining with nasolabial flaps and restoring support with costal cartilage grafts.<ref>{{cite journal \| vauthors = Millard DR, Mejia FA \| title = Reconstruction of the nose damaged by cocaine \| journal = Plastic and Reconstructive Surgery \| volume = 107 \| issue = 2 \| pages = 419–424 \| date = February 2001 \| pmid = 11214057 \| doi = 10.1097/00006534-200102000-00018 }}</ref> Although cocaine use had not significantly changed over the six years prior to 1999, the number of first-time users went up from 574,000 in 1991, to 934,000 in 1998 — an increase of 63%. While these numbers indicated that cocaine is still widely present in the United States, cocaine use was significantly less prevalent than it was during the early 1980s. Cocaine use peaked in [[1982]] when 10.4 million Americans (5.6 percent of the population) reportedly used the drug{{Fact\|date=February 2007}}. In 2024, Belgian doctors report a rise in patients needing nose reconstruction due to cocaine use, which damages nasal tissue and cartilage; however, few undergo surgery because it requires at least six months of abstinence from cocaine for proper healing.<ref>{{cite news \| vauthors = Min R \|title=Doctors in Belgium see serious nose lesions amid rising cocaine use \|url=https://www.euronews.com/health/2024/03/28/more-people-in-belgium-need-nose-reconstruction-due-to-cocaine-use-doctors-say \|work=euronews \|date=28 March 2024 \|language=en}}</ref> ~~==== Usage among youth ====~~ Some individuals seek [[plastic surgery]] to repair or reconstruct nasal damage caused by cocaine use, although surgical outcomes can be complicated by ongoing tissue loss and poor healing. When nasal damage is too severe for reconstruction, a [[nose prosthesis]] may be used to restore appearance and [[quality of life]].<ref name="fraser-nose-the-irreparable-damage-cocaine-use-can-do" /><ref name="BBC_2023" /> The [[1999]] [[Monitoring the future\|Monitoring the Future]] (MTF) survey found the proportion of American students reporting use of powder cocaine rose during the 1990s. In [[1991]], 2.3 percent of eighth-graders stated that they had used cocaine in their lifetime. This figure rose to 4.7 percent in 1999. For the older grades, increases began in 1992 and continued through the beginning of 1999. Between those years, lifetime use of cocaine went from 3.3 percent to 7.7 percent for tenth-graders and from 6.1 percent to 9.8 percent for twelfth-graders. Lifetime use of crack cocaine, according to MTF, also increased among eighth-, tenth-, and twelfth-graders, from an average of 2 percent in 1991 to 3.9 percent in 1999. == Overdose == Perceived risk and disapproval of cocaine and crack use both decreased during the 1990s at all three grade levels. The 1999 NHSDA found the highest rate of monthly cocaine use was for those aged 18–25 at 1.7 percent, an increase from 1.2 percent in 1997. Rates declined between 1996 and 1998 for ages 26–34, while rates slightly increased for the 12–17 and 35+ age groups. Studies also show people are experimenting with cocaine at younger ages. NHSDA found a steady decline in the mean age of first use from 23.6 years in 1992 to 20.6 years in 1998. {{Main\|Cocaine intoxication}} [[File:Death rates from cocaine overdoses, OWID.svg\|thumb\|Death rates from cocaine overdoses]] ~~== Addiction ==~~ [[File:US timeline. Cocaine deaths.svg\|thumb\|upright=1.3\|US yearly overdose deaths involving cocaine.<ref name="NIDA-deaths">{{cite web \| url = http://www.drugabuse.gov/related-topics/trends-statistics/overdose-death-rates \| title = Overdose Death Rates \| work = [[National Institute on Drug Abuse]] (NIDA) \| date = 21 August 2024 }}</ref>]] ~~{{Expert-subject\|Medicine}}~~ According to the [[European Union Drugs Agency]], the estimated minimum lethal dose is 1.2 grams. However, sensitive individuals have died from as little as 30 milligrams applied to mucous membranes-an amount that is 40 times less than the minimum lethal dose. In contrast, addicts may tolerate doses as high as 5 grams per day.<ref name="EUDA" /> '''Cocaine addiction''' is the excessive intake of cocaine, and can result in physiological damage, lethargy, depression, or a potentially fatal overdose. The immediate craving to use more cocaine is strong and very common, because euphoric effects usually subside in most users within an hour of the last dosage, leading to serial cocaine readministrations, and prolonged, multi-dose binge use in those who are addicted. When administration stops after binge use, it is followed by a "crash" (also known as a "come down"), the onset of severely dysphoric mood with escalating exhaustion until sleep is achieved, which is sometimes accomplished by taking sleeping medications, or [[sedative]]s, a popular one being [[Quetiapine\|Seroquel]]. Resumption of use may occur upon awakening or may not occur for several days, but the intense euphoria of such use can, as it has in many users, produce intense craving and develop rather quickly into addiction. The risk<ref>{{cite journal\|author=O'Brien MS, Anthony JC\|title=Risk of becoming cocaine dependent: epidemiological estimates for the United States, 2000-2001.\|url=http://www.nature.com/npp/journal/v30/n5/full/1300681a.html\|year=2005\|PMID=15785780\|journal=Neuropsychopharmacology\|volume=30\|pages=1006–1018\|curly=true}}</ref> of becoming cocaine-dependent within 2 years of first use(recent-onset) is 5-6%; after 10 years, it's 15-16%. These are the aggregate rates for all types of use considered, i.e., smoking, snorting, injecting. Among recent-onset users, the ''relative'' rates are higher for smoking (3.4 times) and much higher for injecting (31 times). They also vary, based on other characteristics, such as gender: among recent-onset users, females are 3.3 times more likely to become addicted, compared to males; age: among recent-onset users, those who started using at ages 12 or 13 were 4 times as likely to become addicted, compared to those who started between ages 18 and 20; and race: among recent-onset users, non-Hispanic Blacks are 7 times as likely to become addicted, compared to non-Hispanic Whites. Many habitual abusers develop a transient manic-like condition similar to [[amphetamine psychosis]] and [[schizophrenia]], whose symptoms include aggression, severe paranoia, and tactile hallucinations (including the feeling of insects under the skin, or "coke bugs") during binges.<ref>{{cite journal \| author=Gawin. FH. \| title=Cocaine addiction: Psychology and neurophysiology \| journal=[[Science]] \| year= 1991 \| volume=251\|pages=1580–1586 \|url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=2011738&query_hl=18 \|curly=true}}</ref> Cocaine can be snorted, swallowed, injected, or smoked. Most deaths due to cocaine are accidental but may also be the result of [[Mule (smuggling)\|body packing or stuffing]] with rupture in the gastrointestinal tract. Alcohol impairment increases the likelihood of risk-taking behaviors and susceptibility to [[peer pressure]], and also raises the risk of overdose due to the formation of [[cocaethylene]] (see the [[#Alcohol\|alcohol]] section). Cocaine has positive reinforcement effects, which refers to the effect that certain stimuli have on behavior. Good feelings become associated with the drug, causing a frequent user to take the drug as a response to bad news or mild [[depression (mood)\|depression]]. This activation strengthens the response that was just made. If the drug was taken by a fast acting route such as injection or inhalation, the response will be the act of taking more cocaine, so the response will be reinforced. Powder cocaine, being a [[club drug]] is mostly consumed in the evening and night hours. Because cocaine is a [[stimulant]], a user will often drink large amounts of [[alcohol]] during and after usage or smoke [[cannabis]] to dull "crash" or "come down" effects and hasten slumber. [[Benzodiazepines]] (e.g., xanax<sup>®</sup>, rohypnol<sup>®</sup>) are also used for this purpose. Other drugs such as [[heroin]] and various pharmaceuticals are often used to amplify reinforcement or to minimize such negative effects, further increasing addiction potential and harmfulness. Use of cocaine causes [[cardiac arrhythmia\|abnormally fast heart rhythms]] and a marked elevation of blood pressure ([[hypertension]]), which can be life-threatening. This can lead to death from acute [[myocardial infarction]], acute [[respiratory failure]] (i.e., [[hypoxemia]], with or without [[hypercapnia]]), [[stroke]], [[cerebral hemorrhage]], and [[Cardiac arrest\|sudden cardiac arrest]].<ref>{{cite journal \| vauthors = O'Leary ME, Hancox JC \| title = Role of voltage-gated sodium, potassium and calcium channels in the development of cocaine-associated cardiac arrhythmias \| journal = British Journal of Clinical Pharmacology \| volume = 69 \| issue = 5 \| pages = 427–442 \| date = May 2010 \| pmid = 20573078 \| pmc = 2856043 \| doi = 10.1111/j.1365-2125.2010.03629.x }}</ref> Overdose can also cause acute [[hepatotoxicity]]—typically due to toxic metabolites—though most cases resolve quickly; however, fatal outcomes from [[multiple organ dysfunction syndrome]] are possible, and there is no specific antidote.<ref>{{cite journal \| vauthors = \| title = Cocaine \| journal = LiverTox: Clinical and Research Information on Drug-Induced Liver Injury [Internet]. \| ___location = Bethesda (MD) \| publisher = National Institute of Diabetes and Digestive and Kidney Diseases \| date = 2017 \| pmid = 31643773 \| url = https://www.ncbi.nlm.nih.gov/books/NBK548454/ }}</ref> Cocaine overdose may result in [[hyperthermia]] as stimulation and increased muscular activity cause greater heat production. Heat loss is also inhibited by the cocaine-induced [[vasoconstriction]]. It has been shown in studies that [[rhesus monkeys]] provided with a mechanism of cocaine self-administration prefer the drug over food that is in the cage. This happens even when the monkeys are starving.<ref>{{cite journal\|author=Aigner TG, Balster RL\|title=Choice behavior in rhesus monkeys: cocaine versus food\|url=http://www.sciencemag.org/cgi/content/abstract/201/4355/534\|volume=Science 201\|pages=534-535\|curly=true}}</ref> In 2024, drug-related deaths in England and Wales reached their highest level in three decades, with a notable increase in fatalities involving cocaine and experts urging urgent government intervention to address the crisis. Martin Powell, from the charity Transform, which campaigns for the [[drug liberalization\|legal regulation of drugs]], suggested that the recent rise in cocaine-related deaths in the UK may be due to the increased purity of cocaine, leading users to consume it more frequently and alongside other substances.<ref>{{cite news \| vauthors = Lawrie E \|title=Cocaine use fuels record high in drug deaths \|url=https://www.bbc.com/news/articles/cy5l4nknew0o \|work=www.bbc.com \|date=23 October 2024}}</ref> It is speculated that cocaine's addictive properties stem partially from its [[DAT]]-blocking effects (in particular, increasing the dopaminergic transmission from [[ventral tegmental area]] neurons). However, a study has shown that mice with no dopamine transporters still exhibit the rewarding effects of cocaine administration.<ref>{{cite journal \| author=Sora, ''et al.'' \| title=Cocaine reward models: Conditioned place preference can be established in dopamine- and in serotonin-transporter knockout mice \| journal=[[PNAS]] \| year=June 23, 1998 \| volume=95\|issue=13 \|pages=7600–7704 \|url=http://www.pnas.org/cgi/content/full/95/13/7699 \|curly=true}}</ref> Later work demonstrated that a combined DAT/SERT knockout eliminated the rewarding effects.<ref>{{cite journal \| author=Sora, ''et al.'' \| title=Molecular mechanisms of cocaine reward: Combined dopamine and serotonin transporter knockouts eliminate cocaine place preference \| journal=[[PNAS]] \| year=April 24, 2001 \| volume=98\|issue=9 \|pages=5300–5305 \|url=http://www.pnas.org/cgi/content/full/98/9/5300 \|curly=true}}</ref> The rewarding effects of cocaine are influenced by [[circadian rhythms]],<ref>{{cite journal \| author=Kurtuncu ''et al.'' \| title=Involvement of the pineal gland in diurnal cocaine reward in mice \| journal=European Journal of Pharmacology \| year=April 12, 2004 \| volume=489\|issue=3 \|pages=203–205 \|url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=15087244&query_hl=23 \|curly=true}}</ref> possibly by involving a set of genes termed "clock genes".<ref>{{cite journal \| author=Yuferov ''et al.'' \| title=Biological clock: biological clocks may modulate drug addiction \| journal=European Journal of Human Genetics \| year=October 2005 \| volume=13\|issue=10 \|pages=1101–1103 \|url=http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=Abstract&list_uids=16094306&query_hl=18 \|curly=true}}</ref> However, chronic cocaine addiction is not solely due to cocaine reward. Chronic repeated use is needed to produce cocaine-induced changes in brain reward centers and consequent chronic dysphoria (described above under "Effects and Health Issues - Chronic"). Dysphoria magnifies craving for cocaine because cocaine reward rapidly, albeit transiently, improves mood. This contributes to continued use and a self-perpetuating, worsening condition, since those addicted usually cannot appreciate that long-term effects are opposite those occurring immediately after use. === ~~Treatment~~Interactions === {{See also\|Combined drug intoxication}} === Alcohol === [[Cognitive Behavioral Therapy]] (CBT) shows promising results. One or more [[cocaine vaccine]]s exist or are on trial that will stop desirable effects from the drug. The National Institutes of Health of an unspecified country is researching [[modafinil]], a narcolepsy drug and mild stimulant, as a potential cocaine treatment. [[Twelve-step program]]s such as [[Cocaine Anonymous]] (modeled on [[Alcoholics Anonymous]]) are claimed by many cocaine addicts to be helpful in achieving long-term abstinence. These spiritual programs have no statistically-measurable effect as Alcoholics Anonymous does not release any quantifiable measure of its success rates. There are, however, many recovering addicts who claim this program has aided them. {{Main\|Cocaethylene}} {{See also\|Coca wine}} ~~==== GVG ====~~ [[Alcohol (drug)\|Alcohol]] interacts with cocaine ''in vivo'' to produce [[cocaethylene]], another psychoactive substance which may be substantially more [[cardiotoxic]] than either cocaine or alcohol by themselves.<ref>{{cite journal \|vauthors=Laizure SC, Mandrell T, Gades NM, Parker RB \|title=Cocaethylene metabolism and interaction with cocaine and ethanol: role of carboxylesterases \|journal=Drug Metabolism and Disposition \|volume=31 \|issue=1 \|pages=16–20 \|date=January 2003 \|pmid=12485948 \|doi=10.1124/dmd.31.1.16}}</ref><ref>{{cite journal \|vauthors=Pergolizzi J, Breve F, Magnusson P, LeQuang JA, Varrassi G \|title=Cocaethylene: When Cocaine and Alcohol Are Taken Together \|journal=Cureus \|volume=14 \|issue=2 \|date=February 2022 \|pages=e22498 \|pmid=35345678 \|pmc=8956485 \|doi=10.7759/cureus.22498 \|doi-access=free}}</ref> In 2024, a systematic review of human studies concluded that, despite some inconsistencies in the findings, the co-use of cocaine and alcohol poses a significantly greater risk of cardiovascular fatalities compared to cocaine use alone. This elevated risk is largely attributed to the formation of cocaethylene, a unique and toxic metabolite produced only when both substances are consumed together. Cocaethylene is associated with an 18- to 25-fold increased risk of sudden death, as well as a higher incidence of myocardial injury and cardiac arrest, underscoring the serious health risks of simultaneous cocaine and alcohol use.<ref>{{cite journal \| vauthors = van Amsterdam J, Gresnigt F, van den Brink W \| title = Cardiovascular Risks of Simultaneous Use of Alcohol and Cocaine-A Systematic Review \| journal = Journal of Clinical Medicine \| volume = 13 \| issue = 5 \| page = 1475 \| date = March 2024 \| pmid = 38592322 \| pmc = 10935323 \| doi = 10.3390/jcm13051475 \| doi-access = free }}</ref> [[Image:Dopamine_monkey.png\|300px\|right\|thumb\|[[Positron Emission Tomography]] scans showing the average level of dopamine receptors in six primates' brains. Red is high- and blue is low-concentration of dopamine receptors. The higher the level of dopamine, the fewer receptors there will be.]] === MAOIs === Studies have shown that [[gamma vinyl-gamma-aminobutyric acid]] (gamma vinyl-GABA, or GVG), a drug normally used to treat [[epilepsy]], blocks cocaine's action in the [[brain]]s of [[primate]]s. GVG increases the amount of the neurotransmitter [[gamma-aminobutyric acid\|GABA]] in the brain and reduces the level of [[dopamine]] in the region of the brain that is thought to be involved in addiction. In January [[2005]] the [[U.S. Food and Drug Administration]] gave permission for a Phase I [[clinical trial]] of GVG for the treatment of addiction. Another drug currently tested for anti-addictive properties is the cannabinoid antagonist [[rimonabant]]. [[Monoamine oxidase inhibitor]]s (MAOIs) should not be combined with other psychoactive substances (antidepressants, painkillers, stimulants, including prescribed, OTC and illegally acquired drugs, etc.) except under expert care.{{citation needed\|date=June 2025}} ==== ~~GBR~~Opioids ~~12909 =~~=== {{See also\|Speedball (drug)\|Opioid epidemic in the United States}} The [[opioid epidemic]] now involves more overdose deaths with both opioids and cocaine, especially among non-Hispanic Blacks who are twice as likely to die from combined opioid-stimulant overdoses compared to non-Hispanic whites. Cocaine-related deaths in Blacks are similar to opioid deaths in whites. Risk factors include young age, education, urban living, mental disorders, and stress. It remains unclear if co-use is intentional. Recent studies expand focus beyond heroin to all opioids, reflecting changing overdose patterns.<ref>{{cite journal \| vauthors = Liu X, Singer ME \| title = Intentional use of both opioids and cocaine in the United States \| journal = Preventive Medicine Reports \| volume = 33 \| article-number = 102227 \| date = June 2023 \| pmid = 37223567 \| pmc = 10201855 \| doi = 10.1016/j.pmedr.2023.102227 }}</ref> == Pharmacology == GBR 12909 ([[Vanoxerine]]) is a [[dopamine reuptake inhibitor\|selective dopamine uptake inhibitor]]. Because of this, it reduces cocaine's effect on the brain, and may help to treat cocaine addiction. Studies have shown that GBR, when given to primates, suppresses cocaine self-administration. ==== ~~Venlafaxine~~Pharmacokinetics ==== The extent of absorption of cocaine into the [[circulatory system]] after nasal insufflation is similar to that after oral ingestion. The rate of absorption after nasal insufflation is limited by cocaine-induced vasoconstriction of capillaries in the nasal mucosa. Onset of absorption after oral ingestion is delayed because cocaine is a weak base with a [[pKa]] of 8.6, and is thus in an ionized form that is poorly absorbed from the [[gastric acid]] and easily absorbed from the alkaline [[duodenum]].<ref name="Wilkinson_1980" /> The rate and extent of absorption from inhalation of cocaine is similar or greater than with intravenous injection, as inhalation provides access directly to the [[capillary]] bed. The delay in absorption after oral ingestion may account for the popular belief that cocaine bioavailability from the stomach is lower than after insufflation. Compared with ingestion, the faster absorption of insufflated cocaine results in quicker attainment of maximum drug effects. Snorting cocaine produces maximum physiological effects within 40 minutes and maximum psychotropic effects within 20 minutes. Physiological and psychotropic effects from nasally insufflated cocaine are sustained for approximately 40–60 minutes after the peak effects are attained.<ref>{{Cite journal \| vauthors = Barnett G, Hawks R, Resnick R \| title = Cocaine pharmacokinetics in humans \| journal = Journal of Ethnopharmacology \| volume = 3 \| issue = 2–3 \| pages = 353–66 \| year = 1981 \| pmid = 7242115 \| doi = 10.1016/0378-8741(81)90063-5 }}; Jones, supra note 19; Wilkinson ''et al.'', Van Dyke ''et al.''</ref> Cocaine crosses the [[blood–brain barrier]] via both a proton-coupled [[Organic cation transport protein\|organic cation antiporter]]<ref name="How do psychostimulants enter the h">{{Cite journal \| vauthors = Sachkova A, Doetsch DA, Jensen O, Brockmöller J, Ansari S \| title = How do psychostimulants enter the human brain? Analysis of the role of the proton-organic cation antiporter \| journal = Biochemical Pharmacology \| volume = 192 \| article-number = 114751 \| date = October 2021 \| pmid = 34464621 \| doi = 10.1016/j.bcp.2021.114751 }}</ref><ref name="Structural Requirements for Uptake">{{Cite journal \| vauthors = Tega Y, Tabata H, Kurosawa T, Kitamura A, Itagaki F, Oshitari T, Deguchi Y \| title = Structural Requirements for Uptake of Diphenhydramine Analogs into hCMEC/D3 Cells Via the Proton-Coupled Organic Cation Antiporter \| journal = Journal of Pharmaceutical Sciences \| volume = 110 \| issue = 1 \| pages = 397–403 \| date = January 2021 \| pmid = 32898521 \| doi = 10.1016/j.xphs.2020.09.001 \| doi-access = free \| bibcode = 2021JPhmS.110..397T }}</ref> and (to a lesser extent) via [[Passive transport\|passive diffusion across cell membranes]].<ref name="Chapy_2014">{{Cite journal \| vauthors = Chapy H, Smirnova M, André P, Schlatter J, Chiadmi F, Couraud PO, Scherrmann JM, Declèves X, Cisternino S \| title = Carrier-mediated cocaine transport at the blood–brain barrier as a putative mechanism in addiction liability \| journal = The International Journal of Neuropsychopharmacology \| volume = 18 \| issue = 1 \| pages = pyu001 \| date = October 2014 \| pmid = 25539501 \| pmc = 4368859 \| doi = 10.1093/ijnp/pyu001 }}</ref> As of September 2022, the gene or genes encoding the human proton-organic cation antiporter had not been identified.<ref>{{Cite journal \| vauthors = Sachkova A, Jensen O, Dücker C, Ansari S, Brockmöller J \| title = The mystery of the human proton-organic cation antiporter: One transport protein or many? \| journal = Pharmacology & Therapeutics \| article-number = 108283 \| date = September 2022 \| volume = 239 \| pmid = 36162727 \| doi = 10.1016/j.pharmthera.2022.108283 \| s2cid = 252527522 \| url = https://resolver.sub.uni-goettingen.de/purl?gro-2/117956 }}</ref> [[Venlafaxine]] ([[Effexor<sup>®</sup>]]), although not a dopamine re-uptake inhibitor, is a serotonin-norepinephrine reuptake inhibitor that has been successfully used to combat the depression caused by cocaine withdrawal and to a lesser extent, the addiction associated with the drug itself. Venlafaxine has been shown to have significant withdrawal problems itself, and can lead to lifetime use due to these withdrawal effects. A statistically significant number of people prescribed Effexor<sup>®</sup> have committed suicide (2 attempts per 1000 patients, vs 1.56 suicides per 1,000 untreated depressives) (Reference needed) Cocaine has a short elimination half-life of 0.7–1.5 hours and is extensively [[metabolism\|metabolized]] by [[Blood plasma\|plasma]] esterases and also by liver [[cholinesterase]]s, with only about 1% excreted unchanged in the urine.<ref name="Zimmerman_2012" /> The metabolism is dominated by [[hydrolysis\|hydrolytic]] [[ester]] cleavage, so the eliminated metabolites consist mostly of [[benzoylecgonine]] (BE), the major [[metabolite]], and other metabolites in lesser amounts such as ecgonine methyl ester (EME) and [[ecgonine]].<ref>{{Cite journal \| vauthors = Ambre J, Ruo TI, Nelson J, Belknap S \| title = Urinary excretion of cocaine, benzoylecgonine, and ecgonine methyl ester in humans \| journal = Journal of Analytical Toxicology \| volume = 12 \| issue = 6 \| pages = 301–6 \| date = November 1988 \| pmid = 3244269 \| doi = 10.1093/jat/12.6.301 }}</ref><ref name="Zimmerman_2012" /> Further minor metabolites of cocaine include [[norcocaine]], p-hydroxycocaine, m-hydroxycocaine, p-hydroxybenzoylecgonine ({{chem name\|pOHBE}}), and m-hydroxybenzoylecgonine.<ref>{{Cite journal \| vauthors = Kolbrich EA, Barnes AJ, Gorelick DA, Boyd SJ, Cone EJ, Huestis MA \| title = Major and minor metabolites of cocaine in human plasma following controlled subcutaneous cocaine administration \| journal = Journal of Analytical Toxicology \| volume = 30 \| issue = 8 \| pages = 501–10 \| date = October 2006 \| pmid = 17132243 \| doi = 10.1093/jat/30.8.501 \| url = https://openurl.ingenta.com/content/nlm?genre=article&issn=0146-4760&volume=30&issue=8&spage=501&aulast=Kolbrich \| url-status = dead \| doi-access = free \| archive-url = https://archive.today/20120718083717/http://openurl.ingenta.com/content/nlm?genre=article&issn=0146-4760&volume=30&issue=8&spage=501&aulast=Kolbrich \| archive-date = 18 July 2012 }}</ref> ~~== References ==~~ Depending on [[liver]] and [[kidney]] functions, cocaine metabolites are detectable in urine between three and eight days. Generally speaking [[benzoylecgonine]] is eliminated from someone's urine between three and five days. In urine from heavy cocaine users, benzoylecgonine can be detected within four hours after intake and in concentrations greater than 150 ng/mL for up to eight days later.<ref>{{cite web\|title=Schaffer Library of Drug Policy: Urine Testing for Cocaine\|access-date=3 April 2025\|url=https://www.druglibrary.drugsense.org/schaffer/cocaine/clearurine.htm}}</ref> ~~<div class="references-small"><references/></div>~~ === Detection in the body === ==== Body fluids ==== Cocaine and its major metabolites may be quantified in blood, plasma, or urine to monitor for use, confirm a diagnosis of poisoning, or assist in the forensic investigation of a traffic or other criminal violation or sudden death. Most commercial cocaine [[immunoassay]] screening tests cross-react appreciably with the major cocaine metabolites, but [[chromatography\|chromatographic]] techniques can easily distinguish and separately measure each of these substances. When interpreting the results of a test, it is important to consider the cocaine usage history of the individual, since a chronic user can develop tolerance to doses that would incapacitate a cocaine-naive individual, and the chronic user often has high baseline values of the metabolites in his system. Cautious interpretation of testing results may allow a distinction between passive or active usage, and between smoking versus other routes of administration.<ref>{{cite book \| vauthors = Baselt R \| title = Disposition of Toxic Drugs and Chemicals in Man \| edition = 9th \| publisher = Biomedical Publications \| ___location = Seal Beach, California \|year = 2011 \|pages = 390–394 }}</ref> ==== Hair ==== [[Hair analysis]] can detect cocaine [[metabolite]]s in regular users until after the sections of hair grown during the period of cocaine use are cut or fall out.<ref>{{Cite web\|url=https://www.chemistryviews.org/details/news/8693061/Cocaine_Metabolites_in_Hair.html\|title=Cocaine Metabolites in Hair\|vauthors=Czykanski M\|date=30 December 2015\|website=Chemistry Views\|access-date=22 July 2019\|archive-date=22 July 2019\|archive-url=https://web.archive.org/web/20190722212558/https://www.chemistryviews.org/details/news/8693061/Cocaine_Metabolites_in_Hair.html\|url-status=live}}</ref> === Pharmacodynamics === Cocaine acts as a [[serotonin–norepinephrine–dopamine reuptake inhibitor]] (SNDRI).<ref name="Azizi_2022" /><ref name="Cheng_2015" /> Cocaine increases levels of [[serotonin]], [[norepinephrine]], and [[dopamine]] in the synaptic cleft, leading to heightened post-synaptic activation, with dopamine contributing to euphoria and arousal, and the other monoamines enhancing additional effects.<ref name="Azizi_2022" /><ref>{{Cite journal \| vauthors = Proebstl L, Kamp F, Manz K, Krause D, Adorjan K, Pogarell O, Koller G, Soyka M, Falkai P, Kambeitz J \| title = Effects of stimulant drug use on the dopaminergic system: A systematic review and meta-analysis of in vivo neuroimaging studies \| journal = European Psychiatry \| volume = 59 \| pages = 15–24 \| date = June 2019 \| pmid = 30981746 \| doi = 10.1016/j.eurpsy.2019.03.003 \| doi-access = free }}</ref><ref>{{Cite web\|url=https://www.drugabuse.gov/publications/research-reports/cocaine/how-does-cocaine-produce-its-effects\|title=How does cocaine produce its effects?\|access-date=12 May 2021\|archive-date=18 January 2022\|archive-url=https://web.archive.org/web/20220118113925/https://www.drugabuse.gov/publications/research-reports/cocaine/how-does-cocaine-produce-its-effects\|url-status=dead}}</ref><ref>{{Cite journal \| vauthors = Wise RA, Robble MA \| title = Dopamine and Addiction \| journal = Annual Review of Psychology \| volume = 71 \| issue = 1 \| pages = 79–106 \| date = January 2020 \| pmid = 31905114 \| doi = 10.1146/annurev-psych-010418-103337 \| doi-access = free }}</ref> The [[pharmacodynamics]] of cocaine involve the complex relationships of neurotransmitters (inhibiting [[monoamine]] uptake in rats with ratios of about: [[5HT\|serotonin]]:dopamine = 2:3, serotonin:[[norepinephrine]] = 2:5).<ref>{{Cite journal \| vauthors = Rothman RB, Baumann MH, Dersch CM, Romero DV, Rice KC, Carroll FI, Partilla JS \| title = Amphetamine-type central nervous system stimulants release norepinephrine more potently than they release dopamine and serotonin \| journal = Synapse \| volume = 39 \| issue = 1 \| pages = 32–41 \| date = January 2001 \| pmid = 11071707 \| doi = 10.1002/1098-2396(20010101)39:1<32::AID-SYN5>3.0.CO;2-3 \| s2cid = 15573624 }} (Table V. on page 37)</ref><ref name="Pom_2012" /> The most extensively studied effect of cocaine on the [[central nervous system]] is the blockade of the [[dopamine transporter]] protein. Dopamine [[neurotransmitter]] released during neural signaling is normally recycled via the transporter; i.e., the transporter binds the transmitter and pumps it out of the synaptic cleft back into the [[presynaptic]] [[neuron]], where it is taken up into storage [[vesicle (biology)\|vesicles]]. Cocaine binds tightly at the dopamine transporter forming a complex that blocks the transporter's function. The dopamine transporter can no longer perform its reuptake function, and thus [[dopamine]] accumulates in the [[synaptic cleft]]. The increased concentration of dopamine in the synapse activates post-synaptic dopamine receptors, which makes the drug [[Reward system\|rewarding]] and promotes the compulsive use of cocaine.<ref>{{Cite journal \| vauthors = Hummel M, Unterwald EM \| title = D1 dopamine receptor: a putative neurochemical and behavioral link to cocaine action \| journal = Journal of Cellular Physiology \| volume = 191 \| issue = 1 \| pages = 17–27 \| date = April 2002 \| pmid = 11920678 \| doi = 10.1002/jcp.10078 \| s2cid = 40444893 \| doi-access = free }}</ref> Cocaine affects certain serotonin (5-HT) receptors; in particular, it has been shown to [[receptor antagonist\|antagonize]] the [[5-HT3 receptor\|5-HT<sub>3</sub> receptor]], which is a [[ligand-gated ion channel]]. An overabundance of 5-HT<sub>3</sub> receptors is reported in cocaine-conditioned rats, though 5-HT<sub>3</sub>'s role is unclear.<ref>{{Cite journal \| vauthors = Carta M, Allan AM, Partridge LD, Valenzuela CF \| title = Cocaine inhibits 5-HT3 receptor function in neurons from transgenic mice overexpressing the receptor \| journal = European Journal of Pharmacology \| volume = 459 \| issue = 2–3 \| pages = 167–9 \| date = January 2003 \| pmid = 12524142 \| doi = 10.1016/S0014-2999(02)02867-4 }}</ref> The [[5-HT2 receptor\|5-HT<sub>2</sub> receptor]] (particularly the subtypes [[5-HT2A receptor\|5-HT<sub>2A</sub>]], [[5-HT2B receptor\|5-HT<sub>2B</sub>]] and [[5-HT2C receptor\|5-HT<sub>2C</sub>]]) are involved in the [[Locomotor activity\|locomotor-activating]] effects of cocaine.<ref>{{Cite journal \| vauthors = Filip M, Bubar MJ, Cunningham KA \| title = Contribution of serotonin (5-hydroxytryptamine; 5-HT) 5-HT2 receptor subtypes to the hyperlocomotor effects of cocaine: acute and chronic pharmacological analyses \| journal = The Journal of Pharmacology and Experimental Therapeutics \| volume = 310 \| issue = 3 \| pages = 1246–54 \| date = September 2004 \| pmid = 15131246 \| doi = 10.1124/jpet.104.068841 \| s2cid = 25809734 }}</ref> Cocaine has been demonstrated to bind as to directly stabilize the [[Dopamine transporter\|DAT]] transporter on the open outward-facing conformation. Further, cocaine binds in such a way as to inhibit a [[hydrogen bond]] innate to DAT. Cocaine's binding properties are such that it attaches so this hydrogen bond will not form and is blocked from formation due to the tightly locked orientation of the cocaine molecule. Research studies have suggested that the affinity for the transporter is not what is involved in the habituation of the substance so much as the conformation and binding properties to where and how on the transporter the molecule binds.<ref>{{Cite journal \| vauthors = Beuming T, Kniazeff J, Bergmann ML, Shi L, Gracia L, Raniszewska K, Newman AH, Javitch JA, Weinstein H, Gether U, Loland CJ \| title = The binding sites for cocaine and dopamine in the dopamine transporter overlap \| journal = Nature Neuroscience \| volume = 11 \| issue = 7 \| pages = 780–9 \| date = July 2008 \| pmid = 18568020 \| pmc = 2692229 \| doi = 10.1038/nn.2146 }}</ref> Conflicting findings have challenged the widely accepted view that cocaine functions solely as a reuptake inhibitor. To induce euphoria an intravenous dose of 0.3-0.6 mg/kg of cocaine is required, which blocks 66-70% of DAT in the brain.<ref>{{cite journal \| vauthors = Volkow ND, Wang GJ, Fischman MW, Foltin RW, Fowler JS, Abumrad NN, Vitkun S, Logan J, Gatley SJ, Pappas N, Hitzemann R, Shea CE \| title = Relationship between subjective effects of cocaine and dopamine transporter occupancy \| journal = Nature \| volume = 386 \| issue = 6627 \| pages = 827–830 \| date = April 1997 \| pmid = 9126740 \| doi = 10.1038/386827a0 \| bibcode = 1997Natur.386..827V }}</ref> Re-administering cocaine beyond this threshold does not significantly increase DAT occupancy but still results in an increase of euphoria which cannot be explained by reuptake inhibition alone. This discrepancy is not shared with other dopamine reuptake inhibitors like [[bupropion]], [[sibutramine]], [[mazindol]] or [[tesofensine]], which have similar or higher potencies than cocaine as dopamine reuptake inhibitors. Furthermore, a similar response-occupancy discrepancy has been observed with [[methylphenidate]], which also stabilizes the dopamine transporter in an open outward-facing conformation.<ref name="Heal_2014">{{cite journal \| vauthors = Heal DJ, Gosden J, Smith SL \| title = Dopamine reuptake transporter (DAT) "inverse agonism"--a novel hypothesis to explain the enigmatic pharmacology of cocaine \| journal = Neuropharmacology \| volume = 87 \| pages = 19–40 \| date = December 2014 \| pmid = 24953830 \| doi = 10.1016/j.neuropharm.2014.06.012 \| series = CNS Stimulants }}</ref><ref>{{cite journal \| vauthors = Volkow ND, Wang GJ, Fowler JS, Gatley SJ, Ding YS, Logan J, Dewey SL, Hitzemann R, Lieberman J \| title = Relationship between psychostimulant-induced "high" and dopamine transporter occupancy \| journal = Proceedings of the National Academy of Sciences of the United States of America \| volume = 93 \| issue = 19 \| pages = 10388–10392 \| date = September 1996 \| pmid = 8816810 \| pmc = 38394 \| doi = 10.1073/pnas.93.19.10388 \| doi-access = free }}</ref><ref>{{cite journal \| vauthors = Schmitt KC, Reith ME \| title = The atypical stimulant and nootropic modafinil interacts with the dopamine transporter in a different manner than classical cocaine-like inhibitors \| journal = PLOS ONE \| volume = 6 \| issue = 10 \| pages = e25790 \| date = 2011 \| pmid = 22043293 \| pmc = 3197159 \| doi = 10.1371/journal.pone.0025790 \| doi-access = free \| bibcode = 2011PLoSO...625790S }}</ref> These findings have evoked a hypothesis that cocaine may also function as a so-called "DAT inverse agonist" or "negative allosteric modifier of DAT" resulting in dopamine [[Reverse transport\|transporter reversal]], and subsequent dopamine release into the synaptic cleft from the axon terminal in a manner similar to but distinct from [[amphetamine]]s.<ref name="Heal_2014" /> [[Sigma receptor]]s are affected by cocaine, as cocaine functions as a sigma ligand agonist.<ref>{{cite journal \| vauthors = Zhu LX, Sharma S, Gardner B, Escuadro B, Atianzar K, Tashkin DP, Dubinett SM \| title = IL-10 mediates sigma 1 receptor-dependent suppression of antitumor immunity \| journal = Journal of Immunology \| ___location = Baltimore, Md. \| volume = 170 \| issue = 7 \| pages = 3585–91 \| date = April 2003 \| pmid = 12646621 \| doi = 10.4049/jimmunol.170.7.3585 }} {{lay source \|template=cite news \|url=https://www.sciencedaily.com/releases/2003/05/030506073758.htm \|title=Sigma Receptors Play Role in Cocaine-induced Suppression of Immune System \|date= 6 May 2003 \|work=ScienceDaily }}</ref> Further specific receptors it has been demonstrated to function on are [[NMDA]] and the D<sub>1</sub> dopamine receptor.<ref>{{Cite journal \| vauthors = Lluch J, Rodríguez-Arias M, Aguilar MA, Miñarro J \| title = Role of dopamine and glutamate receptors in cocaine-induced social effects in isolated and grouped male OF1 mice \| journal = Pharmacology Biochemistry and Behavior \| volume = 82 \| issue = 3 \| pages = 478–87 \| date = November 2005 \| pmid = 16313950 \| doi = 10.1016/j.pbb.2005.10.003 \| s2cid = 13307446 }}</ref> Cocaine also blocks [[ion channel\|sodium channels]], thereby interfering with the propagation of [[action potential]]s;<ref>{{Cite journal \| vauthors = Knuepfer MM \| title = Cardiovascular disorders associated with cocaine use: myths and truths \| journal = Pharmacology & Therapeutics \| volume = 97 \| issue = 3 \| pages = 181–222 \| date = March 2003 \| pmid = 12576134 \| doi = 10.1016/S0163-7258(02)00329-7 }}</ref><ref name="O'Leary_2010" /> thus, like [[lignocaine]] and [[novocaine]], it acts as a local anesthetic. It also functions on the binding sites to the dopamine and serotonin [[sodium]] dependent transport area as targets as separate mechanisms from its reuptake of those transporters; unique to its local anesthetic value which makes it in a class of functionality different from both its own derived [[phenyltropane]]s analogues which have that removed. In addition to this, cocaine has some target binding to the site of the [[κ-opioid receptor]].<ref>{{Cite web \|url=https://www.drugbank.ca/drugs/DB00907 \|title=Drugbank website "drug card", "(DB00907)" for Cocaine: Giving ten targets of the molecule in vivo, including dopamine/serotonin sodium channel affinity & K-opioid affinity \|publisher=Drugbank.ca \|access-date=9 March 2010 \|url-status=live \|archive-url=https://web.archive.org/web/20100220190540/https://www.drugbank.ca/drugs/DB00907 \|archive-date=20 February 2010 }}</ref>{{Unreliable medical source\|date=May 2025}} Cocaine also causes [[vasoconstriction]], thus reducing bleeding during minor surgical procedures. Recent research points to an important role of circadian mechanisms<ref>{{Cite journal \| vauthors = Uz T, Akhisaroglu M, Ahmed R, Manev H \| title = The pineal gland is critical for circadian Period1 expression in the striatum and for circadian cocaine sensitization in mice \| journal = Neuropsychopharmacology \| volume = 28 \| issue = 12 \| pages = 2117–23 \| date = December 2003 \| pmid = 12865893 \| doi = 10.1038/sj.npp.1300254 \| doi-access = free }}</ref> and [[clock genes]]<ref>{{Cite journal \| vauthors = McClung CA, Sidiropoulou K, Vitaterna M, Takahashi JS, White FJ, Cooper DC, Nestler EJ \| title = Regulation of dopaminergic transmission and cocaine reward by the Clock gene \| journal = Proceedings of the National Academy of Sciences of the United States of America \| volume = 102 \| issue = 26 \| pages = 9377–81 \| date = June 2005 \| pmid = 15967985 \| pmc = 1166621 \| doi = 10.1073/pnas.0503584102 \| bibcode = 2005PNAS..102.9377M \| doi-access = free }}</ref> in behavioral actions of cocaine. Cocaine is known to suppress hunger and appetite by increasing co-localization of sigma σ<sub>1</sub>R receptors and [[ghrelin]] GHS-R1a [[cell surface receptor]]s, thereby increasing ghrelin-mediated signaling of satiety<ref>{{Cite journal \| vauthors = Aguinaga D, Medrano M, Cordomí A, Jiménez-Rosés M, Angelats E, Casanovas M, Vega-Quiroga I, Canela EI, Petrovic M, Gysling K, Pardo L, Franco R, Navarro G \| title = Cocaine Blocks Effects of Hunger Hormone, Ghrelin, Via Interaction with Neuronal Sigma-1 Receptors \| journal = Molecular Neurobiology \| volume = 56 \| issue = 2 \| pages = 1196–1210 \| date = February 2019 \| pmid = 29876881 \| doi = 10.1007/s12035-018-1140-7 \| hdl-access = free \| s2cid = 46964405 \| hdl = 2445/127306 }}</ref> and possibly via other effects on appetitive hormones.<ref>{{Cite journal \| vauthors = Bouhlal S, Ellefsen KN, Sheskier MB, Singley E, Pirard S, Gorelick DA, Huestis MA, Leggio L \| title = Acute effects of intravenous cocaine administration on serum concentrations of ghrelin, amylin, glucagon-like peptide-1, insulin, leptin and peptide YY and relationships with cardiorespiratory and subjective responses \| journal = Drug and Alcohol Dependence \| volume = 180 \| pages = 68–75 \| date = November 2017 \| pmid = 28881319 \| pmc = 5654385 \| doi = 10.1016/j.drugalcdep.2017.07.033 }}</ref> Cocaine effects, further, are shown to be potentiated for the user when used in conjunction with new surroundings and stimuli, and otherwise novel environs.<ref>{{Cite journal \| vauthors = Carey RJ, Damianopoulos EN, Shanahan AB \| title = Cocaine effects on behavioral responding to a novel object placed in a familiar environment \| journal = Pharmacology Biochemistry and Behavior \| volume = 88 \| issue = 3 \| pages = 265–71 \| date = January 2008 \| pmid = 17897705 \| doi = 10.1016/j.pbb.2007.08.010 \| s2cid = 22711773 }}</ref> == Chemistry == {{see also\|coca alkaloid\|list of cocaine analogues}} === Forms === {{See also\|Cocaine paste\|Crack cocaine#Chemistry}} [[File:CocaineHydrochloridePowder cropped.jpg\|right\|thumb\|A pile of [[micronization\|micronized]] cocaine hydrochloride]] [[File:CocaineHCl.jpg\|right\|thumb\|A piece of compressed cocaine hydrochloride, commonly used for smuggling]] In its purest form, cocaine is a white, pearly powder. As a [[tropane alkaloid]], cocaine is a weak base and readily forms salts when combined with acids. The most commonly encountered form is the hydrochloride (HCl) salt, although other salts such as the sulfate (SO<sub>4</sub><sup>2−</sup>) and nitrate (NO<sub>3</sub><sup>−</sup>) are occasionally observed. The solubility of these salts varies depending on their polarity; the hydrochloride salt is polar and highly soluble in water.<ref>{{Cite web \| vauthors = Cotton S \| date = February 2016 \| work = Molecule of the Month \| publisher = University of Bristol \|url= https://www.chm.bris.ac.uk/motm/cocaine/cocaineh.htm \|title=Cocaine: The notorious recreational drug \|access-date=4 May 2020\|archive-date=8 July 2024\|archive-url=https://web.archive.org/web/20240708191819/https://www.chm.bris.ac.uk/motm/cocaine/cocaineh.htm\|url-status=live}}</ref> === Synthesis === ==== Total synthesis ==== The first [[Chemical structure#Structural elucidation\|structure elucidation]] and [[total synthesis]] of the cocaine molecule was accomplished by [[Richard Willstätter]] in 1898.<ref name="Humphrey_2001">{{Cite journal \| vauthors = Humphrey AJ, O'Hagan D \| title = Tropane alkaloid biosynthesis. A century-old problem unresolved \| journal = Natural Product Reports \| volume = 18 \| issue = 5 \| pages = 494–502 \| date = October 2001 \| pmid = 11699882 \| doi = 10.1039/b001713m }}</ref> Willstätter’s synthesis involved constructing the cocaine structure from simpler precursors, notably via the intermediate [[tropinone]]. Subsequent significant contributions to understanding the synthetic pathway and stereochemistry were made by [[Robert Robinson (organic chemist)\|Robert Robinson]] and Edward Leete. Cocaine contains four [[chiral]] centers (1''R'', 2''R'', 3''S'', and 5''S''), two of which are [[Molecular configuration\|configuration]]ally dependent, resulting in eight possible [[stereoisomer]]s. The formation of inactive stereoisomers, along with various synthetic by-products, limits both the yield and purity of the final product.<ref name="Amara_2021">{{cite journal \| vauthors = Amara SB, Koslowski T, Zaidi A \| title=Quantum Chemistry of Cocaine and its Isomers I: Energetics, Reactivity and Solvation \| journal=South African Journal of Chemistry \| volume=75 \| date=2021 \| doi=10.17159/0379-4350/2021/v75a3\| doi-access=free }}</ref><ref name="Drake_2018">{{cite journal \| vauthors = Drake LR, Scott PJ \| title = DARK Classics in Chemical Neuroscience: Cocaine \| journal = ACS Chemical Neuroscience \| volume = 9 \| issue = 10 \| pages = 2358–2372 \| date = October 2018 \| pmid = 29630337 \| pmc = 6197930 \| doi = 10.1021/acschemneuro.8b00117 }}</ref> Although the chemical synthesis of cocaine is technically feasible, it is generally considered impractical due to its high cost, low efficiency, and challenges in stereoselective synthesis compared to extraction from natural plant sources. While domestic clandestine laboratories could theoretically reduce reliance on offshore production and international smuggling—as seen with illicit [[methamphetamine]]—manufacture and synthetic production of cocaine remains rare. Large-scale commercial synthesis has not been explored.<ref name="Kohnen-Johannsen_2019">{{cite journal \| vauthors = Kohnen-Johannsen KL, Kayser O \| title = Tropane Alkaloids: Chemistry, Pharmacology, Biosynthesis and Production \| journal = Molecules \| volume = 24 \| issue = 4 \| page = 796 \| date = February 2019 \| pmid = 30813289 \| pmc = 6412926 \| doi = 10.3390/molecules24040796 \| doi-access = free }}</ref> ==== Biosynthesis ==== {{Main\|Biosynthesis of cocaine}} The [[biosynthesis of cocaine]] is the natural metabolic process by which the [[coca plant]] (''Erythroxylum'' species) produces cocaine, a [[tropane alkaloid]], through a multi-step enzymatically catalyzed pathway beginning with [[ornithine]] or [[arginine]] and culminating in the formation of the cocaine metabolite [[benzoylecgonine]]. Large-scale biosynthesis of cocaine is unexplored.<ref name="Kohnen-Johannsen_2019" /> The biosynthesis of cocaine has long attracted the attention of biochemists and organic chemists. This interest is partly motivated by the strong physiological effects of cocaine, but a further incentive was the unusual [[Bicyclic molecule\|bicyclic]] structure of the molecule. The biosynthesis can be viewed as occurring in two phases, one phase leading to the N-methylpyrrolinium ring, which is preserved in the final product. The second phase incorporates a C4 unit with formation of the bicyclic [[tropane]] core.<ref name="Leete_1990">{{cite journal \| vauthors = Leete E \| title = Recent Developments in the Biosynthesis of the Tropane Alkaloids1 \| journal = Planta Medica \| volume = 56 \| issue = 4 \| pages = 339–352 \| date = Aug 1990 \| pmid = 2236285 \| doi = 10.1055/s-2006-960979 \| doi-access = free \| bibcode = 1990PlMed..56..339L }}</ref> ==== GMO synthesis ==== In 2022, a [[GMO]] produced ''[[N. benthamiana]]'' were discovered that were able to produce 25% of the amount of cocaine found in a coca plant.<ref>{{Cite web \| vauthors = Wilkins A \| date = 25 November 2022 \|title=Genetically modified tobacco plant produces cocaine in its leaves \|url=https://www.newscientist.com/article/2348568-genetically-modified-tobacco-plant-produces-cocaine-in-its-leaves/ \|website=New Scientist \|access-date=27 November 2022 \|archive-date=27 November 2022 \|archive-url=https://web.archive.org/web/20221127225822/https://www.newscientist.com/article/2348568-genetically-modified-tobacco-plant-produces-cocaine-in-its-leaves/ \|url-status=live }}</ref> However, since ''N. benthamiana'' also naturally contains [[nicotine]], separating the cocaine from nicotine and related alkaloids would be challenging. === Field analysis === [[File:Drugwipe Kokain.jpg\|thumb\|[[Drugwipe test]] can detect traces of illicit substances, including cocaine, on surfaces such as driver's licenses at [[random checkpoint]]s.]] [[File:Cocaine under UV light 03.jpg\|thumb\|Cocaine under [[UV light]]]] [[Personal data\|Personal]] cards-including ID cards and driver's licenses-are frequently swabbed by inspectors to detect drug residue, as these items are commonly used to prepare lines of cocaine. Swabbing can reveal traces of cocaine or other illicit substances, providing evidence of recent drug handling or use. This practice may be employed during security checks at border crossings. A ''[[Newsbeat]]'' investigation found that "cocaine torches" used by UK police to detect cocaine use are ineffective on typical street cocaine, as independent lab tests showed they fail to make the drug [[fluoresce]]. Experts and drug charities criticized the devices, warning they can give false positives and waste resources, while police forces defended their use as a deterrent. The manufacturer says the torches only work on much purer forms of cocaine than are found on the street.<ref>{{cite news \| vauthors = Crawford D \|title=Drug torches 'don't always work' \|url=https://www.bbc.com/news/newsbeat-10000473 \|work=BBC News \|date=22 July 2009}}</ref><ref>{{cite news \| vauthors = Taylor J \|title=Drug torches for bouncers 'don't always spot cocaine' \|url=https://www.bbc.com/news/newsbeat-22774362 \|work=BBC News \|date=14 June 2013}}</ref> Cocaine may be detected by law enforcement using the [[Scott reagent]]. The test can easily generate [[False positives and false negatives\|false positives]] for common substances and must be confirmed with a laboratory test.<ref>{{Cite news \|url=https://psmag.com/news/meet-the-chemist-behind-many-popular-and-faulty-police-drug-kits \| vauthors = Gabrielson R \|title=Meet the Chemist Behind Many Popular—and Faulty—Police Drug Kits \|date=22 June 2016 \|work=Pacific Standard \|access-date=21 April 2020 \|archive-date=8 August 2020 \|archive-url=https://web.archive.org/web/20200808062758/https://psmag.com/news/meet-the-chemist-behind-many-popular-and-faulty-police-drug-kits \|url-status=live }}</ref><ref>{{Cite news \| vauthors = Gabrielson R, Sanders T \|url= https://www.nytimes.com/2016/07/10/magazine/how-a-2-roadside-drug-test-sends-innocent-people-to-jail.html \|archive-url=https://ghostarchive.org/archive/20220101/https://www.nytimes.com/2016/07/10/magazine/how-a-2-roadside-drug-test-sends-innocent-people-to-jail.html \|archive-date=1 January 2022 \|url-access=limited \|title=How a $2 Roadside Drug Test Sends Innocent People to Jail \|date=7 July 2016 \|work=The New York Times \|access-date=21 April 2020 \| url-status=live }}</ref> Approximate cocaine purity can be determined using 1 mL 2% cupric sulfate pentahydrate in dilute HCl, 1 mL 2% potassium thiocyanate and 2 mL of [[chloroform]]. The shade of brown shown by the chloroform is proportional to the cocaine content. This test is not cross sensitive to heroin, methamphetamine, [[benzocaine]], procaine and a number of other drugs but other chemicals could cause false positives.<ref>{{Cite journal \| vauthors = Travnikoff B \|title=Semiquantitative screening test for cocaine \|date=1 April 1983 \|journal=Analytical Chemistry \|issue=4 \|volume=55 \|pages=795–796 \|doi=10.1021/ac00255a048 \|issn=0003-2700}}</ref> == Society and culture == {{main\|Cocaine and society}} Both the [[Cocaine and society#Pharmaceutical supply chain\|pharmaceutical supply chain]] and the [[Cocaine and society#Illicit supply chain\|illicit supply chain]] obtain cocaine from coca cultivated in Latin America, but they operate under very different controls and oversight. In Peru, for example, legal coca cultivation is monopolized by the state company [[National Coca Company]] (ENACO), yet approximately 90% of coca leaves produced in the country are diverted to illegal actors for cocaine manufacturing.<ref>{{cite journal \| vauthors = Busnel R, Manrique López H \| title = The political economy of a failed drug reform: Insights from Peru's main legal coca valley \| journal = The International Journal on Drug Policy \| volume = 117 \| article-number = 104050 \| date = July 2023 \| pmid = 37267739 \| doi = 10.1016/j.drugpo.2023.104050 }}</ref> As a result, these illicit coca crops are a primary target of ongoing government-led [[coca eradication]] efforts.<ref name="Grisaffi_2016">{{cite journal \| vauthors = Grisaffi T, Ledebur K \| title = Citizenship or Repression? Coca, Eradication and Development in the Andes \| journal = Stability: International Journal of Security and Development \| volume = 5 \| issue = 1 \| date = 31 March 2016 \| article-number = 3 \| doi = 10.5334/sta.440 \| doi-access = free \| issn = 2165-2627 }}</ref> Cocaine is prohibited in competition for athletes by the [[World Anti-Doping Agency]] (WADA), which lists it as a stimulant on its [[List of drugs banned by the World Anti-Doping Agency\|International Standard for the Prohibited List]].<ref name=WADA17>{{cite web \| url = https://www.wada-ama.org/sites/default/files/resources/files/2016-09-29_-_wada_prohibited_list_2017_eng_final.pdf \| title = World Anti-Doping Code: International Standard Prohibited List 2017 \| date = January 2017}}</ref>{{rp\|6}} ===Street names=== Cocaine is sometimes referred to on the street as blow, coca, coke, crank, flake, snow, or soda cot. Slang terms for free base cocaine include crack or rock.<ref name="DEA">{{cite web \|title=Cocaine \|url=https://www.dea.gov/factsheets/cocaine \|website=DEA \|language=en}}</ref> [https://en.wiktionary.org/wiki/fishscale#Noun Fishscale cocaine], from ''fish'' + ''scale'', is named for its shiny, yellowish flakes that resemble fish scales—distinct from the dull white appearance of standard cocaine powder. === Legal status === {{Main\|Legal status of cocaine}} [[File:Legal_status_of_cocaine_possession.png\|thumb\|Legal status of cocaine possession]] The production, distribution, and sale of cocaine products is restricted (and illegal in most contexts) in most countries as regulated by the [[Single Convention on Narcotic Drugs]], and the [[United Nations Convention Against Illicit Traffic in Narcotic Drugs and Psychotropic Substances]]. In the United States the manufacture, importation, possession, and distribution of cocaine are additionally regulated by the 1970 [[Controlled Substances Act]]. Some countries, such as Bolivia, Colombia, and Peru, permit the cultivation of coca leaf for traditional consumption by the local [[indigenous peoples of the Americas\|indigenous population]], but nevertheless, prohibit the production, sale, and consumption of cocaine.<ref name="bolivia-cocaine-bar-route-36">{{Cite news\|url=https://www.theguardian.com/world/2009/aug/19/bolivia-cocaine-bar-route-36\|title=The world's first cocaine bar\| vauthors = Franklin J \|date=18 August 2009\|newspaper=The Guardian\|issn=0261-3077\|access-date=23 December 2016\|url-status=live\|archive-url=https://web.archive.org/web/20170112142609/https://www.theguardian.com/world/2009/aug/19/bolivia-cocaine-bar-route-36\|archive-date=12 January 2017}}</ref> The provisions as to how much a coca farmer can yield annually is protected by laws such as the Bolivian Cato accord.<ref>{{Cite web \| vauthors = Grisaffi T \|title=The Cato Accord: Bolivia's Humane and Effective Approach to Controlling Coca Cultivation\|url=https://ain-bolivia.org/wp-content/uploads/The-Cato-Accord-Bolivias-Humane-and-Effective-Approach-to-Controlling-Coca-Cultivation.pdf\|website=ain-bolivia.org\|access-date=12 January 2017\|url-status=live\|archive-url=https://web.archive.org/web/20160503160349/https://ain-bolivia.org/wp-content/uploads/The-Cato-Accord-Bolivias-Humane-and-Effective-Approach-to-Controlling-Coca-Cultivation.pdf\|archive-date=3 May 2016}}</ref> In addition, some parts of Europe, the United States, and Australia allow processed cocaine for medicinal uses only. ==== Australia ==== Cocaine is a Schedule 8 controlled drug in Australia under the [[Standard for the Uniform Scheduling of Medicines and Poisons\|Poisons Standard]].<ref>{{Cite web\|url=https://www.legislation.gov.au/F2023L01294/asmade/text\|title=Therapeutic Goods (Poisons Standard—October 2023) Instrument 2023\|website=Federal Register of Legislation\|date=26 September 2023 \|publisher=Australian Government\|access-date=22 January 2024}}</ref> It is the second most popular illicit recreational drug in Australia [[Cannabis in Australia\|behind cannabis]].<ref>{{Cite web\|url=https://www.aihw.gov.au/reports/illicit-use-of-drugs/illicit-drug-use\|title=Illicit drug use\|date=13 December 2023\|website=Australian Institute of Health and Welfare\|access-date=22 January 2024\|archive-date=20 January 2024\|archive-url=https://web.archive.org/web/20240120123407/https://www.aihw.gov.au/reports/illicit-use-of-drugs/illicit-drug-use\|url-status=live}}</ref> In [[Western Australia]] under the Misuse of Drugs Act 1981 4.0g of cocaine is the amount of prohibited drugs determining a court of trial, 2.0g is the amount of cocaine required for the presumption of intention to sell or supply and 28.0g is the amount of cocaine required for purposes of drug trafficking.<ref>{{Cite web\|url=https://www.legislation.wa.gov.au/legislation/prod/filestore.nsf/FileURL/mrdoc_46172.pdf/$FILE/Misuse%20Of%20Drugs%20Act%201981%20-%20%5B08-f0-00%5D.pdf?OpenElement\|title=Misuse of Drugs Act 1981\|website=Western Australian Legislation\|publisher=Government of Western Australia Department of Justice Parliamentary Counsel's Office\|access-date=22 January 2024\|archive-date=17 February 2024\|archive-url=https://web.archive.org/web/20240217143325/https://www.legislation.wa.gov.au/legislation/prod/filestore.nsf/FileURL/mrdoc_46172.pdf/$FILE/Misuse%20Of%20Drugs%20Act%201981%20-%20%5B08-f0-00%5D.pdf?OpenElement\|url-status=live}}</ref> ==== United States ==== {{See also\|Cocaine in the United States}} [[File:George_H._W._Bush_holds_up_a_bag_of_crack_cocaine_during_his_Address_to_the_Nation_on_National_Drug_Control_Strategy.jpg\|thumb\|upright \|President [[George H. W. Bush]] holds up a bag of [[crack cocaine]] during his Address to the Nation on National Drug Control Strategy on September 5, 1989.]] The US federal government instituted a national [[drug labelling]] requirement for cocaine and cocaine-containing products through the [[Pure Food and Drug Act]] of 1906.<ref name="Gootenberg_1999">{{Cite book \| veditors = Gootenberg P \|title=Cocaine: Global Histories \|url= https://archive.org/details/cocaineglobalhist00goot \|url-access=registration \|year=1999 \|publisher=Routledge \|___location=London \|isbn=978-0-203-02646-5}}</ref>{{rp\|37}} The next important federal regulation was the [[Harrison Narcotics Tax Act]] of 1914. While this act is often seen as the start of prohibition, the act itself was not actually a prohibition on cocaine, but instead it set up a regulatory and licensing regime.<ref name="Madge_2001">{{Cite book \| vauthors = Madge T \|title=White Mischief: A Cultural History of Cocaine \|year=2001 \|publisher=Mainstream Publishing Company \|___location=Edinburgh \|isbn=978-1-84018-405-1\|page = 106}}</ref> The Harrison Act did not recognize addiction as a treatable condition and therefore the therapeutic use of cocaine, heroin, or morphine to such individuals was outlawed{{Spaced ndash}} leading a 1915 editorial in the journal ''American Medicine'' to remark that the addict "is denied the medical care he urgently needs, open, above-board sources from which he formerly obtained his drug supply are closed to him, and he is driven to the underworld where he can get his drug, but of course, surreptitiously and in violation of the law."<ref>{{Cite journal\|title=Narcotic drug addiction\|journal=American Medicine\|date=November 1915\|page=799\|url=https://books.google.com/books?id=tvAAAAAAYAAJ&pg=PA799\|access-date=29 April 2018\|publisher=American-Medicine Publishing Company\|url-status=live\|archive-url=https://web.archive.org/web/20180509174117/https://books.google.com/books?id=tvAAAAAAYAAJ&pg=PA799\|archive-date=9 May 2018}}</ref> The Harrison Act left manufacturers of cocaine untouched so long as they met certain purity and labeling standards.<ref name="Gootenberg_1999" />{{rp\|40}} Despite that cocaine was typically illegal to sell and legal outlets were rarer, the quantities of legal cocaine produced declined very little.<ref name="Gootenberg_1999" />{{rp\|40}} Legal cocaine quantities did not decrease until the [[Narcotic Drugs Import and Export Act\|Jones–Miller Act]] of 1922 put serious restrictions on cocaine manufactures.<ref name="Gootenberg_1999" />{{rp\|40}} Before the early 1900s, newspapers primarily portrayed addiction (rather than violence or crime) as the main problem caused by cocaine use, and depicted cocaine users as upper or middle class [[White people]]. In 1914, The New York Times published an article titled "Negro Cocaine 'Fiends' Are a New Southern Menace," portraying [[Black people]] who used cocaine as dangerous and able to withstand wounds that would normally be fatal.<ref>{{Cite book \|vauthors=Brown E, Barganier G \|title=Race and Crime: Geographies of Injustice \|date=2018 \|publisher=University of California Press \|___location=Oakland, California \|isbn=978-0-520-29418-9 \|pages=207–209 \|url=https://books.google.com/books?id=2ChtDwAAQBAJ \|access-date=21 November 2021 \|archive-date=12 April 2023 \|archive-url=https://web.archive.org/web/20230412145040/https://books.google.com/books?id=2ChtDwAAQBAJ \|url-status=live }}</ref> The [[Anti-Drug Abuse Act of 1986]] mandated the same prison sentences for distributing 500 grams of powdered cocaine and just 5 grams of crack cocaine.<ref>{{Cite book \|vauthors=Moore NM \|title=The Political Roots of Racial Tracking in American Criminal Justice \|date=2015 \|publisher=Cambridge University Press \|___location=New York, NY \|isbn=978-1-107-02297-3 \|page=270 \|url=https://books.google.com/books?id=QKwPBgAAQBAJ&pg=PA270 \|access-date=21 November 2021 \|archive-date=6 April 2023 \|archive-url=https://web.archive.org/web/20230406100009/https://books.google.com/books?id=QKwPBgAAQBAJ&pg=PA270 \|url-status=live }}</ref> In the [[National Survey on Drug Use and Health]], white respondents reported a higher rate of powdered cocaine use, and Black respondents reported a higher rate of crack cocaine use.<ref>{{Cite book \|vauthors=Glaser J \|title=Suspect Race: Causes and Consequences of Racial Profiling \|date=2015 \|publisher=Oxford University Press \|___location=New York, NY \|isbn=978-0-19-537040-9 \|page=7 \|url=https://books.google.com/books?id=3GjDBAAAQBAJ&pg=PA7 \|access-date=21 November 2021 \|archive-date=12 April 2023 \|archive-url=https://web.archive.org/web/20230412145042/https://books.google.com/books?id=3GjDBAAAQBAJ&pg=PA7 \|url-status=live }}</ref> ===Prevalence and trends=== Cocaine production, seizures, and use all reached record levels in 2023, making it the world’s fastest-growing illicit drug market. Seizures rose by 68% from 2019 to 2023, while the number of users increased from 17 million in 2013 to 25 million in 2023, according to the UNODC [[World Drug Report]] 2025.<ref name="Press_release_WDR_2025_English.pdf">{{cite web \| title = UNODC World Drug Report 2025: Global instability compounding social, economic and security costs of the world drug problem \|url=https://www.unodc.org/documents/data-and-analysis/WDR_2025/Press_release_WDR_2025_English.pdf \| publisher = United Nations Office on Drugs and Crime }}</ref> The report further states that Western Europe’s cocaine market is rapidly expanding, resulting in increased violence driven by traffickers, including organized criminal groups from the Western Balkans. Concurrently, record levels of cocaine production have enabled traffickers to enter new markets across Asia and Africa, reflecting the expanding global reach of cocaine trafficking.<ref name="WDR25_Special_points_of_interest.pdf">{{cite report \|title=World Drug Report 2025: Special points of interest \|url=https://www.unodc.org/documents/data-and-analysis/WDR_2025/WDR25_Special_points_of_interest.pdf \|publisher=United Nations Office on Drugs and Crime \|date=2025 \|access-date=2025-06-29 \|type=PDF}}</ref> The U.S. is the world's largest consumer of cocaine,<ref name="WFK Illicit drugs">{{Cite web \|url=https://www.cia.gov/library/publications/the-world-factbook/fields/2086.html \|title=Field Listing – Illicit drugs (by country) \|publisher=Cia.gov \|access-date=15 January 2011 \|url-status=dead \|archive-url=https://web.archive.org/web/20101229044611/https://www.cia.gov/library/publications/the-world-factbook/fields/2086.html \|archive-date=29 December 2010 }}</ref> while South America, as a continent, ranks third in terms of consumer market size.<ref name="Andean_full_report.pdf" /> Europe ranks cocaine as the second most commonly used illicit drug.<ref>{{cite web \|title=Cocaine – the current situation in Europe (European Drug Report 2024) {{!}} www.euda.europa.eu \|url=https://www.euda.europa.eu/publications/european-drug-report/2024/cocaine_en \|website=www.euda.europa.eu}}</ref> Cocaine is among the most widely consumed [[Recreational drug use\|recreational]] stimulants worldwide.<ref name="Roque_2022">{{cite journal \| vauthors = Roque Bravo R, Faria AC, Brito-da-Costa AM, Carmo H, Mladěnka P, Dias da Silva D, Remião F \| title = Cocaine: An Updated Overview on Chemistry, Detection, Biokinetics, and Pharmacotoxicological Aspects including Abuse Pattern \| journal = Toxins \| volume = 14 \| issue = 4 \| page = 278 \| date = April 2022 \| pmid = 35448887 \| pmc = 9032145 \| doi = 10.3390/toxins14040278 \| doi-access = free }}</ref> === Impact === ==== Impact of illicit cocaine ==== ===== Impact on impoverished communities ===== In countries where cocaine is illicitly produced, an intermediate product known as cocaine paste—often referred to as "poor man's cocaine"—is frequently smoked in impoverished communities. This substance is favored in these areas primarily because it is inexpensive and more accessible than refined cocaine. However, the use of cocaine paste poses severe health risks. During its production, various toxic chemicals are used to extract coca alkaloids from the coca leaves. Many of these hazardous substances, such as solvents and acids, remain in the paste after processing. When the paste is smoked, individuals are exposed not only to the addictive effects of the drug itself but also to the dangerous residual chemicals, which can cause significant harm to the lungs, nervous system, and overall health. This combination of affordability, accessibility, and toxicity makes cocaine paste particularly damaging to vulnerable populations in cocaine-producing regions.<ref name="smokablecocaine_eng_web-def.pdf" /><ref name="Arif_1987" /><ref name="Jeri_1984" /><ref name="Phillips_2009" /> ===== Environmental impact ===== {{See also\|Environmental impact of illicit drug production}} Most of the world's cocaine is produced in South America, particularly in the [[Andes\|Andean region]].<ref name="UNODC_2019">{{cite report \| author = UNODC \| date = 2006 \| url = https://www.unodc.org/pdf/andean/Andean_report_Part2.pdf \| title = Part 2. Environmental Effects of Illicit Drug Cultivation and Processing \| access-date = 6 May 2019 }}</ref> The environmental destruction caused by the production of cocaine has been well documented, with reports made the UN and other government bodies.<ref name="McSweeney_2015">{{cite web \| vauthors = McSweeney K \| title = The Impact of Drug Policy on the Environment \| url = https://www.opensocietyfoundations.org/sites/default/files/impact-drug-policy-environment-20151208.pdf \| date = 2015 \| access-date = 7 May 2019 }}</ref> Due to the illegal nature of [[Coca production in Colombia\|coca production]], farmers make little effort in soil conservation and sustainability practices as seen in the high mobility and short life of coca plots in Colombia.<ref name="UNODC_2019" /> One of the major implications of cocaine production is [[deforestation]] as large areas of forest are cleared for coca cultivation. The UNODC approximated that 97,622 hectares of [[Old-growth forest\|primary forest]] were cleared for coca cultivation during 2001–2004 in the Andean region.<ref name="UNODC_2019" /> This further causes [[habitat destruction]], especially in [[biodiversity hotspot]]s, areas rich in a variety of species. Such areas are chosen for coca cultivation due to their remote locations, minimising chances of detection.<ref name="Burns-Edel_2016">{{cite journal \| vauthors = Burns-Edel T \| title = Environmental Impacts of Illicit Drug Production. Issue \| journal = Global Societies Journal \| volume = 4 \| year = 2016 \| url = https://gsj.global.ucsb.edu/sites/secure.lsit.ucsb.edu.gisp.d7_gs-2/files/sitefiles/Burns-Edel.pdf }}</ref> Deforestation impacts [[soil erosion]] which further inhibits the survival of native species.<ref name="UNODC_2019" /> The use of [[pesticide]]s can also severely affect the environment. Farmers are able to use unregulated and highly toxic pesticides due to the clandestine nature of drug production.<ref name="Burns-Edel_2016" /> The use of such pesticides can have both direct and indirect effects on the ecosystem. Where lethal levels of exposure directly cause the death of fauna, which is further carried up the [[food chain]] where secondary feeders who consume the poisoned animals are also impacted. Furthermore, non-lethal levels of exposure can also cause weaker immune system development and neurological issues, further increasing mortality rates.<ref name="Burns-Edel_2016" /> ===== Impact of illicit cocaine trade ===== Cocaine is extremely expensive on the black market, with prices rising sharply at each distribution level—often more than its weight in gold.<ref>{{cite journal \| vauthors = Hulme S, Hughes CE, Nielsen S \| title = The price and mark up of pharmaceutical drugs supplied on the black market \| journal = The International Journal on Drug Policy \| volume = 76 \| article-number = 102626 \| date = February 2020 \| pmid = 31841773 \| doi = 10.1016/j.drugpo.2019.102626 }}</ref> ====== Latin America ====== Drug war policies in Latin America and the Caribbean have led to more violence, higher incarceration rates, health crises, and deeper poverty, while undermining trust in institutions and worsening inequality. There is increasing support for shifting toward drug policies that focus on sustainable development and human rights instead of punitive measures.<ref name="ow-the-drug-wars-impact-latin-america-and-the-caribbean-development">{{cite web \| vauthors = Zepeda R \| date = 16 August 2023 \|title=How the drug wars impact Latin America and the Caribbean development? \| publisher = King's College London \|url=https://www.kcl.ac.uk/how-the-drug-wars-impact-latin-america-and-the-caribbean-development }}</ref> ====== West Africa ====== Cocaine trafficking in West Africa has become closely linked with the activities of several [[List of designated terrorist groups\|terrorist organizations]].<ref>{{cite web \|title=Organized Crime Module 16 Key Issues: Terrorism and drug trafficking \|url=https://www.unodc.org/e4j/fr/organized-crime/module-16/key-issues/terrorism-and-drug-trafficking.html \|website=www.unodc.org \|language=en}}</ref><ref>{{cite report \| title = Transnational Organized Crime in West Africa: A Threat Assessment \| date = 2013 \| publisher = United Nations Office on Drugs and Crime (UNODC) \| url = https://www.unodc.org/documents/data-and-analysis/tocta/West_Africa_TOCTA_2013_EN.pdf }}</ref><ref>{{cite web \| title = Linkages Between Organized Crime and Terrorism \| publisher = United Nations Office on Drugs and Crime (UNODC) \| date = 2019 \|url= https://www.unodc.org/documents/e4j/FINAL_Module_16_Linkages_between_Organized_Crime_andTerrorism_14_Mar_2019.pdf }}</ref> ==== Impact of enforcement ==== ===== Impact of coca eradication ===== {{See also\|Coca eradication}} In December 2000, Dutch journalist [[Marjon van Royen]] found that "because the chemical is sprayed in Colombia from planes on inhabited areas, there have been consistent health complaints [in humans]. Burning eyes, dizziness and respiratory problems being most frequently reported." In some areas, 80 percent of the children of the indigenous community fell sick with skin rashes, fever, diarrhoea and eye infections.<ref>{{cite web \| vauthors = van Royen M \| url = http://marjonvanroyen.nl/index.php?option=com_content&view=article&id=525&Itemid=46 \| title = Driven Mad by Itch \| work = [[NRC Handelsblad]] \| date = December 28, 2000 }}</ref> Because the glyphosate is sprayed from the air, there is a much higher chance of human error when spraying suspected illegal coca plantations. In many cases the wrong fields are sprayed, resulting in not only a total loss of the farmer's crop- but the loss of that field altogether as nothing will grow where the herbicide has been sprayed.<ref name="Sue Branford 2005">{{cite book \| vauthors = O'Shaughnessy H, Branford S \| title = Chemical Warfare in Colombia: The Costs of Coca Fumigation \| ___location = London \| date = 2005 \| publisher = Latin America Bureau \| isbn = 978-1-899365-68-5 \| url = https://books.google.com/books?id=6E5_tAEACAAJ }}</ref> Though official documentation of the health effects of glyphosate spraying in Colombia are virtually non-existent, neighbouring Ecuador has conducted studies to determine the cause of mysterious illnesses amongst people living along the border of Colombia and has since demanded that no aerial sprayings occur within 10 km of the border because of the damages caused to the people, animals and environment in that area.<ref name="Sue Branford 2005"/> In 2015, Colombia announced a ban on using glyphosate in these programs due to concerns about human toxicity of the chemical.<ref name = BBCColumbia>{{cite web \| work = [[BBC]] \| date = May 10, 2015 \| url = https://www.bbc.com/news/world-latin-america-32677411 \| title = Colombia to ban coca spraying herbicide glyphosate }}</ref> =====Impact of interdiction===== The Consolidated Counterdrug Database (CCDB) is a U.S. government dataset created in the 1990s that compiles vetted data on cocaine trafficking and seizures in the [[Western Hemisphere]] "transit zone," involving 26 U.S. agencies and 20 foreign partners. It provides a highly reliable, conservative record of cocaine movements and interdiction efforts, revealing that despite large seizures, interdiction captures only a small fraction of trafficking events and has minimal impact on U.S. cocaine prices. The CCDB challenges optimistic views of drug interdiction effectiveness and underscores the need for new policy approaches, yet remains underutilized in research despite being unclassified.<ref>{{cite journal \| vauthors = McSweeney K \| title = Reliable drug war data: The Consolidated Counterdrug Database and cocaine interdiction in the "Transit Zone" \| journal = The International Journal on Drug Policy \| volume = 80 \| article-number = 102719 \| date = June 2020 \| pmid = 32416537 \| doi = 10.1016/j.drugpo.2020.102719 }}</ref> == Research == Cocaine [[hapten]]s are chemically modified derivatives of cocaine that retain key immunogenic features, allowing them to be attached to carrier proteins such as [[keyhole limpet hemocyanin]] or [[bovine serum albumin]]. This enables the immune system to recognize cocaine and produce anti-cocaine antibodies, which can bind cocaine in the bloodstream and prevent it from reaching the brain, thereby blocking its psychoactive effects.<ref name="Janda_2011">{{cite journal \| vauthors = Janda KD, Treweek JB \| title = Vaccines targeting drugs of abuse: is the glass half-empty or half-full? \| journal = Nature Reviews. Immunology \| volume = 12 \| issue = 1 \| pages = 67–72 \| date = December 2011 \| pmid = 22173478 \| doi = 10.1038/nri3130 }}</ref><ref>{{cite journal \| vauthors = Anthenelli RM, Somoza E \| title = Vaccine for cocaine addiction: A promising new immunotherapy \| journal = Current Psychiatry \| volume = 9 \| issue = 9 \| pages = 16–20 \| date = September 2010 \| url = https://cdn.mdedge.com/files/s3fs-public/Document/September-2017/0909CP_Article1.pdf }}</ref><ref name="Bremer_2017">{{cite journal \| vauthors = Bremer PT, Schlosburg JE, Banks ML, Steele FF, Zhou B, Poklis JL, Janda KD \| title = Development of a Clinically Viable Heroin Vaccine \| journal = Journal of the American Chemical Society \| volume = 139 \| issue = 25 \| pages = 8601–8611 \| date = June 2017 \| pmid = 28574716 \| pmc = 5612493 \| doi = 10.1021/jacs.7b03334 \| bibcode = 2017JAChS.139.8601B \| url = }}</ref> The [[cocaine esterase]] enzyme and redesigned versions of it have been studied as a potential treatment for [[cocaine dependence\|cocaine addiction]] in humans.<ref>{{cite journal \| vauthors = Narasimhan D, Woods JH, Sunahara RK \| title = Bacterial cocaine esterase: a protein-based therapy for cocaine overdose and addiction \| journal = [[Future Medicinal Chemistry]] \| volume = 4 \| issue = 2 \| pages = 137–50 \| date = February 2012 \| pmid = 22300094 \| doi = 10.4155/fmc.11.194 \| pmc = 3290992 }}</ref> [[Coca tea]] has been explored as a supportive treatment for cocaine dependence. A study in [[Lima]], Peru, found that using coca leaf infusion along with counseling reduced relapse rates and significantly increased the duration of abstinence among addicted individuals, suggesting that this approach may help prevent relapse during treatment.<ref name="Teobaldo_2014">{{Cite journal \| vauthors = Teobaldo L \|title=The Standard Low Dose of Oral Cocaine: Used for Treatment of Cocaine Dependence. \|journal=Substance Abuse \|date=1994 \|volume=15 \|issue=4 \|pages=215–220 \|url=http://www.dronet.org/sostanze/sos_pdf/cocaine21.pdf \|archive-url=https://web.archive.org/web/20140602154528/http://www.dronet.org/sostanze/sos_pdf/cocaine21.pdf \|archive-date=2 June 2014 \|url-status=live}}</ref> Recent research has also examined the use of prescription psychostimulants for cocaine dependence, following the [[Self-medication#Self-medication hypothesis\|Self-Medication Hypothesis]]. This hypothesis suggests that some individuals use cocaine to address underlying neurochemical or psychological issues. While some studies indicate that psychostimulant therapy may reduce cocaine use and cravings, the evidence is mixed and further research is needed.<ref>{{cite journal \| vauthors = Mariani JJ, Khantzian EJ, Levin FR \| title = The self-medication hypothesis and psychostimulant treatment of cocaine dependence: an update \| journal = The American Journal on Addictions \| volume = 23 \| issue = 2 \| pages = 189–193 \| date = March 2014 \| pmid = 25187055 \| pmc = 4227391 \| doi = 10.1111/j.1521-0391.2013.12086.x }}</ref> In animal studies, nicotine exposure in [[Laboratory mouse\|mice]] increases the likelihood of later cocaine use, with clear molecular changes in the brain.<ref name="Kandel_2014">{{cite journal \| vauthors = Kandel ER, Kandel DB \| title = Shattuck Lecture. A molecular basis for nicotine as a gateway drug \| journal = The New England Journal of Medicine \| volume = 371 \| issue = 10 \| pages = 932–943 \| date = September 2014 \| pmid = 25184865 \| pmc = 4353486 \| doi = 10.1056/NEJMsa1405092 \| author2-link = Denise Kandel \| author1-link = Eric Kandel }}</ref> These findings mirror human [[Epidemiology\|epidemiological]] data showing a link between nicotine use and increased risk of later cannabis and cocaine use, as well as other substances.<ref name="Keyes_2016">{{cite journal \| vauthors = Keyes KM, Hamilton A, Kandel DB \| title = Birth Cohorts Analysis of Adolescent Cigarette Smoking and Subsequent Marijuana and Cocaine Use \| journal = American Journal of Public Health \| volume = 106 \| issue = 6 \| pages = 1143–1149 \| date = June 2016 \| pmid = 27077359 \| pmc = 4880234 \| doi = 10.2105/AJPH.2016.303128 }}</ref><ref name="Ren_2019">{{cite journal \| vauthors = Ren M, Lotfipour S \| title = Nicotine Gateway Effects on Adolescent Substance Use \| journal = The Western Journal of Emergency Medicine \| volume = 20 \| issue = 5 \| pages = 696–709 \| date = August 2019 \| pmid = 31539325 \| pmc = 6754186 \| doi = 10.5811/westjem.2019.7.41661 }}</ref> Similarly, in rats, alcohol consumption raises the probability of later cocaine addiction and is associated with changes in the brain’s reward system.<ref name="Griffin_2017">{{cite journal \| vauthors = Griffin EA, Melas PA, Zhou R, Li Y, Mercado P, Kempadoo KA, Stephenson S, Colnaghi L, Taylor K, Hu MC, Kandel ER, Kandel DB \| title = Prior alcohol use enhances vulnerability to compulsive cocaine self-administration by promoting degradation of HDAC4 and HDAC5 \| journal = Science Advances \| volume = 3 \| issue = 11 \| article-number = e1701682 \| date = November 2017 \| pmid = 29109977 \| pmc = 5665598 \| doi = 10.1126/sciadv.1701682 \| bibcode = 2017SciA....3E1682G }}</ref><ref name="Anderson_2019">{{cite journal \| vauthors = Anderson EM, Penrod RD, Barry SM, Hughes BW, Taniguchi M, Cowan CW \| title = It is a complex issue: emerging connections between epigenetic regulators in drug addiction \| journal = The European Journal of Neuroscience \| volume = 50 \| issue = 3 \| pages = 2477–2491 \| date = August 2019 \| pmid = 30251397 \| doi = 10.1111/ejn.14170 \| s2cid = 52816486 }}</ref> Human studies also show that alcohol use increases the risk of transitioning from cocaine use to addiction.<ref name="Lopez-Quintero_2011">{{cite journal \| vauthors = Lopez-Quintero C, Pérez de los Cobos J, Hasin DS, Okuda M, Wang S, Grant BF, Blanco C \| title = Probability and predictors of transition from first use to dependence on nicotine, alcohol, cannabis, and cocaine: results of the National Epidemiologic Survey on Alcohol and Related Conditions (NESARC) \| journal = Drug and Alcohol Dependence \| volume = 115 \| issue = 1–2 \| pages = 120–130 \| date = May 2011 \| pmid = 21145178 \| pmc = 3069146 \| doi = 10.1016/j.drugalcdep.2010.11.004 }}</ref><ref name="Bickel_2016">{{cite book \| vauthors = Bickel WK, Snider SE, Quisenberry AJ, Stein JS, Hanlon CA \| title = Competing neurobehavioral decision systems theory of cocaine addiction: From mechanisms to therapeutic opportunities \| chapter = Competing neurobehavioral decision systems theory of cocaine addiction \| series = Progress in Brain Research \| volume = 223 \| pages = 269–293 \| year = 2016 \| pmid = 26806781 \| pmc = 5495192 \| doi = 10.1016/bs.pbr.2015.07.009 \| isbn = 978-0-444-63545-7 }}</ref> Experimentally, cocaine injections can be delivered to animals such as [[Drosophila melanogaster\|fruit flies]] to study the mechanisms of cocaine addiction.<ref>{{Cite journal \| vauthors = Dimitrijevic N, Dzitoyeva S, Manev H \| title = An automated assay of the behavioral effects of cocaine injections in adult Drosophila \| journal = Journal of Neuroscience Methods \| volume = 137 \| issue = 2 \| pages = 181–184 \| date = August 2004 \| pmid = 15262059 \| doi = 10.1016/j.jneumeth.2004.02.023 \| s2cid = 19882594 }}</ref> ===Cocaine vaccines=== ====Calixcoca==== {{Main\|Calixcoca}} [[Calixcoca]] is an experimental [[vaccine]] to treat cocaine and crack cocaine addiction. It has been in development since 2015 by the [[Federal University of Minas Gerais]] (UFMG) in Brazil.<ref name="Corrêa_2023">{{Cite web \| vauthors = Corrêa F \|date=2023-05-30 \|title=Brasileiros desenvolvem vacina contra crack e cocaína \|url=https://www1.folha.uol.com.br/equilibrioesaude/2023/05/brasileiros-desenvolvem-vacina-contra-crack-e-cocaina.shtml \|archive-url=https://web.archive.org/web/20230614024354/https://www1.folha.uol.com.br/equilibrioesaude/2023/05/brasileiros-desenvolvem-vacina-contra-crack-e-cocaina.shtml \|archive-date=2023-06-14 \|access-date=2023-06-14 \|website=Folha de S.Paulo \|language=pt-BR}}</ref> ====TA-CD==== {{Main\|TA-CD}} [[TA-CD]] is a [[vaccine]] developed by the Xenova Group and designed to negate the effects of cocaine, making it suitable for use in treatment of addiction. It is created by combining [[norcocaine]] with inactivated [[cholera]] toxin.<ref name="Martell_2005">{{cite journal \|vauthors=Martell BA, Mitchell E, Poling J, Gonsai K, Kosten TR \|title=Vaccine pharmacotherapy for the treatment of cocaine dependence \|journal=Biol. Psychiatry \|volume=58 \|issue=2 \|pages=158–64 \|date=July 2005 \|pmid=16038686 \|doi=10.1016/j.biopsych.2005.04.032 \|s2cid=22415520 }}</ref> == History == {{Main\|History of cocaine}} Coca leaves have been used by indigenous South Americans for thousands of years, both as a stimulant and for medicinal purposes.<ref name="Hesse_2002">{{Cite book\| vauthors = Hesse M \|title=Alkaloids: Nature's Curse or Blessing?\|page=304\|publisher=Wiley-VCH\|___location=Weinheim\|year=2002\|isbn=978-3-906390-24-6}}</ref> When the [[Spanish colonization of the Americas\|Spanish arrived in South America]], they initially banned coca but soon legalized and taxed it after seeing its importance to local labor.<ref>{{Cite news\|date=2006 <!--2006-03-02--> \|title=Drug that spans the ages: The history of cocaine \|url=https://www.independent.co.uk/news/uk/this-britain/drug-that-spans-the-ages-the-history-of-cocaine-468286.html \|publisher=The Independent (UK) \|___location=London \|access-date=30 April 2010 \|url-status=dead \|archive-url=https://web.archive.org/web/20100228194626/https://www.independent.co.uk/news/uk/this-britain/drug-that-spans-the-ages-the-history-of-cocaine-468286.html \|archive-date=28 February 2010 }}</ref> The active ingredient, cocaine, was first isolated in 1855 by [[Friedrich Gaedcke]] and later refined by [[Albert Niemann (chemist)\|Albert Niemann]], who named it “cocaine.”<ref name="Luch_2009">{{cite book \| vauthors = Luch A \| title=Molecular, Clinical and Environmental Toxicology \| publisher=Springer Science & Business Media \| publication-place=Basel Boston \| date=3 April 2009 \| isbn=978-3-7643-8336-7 \| page=20 }}</ref><ref name="Niemann_1860">{{Cite journal\|volume = 153\|issue = 2 and 3\|pages = 129–155; 291–308\|year = 1860\|title = Ueber eine neue organische Base in den Cocablättern\|vauthors = Niemann A\|doi = 10.1002/ardp.18601530202\|journal = Archiv der Pharmazie\|s2cid = 98195820\|url = https://zenodo.org/record/1424541\|access-date = 30 June 2019\|archive-date = 28 July 2020\|archive-url = https://web.archive.org/web/20200728162205/https://zenodo.org/record/1424541\|url-status = live}}</ref><ref>{{OEtymD\|Cocaine}}</ref> In the late 1800s, cocaine became popular in Western medicine as a local anesthetic and was widely used in various products, including drinks and remedies.<ref>{{Cite journal\|title=Practical comments on the use and abuse of cocaine\| vauthors = Halsted W \|journal=New York Medical Journal\|year=1885\|pages=294–295\|volume=42}}</ref> and [[James Leonard Corning]] demonstrated [[peridural]] anesthesia.<ref>{{Cite journal\| vauthors = Corning JL \|year=1885\|journal=New York Medical Journal\|title=An experimental study\|volume=42\|page=483}}</ref> However, due to its toxic effects and potential for abuse, safer alternatives eventually replaced it in medical practice.<ref name="Latorre_1999" /> Large-scale coca cultivation and cocaine production occurred in Taiwan Asia, in [[Geography of Taiwan\|Taiwan]] (then known as Formosa) and [[Java]] (today part of Indonesia) before [[World War II]].<ref name="Lu_2024">{{cite journal \| vauthors = Lu SL \| title = A Promising Tropical Medicinal Plant: Taiwan as the Production Hub of Japan's Coca Empire \| journal = Berichte zur Wissenschaftsgeschichte \| volume = 47 \| issue = 4 \| pages = 352–381 \| date = December 2024 \| pmid = 39570053 \| doi = 10.1002/bewi.202400005 }}</ref><ref name="Musto_1998">{{cite journal \| vauthors = Musto DF \| title = International traffic in coca through the early 20th century \| journal = Drug and Alcohol Dependence \| volume = 49 \| issue = 2 \| pages = 145–156 \| date = January 1998 \| pmid = 9543651 \| doi = 10.1016/s0376-8716(97)00157-9 }}</ref> Since the 1980s, the cocaine trade was dominated by centralized, hierarchical [[drug cartel]]s such as [[Medellín Cartel\|Medellín]] and [[Cali Cartel\|Cali]], along with their successors and early [[Revolutionary Armed Forces of Colombia\|FARC]] factions. By the early 2000s, this model fragmented into a diverse network of global trafficking links, allowing South American cocaine production to easily supply markets in Europe, Africa, Asia, and Oceania through various routes.<ref name="Lien_2025">{{cite journal \| vauthors = Lien N, Feltran G \| title = (I)llicit Chains: Some New Hypotheses Regarding a Changing Global Cocaine Market \| journal = Journal of Illicit Economies and Development \| volume = 7 \| issue = 1 \| date = 11 March 2025 \| pages = 20–34 \| doi = 10.31389/jied.274 \| url = https://jied.lse.ac.uk/articles/10.31389/jied.274 \| issn = 2516-7227 }}</ref> == Etymology == The word cocaine derives {{ety\|fr\|Cocaïne}}, {{ety\|es\|[[coca]]}}, ultimately {{ety\|que\|kúka}}.<ref>{{Cite web \|title=Cocaine \|url=https://ahdictionary.com/word/search.html?q=+COCAINE \|url-status=live \|archive-url=https://web.archive.org/web/20230103150607/https://ahdictionary.com/word/search.html?q=+COCAINE \|archive-date=3 January 2023 \|access-date=3 January 2023 \|website=American Heritage Dictionary}}</ref> == See also == {{Portal\|Medicine}} {{Div col\|colwidth=22em}} * [[Cocaine reverse ester]] * [[Cocaine and amphetamine regulated transcript]] * [[MDMA]] – also acts, to a lesser extent, as an SNDRI like cocaine {{Div col end}} {{clear}} == References == * [[Benzocaine]] {{Reflist}} * [[Coca]] * [[Coca eradication]] * [[Crack baby]] * [[Crack Epidemic]] * [[Cuscohygrine]] * [[Drug addiction]] * [[Drug injection]] * [[Drugs and prostitution]] * [[Ecgonine benzoate]] * [[Hydroxytropacocaine]] * [[Hygrine]] * [[Methylecgonine cinnamate]] * [[Procaine\|Novocaine]] * [[Psychoactive drug]] * [[(-)-2-ß-Carbomethoxy-3-ß-(4-fluorophenyl)tropane naphthalenedisulfonate]] (CFT, WIN-35,428) == Further reading == {{refbegin}} * {{Cite book \| veditors = Spillane JF \|title=Cocaine: From Medical Marvel to Modern Menace in the United States, 1884–1920 \|year=2000 \|publisher=The Johns Hopkins University Press \|___location=Baltimore and London \|isbn=978-0-8018-6230-4 \|url=https://archive.org/details/cocainefrommedic00spil }} * {{Cite book \| vauthors = Feiling T \|title=The Candy Machine: How Cocaine Took Over the World \|___location=London \|publisher=Penguin \|year=2009 \|isbn=978-0-14-103446-1}} * {{cite journal \| vauthors = Gewin V \| url = http://www.nature.com/news/2011/111102/full/news.2011.627.html \| title = Smoking stokes cocaine cravings: Molecular mechanism found for controversial 'gateway drug' hypothesis \| journal = Nature News \| date = November 2, 2011 \| doi = 10.1038/news.2011.627 }} * {{cite web \|title=Global Report on Cocaine 2023 \| work = United Nations Office on Drugs and Crime (UNODC) \|url=https://www.unodc.org/documents/data-and-analysis/cocaine/Global_cocaine_report_2023.pdf}} {{refend}} * ''[[Special:Booksources/0312422261\|Cocaine: an unauthorized biography]]'' by [[Dominic Streatfeild]] * ''[http://vlp.mpiwg-berlin.mpg.de/library/data/lit29488 Über Coca]'' by [[Sigmund Freud]] * ''History of Coca. The Divine Plant of the Incas" by W. Golden Mortimer, M.D. 576 pp. And/Or Press San Francisco, 1974. No ISBN. * ''The Triumph of Surgery'' by [[Jürgen Thorwald]] - Ch. 6 - The second battle against Pain (The early use of cocaine solution in eye surgery) * ''[[Snowblind]]'' by [[Robert Sabbag]], Cannongate Books ISBN 1-84195-225-7 * ''The Man Who Made It Snow'' by Max Mermelstein. ISBN 0-671-70312-9 * Celerino III Castillo & Dave Harmon (1994). ''Powderburns: Cocaine, Contras & the Drug War'', Sundial. ISBN 0-88962-578-6 (paperback) ISBN 0-8095-4855-0 (hardcover; Borgo Pr; 3rd ed.; 1995). * Alexander Cockburn & Jeffrey St. Clair (1999). ''Whiteout: The CIA, Drugs and the Press'', Verso. ISBN 1-85984-139-2 (cloth), ISBN 1-85984-258-5 (paperback). Cites 116 books. * Frederick P. Hitz (1999). ''Obscuring Propriety: The CIA and Drugs, International Journal of Intelligence and Counterintelligence'', 12(4): 448-462 DOI:10.1080/088506099304990 * Robert Parry (1999). ''Lost History: Contras, Cocaine, the Press & “[[Project Truth]]”'', Media Consortium. ISBN 1-893517-00-4. * [[Richard Smart]] (Hard Cover 1985). ''[[The Snow Papers]]'' The Atlantic Monthly Press ISBN 0-87113-030-0 * Peter Dale Scott & Jonathan Marshall (1991). ''Cocaine Politics: Drugs, Armies, and the CIA in Central America'', University of California Press. ISBN 0-520-21449-8 (paperback, 1998 reprint), ISBN 0-520-07312-6 (hardcover, 1991), ISBN 0-520-07781-4 (paperback, 1992 reprint). * [[Gary Webb]](1998). ''Dark Alliance: The CIA, the Contras, and the Crack Cocaine Explosion'', Seven Stories Press. ISBN 1-888363-68-1 (hardcover, 1998), ISBN 1-888363-93-2 (paperback, 1999). * [[Philippe Bourgois]] ''In Search of Respect: Selling Crack in El Barrio''. New York: Cambridge University Press. 2003. Second Updated Edition. * [[Otto Snow]] ''THC & Tropacocaine'' ISBN 0-9663128-5-6 (paperback 2004) * [[David Lee]] ''Cocaine Handbook'' ISBN 0-915904-56-X (paperback 1981) * [[Adam Gottlieb]] ''Cocaine Tester's Handbook'' ASIN B0007C137A (paperback 1975) * [[Adam Gottlieb]] ''Pleasures of Cocaine: If You Enjoy: This Book May Save Your Life'' ISBN 0-914171-81-X (paperback 1996) * [[Carol Saline]] ''Doctor Snow: How the FBI Nailed a Ivy League Coke King'' ISBN 0-453-00593-4 (HardCover 1986) * [[Mark Bowden]] ''Doctor Dealer: The Rise & Fall Of An All American Boy and his Multi-Million Dollar Cocaine Empire'' ISBN 0-446-51382-2 (HardCover 1987) ~~Smoke Crack Like Thissss.................... Find the nigga with the whitest snow, dont buy from a nigga you dont know.~~ == External links == {{sister project links\|d=Q41576\|c=Category:Cocaine\|n=no\|b=no\|v=no\|voy=no\|m=no\|mw=no\|s=no\|wikt=cocaine\|species=no}} ~~{{external links}}~~ * [http://answers.yahoo.com/question/index?qid=20061017193046AACTYnB When was cocaine first developed?] a history of cocaine. * [http://www.ca.org/literature/selftest.htm Self-test] — from Cocaine Addicts Anonymous * [http://www.CocaineHelp.org Cocaine User Helping Hand] — Internet Portal dedicated to help crack- and cocaine-addicted people. Contains wide variety of information on drug abuse, available treatment, and recovery issues. * [http://www.erowid.org/chemicals/cocaine/cocaine.shtml Erowid -> Cocaine Information] — A collection of data about cocaine including dose, effects, chemistry, legal status, images and more. * [http://www.snopes.com/cokelore/cocaine.asp Urban Legends Reference Pages: Cokelore (Cocaine-Cola)] — ~~about cocaine in Coke~~ * [http://www.pdxnorml.org/NYT_addictive_080294.html Addictive properties] * [http://www.sharedresponsibility.gov.co/ Shared Responsibility] — Information about European cocaine use and drug trafficking in Colombia. * [http://sun.ars-grin.gov:8080/npgspub/xsql/duke/chemdisp.xsql?chemical=COCAINE Cocaine content of plants] * [http://www.cocaine.org Cocaine.org] — Information guide on Cocaine and its history, use/abuse, etc. * [http://www.bbc.co.uk/dna/h2g2/A10832384 Cocaine - The History and the Risks at h2g2] * [http://www.who.int/substance_abuse/publications/en/Neuroscience_E.pdf Neuroscience of Psychoactive Substance Use and Dependence] by the [[WHO]] – [http://www.greenfacts.org/en/psychoactive-drugs/index.htm Summary] by [[GreenFacts]] {{~~Wiktionary~~Drug use}} {{~~ChemicalSources~~Euphoriants}} {{~~stimulants~~Stimulants}} {{Local anesthetics}} {{Ancient anaesthesia-footer}} {{Ion channel modulators}} {{Monoamine reuptake inhibitors}} {{Sigma receptor modulators}} {{Chemical classes of psychoactive drugs}} {{Psychoactive substance use}} {{Addiction}} {{Authority control}} [[Category:~~Addiction~~Cocaine\| ]] [[Category:~~Alkaloids~~1855 introductions]] [[Category:~~Benzoates~~1855 in the German Confederation]] [[Category:1855 in science]] [[Category:Adulteration]] [[Category:Alkaloids found in Erythroxylum]] [[Category:Anorectics]] [[Category:Benzoate esters]] [[Category:Carboxylate esters]] [[Category:~~Class~~Cardiac ~~A drugs~~stimulants]] [[Category:Cocaine in the United States\|*Cocaine in the United States]] [[Category:~~Dopamine~~Counterculture ~~reuptake~~of ~~inhibitors~~the 1980s]] [[Category:CYP2D6 inhibitors]] [[Category:Euphoriants]] [[Category:German inventions]] [[Category:Local anesthetics]] [[Category:~~Quechua~~Methyl ~~loanwords~~esters]] [[Category:Neurotoxins]] [[Category:Otologicals]] [[Category:Secondary metabolites]] [[Category:Serotonin–norepinephrine–dopamine reuptake inhibitors]] [[Category:Sigma agonists]] [[Category:Stimulants]] [[Category:Sympathomimetic amines]] [[Category:Teratogens]] [[Category:Tropane alkaloids found in Erythroxylum coca]] ~~[[ar:كوكايين]]~~ [[Category:Vasoconstrictors]] ~~[[bn:কোকেইন]]~~ [[Category:Wikipedia medicine articles ready to translate]] ~~[[bs:Kokain]]~~ [[Category:World Anti-Doping Agency prohibited substances]] ~~[[bg:Кокаин]]~~ ~~[[ca:Cocaïna]]~~ ~~[[cs:Kokain]]~~ ~~[[da:Kokain]]~~ ~~[[de:Kokain]]~~ ~~[[et:Kokaiin]]~~ ~~[[es:Cocaína]]~~ ~~[[eo:Kokaino]]~~ ~~[[eu:Kokaina]]~~ ~~[[fa:کوکایین]]~~ ~~[[fr:Cocaïne]]~~ ~~[[gl:Cocaína]]~~ ~~[[ko:코카인]]~~ ~~[[io:Kokaino]]~~ ~~[[id:Kokain]]~~ ~~[[is:Kókaín]]~~ ~~[[it:Cocaina]]~~ ~~[[he:קוקאין]]~~ ~~[[hu:Kokain]]~~ ~~[[ms:Kokaina]]~~ ~~[[nl:Cocaïne]]~~ ~~[[ja:コカイン]]~~ ~~[[no:Kokain]]~~ ~~[[nn:Kokain]]~~ ~~[[pl:Kokaina]]~~ ~~[[pt:Cocaína]]~~ ~~[[ru:Кокаин]]~~ ~~[[simple:Cocaine]]~~ ~~[[sr:Кокаин]]~~ ~~[[fi:Kokaiini]]~~ ~~[[sv:Kokain]]~~ ~~[[vi:Cocaine]]~~ ~~[[tr:Kokain]]~~ ~~[[uk:Кокаїн]]~~

Retrieved from "https://en.wikipedia.org/wiki/Cocaine"

Languages

This page is not available in other languages.

Privacy policy
About Wikipedia
Disclaimers
Contact Wikipedia
Code of Conduct
Developers
Statistics
Cookie statement
Terms of Use
Desktop