|Systematic (IUPAC) name|
|methyl (1R,2R,3S,5S)-3- (benzoyloxy)-8-methyl-8-azabicyclo[3.2.1] octane-2-carboxylate|
|Topical, oral, insufflation, IV|
Nasal spray: 25–43%
|Excretion||Renal (benzoylecgonine and ecgonine methyl ester)|
|N01 R02, S01, S02|
|Synonyms||methylbenzoylecgonine, benzoylmethylecgonine, ecgonine methyl ester benzoate, 2b-Carbomethoxy −3b-benzoyloxy tropane|
|PDB ligand ID||COC (, )|
|Melting point||98 °C (208 °F)|
|Boiling point||187 °C (369 °F)|
|HCl: 1800–2500 mg/mL (20 °C)|
|(what is this?)|
Cocaine (INN) (benzoylmethylecgonine, an ecgonine derivative) is a tropane alkaloid that is obtained from the leaves of the coca plant. The name comes from "coca" and the alkaloid suffix "-ine", forming "cocaine". It is a stimulant, an appetite suppressant, and a nonspecific voltage gated sodium channel blocker, which in turn causes it to produce anaesthesia at low doses. Biologically, cocaine acts as a serotonin–norepinephrine–dopamine reuptake inhibitor, also known as a triple reuptake inhibitor (TRI). It is addictive due to its effect on the mesolimbic reward pathway. At high doses, it is markedly more dangerous than other CNS stimulants, including the entire amphetamine drug class, due to its effect on sodium channels, since blockade of Nav1.5 can cause sudden cardiac death.
Unlike most molecules, cocaine has pockets[clarification needed] with both high hydrophilic and lipophilic efficiency, violating the rule of hydrophilic-lipophilic balance. This causes it to cross the blood–brain barrier far better than other psychoactive chemicals and may even induce blood-brain barrier breakdown. Furthermore, many MAT inhibitors are not reinforcing like cocaine, and has led some to postulate another mechanism, such as DAT "inverse agonism" to play a role in cocaine's pharmacological mode of action.
The use of cocaine resulted in 4,300 deaths in 2013 up from 2,400 in 1990. Cocaine has a small number of legitimate medical applications. It was historically useful as a topical anesthetic in eye and nasal surgery, although it is now predominantly used for nasal and lacrimal duct surgery. In 2005, researchers from Kyoto University Hospital proposed the use of cocaine in conjunction with phenylephrine administered in the form of an eye drop as a diagnostic test for Parkinson's disease. Since it is controlled internationally by the Single Convention on Narcotic Drugs (Schedule I, preparation in Schedule III), the vast majority of cocaine use is illegal.
- 1 Medical effects
- 2 Biosynthesis
- 3 Chemistry
- 4 Pharmacology
- 5 Usage
- 6 History
- 7 Society and culture
- 8 Illicit trade
- 9 See also
- 10 References
- 11 Bibliography
- 12 Further reading
- 13 External links
Cocaine is a powerful nervous system stimulant. Its effects can last from fifteen to thirty minutes, to an hour. The duration of cocaine's effects depends on the amount taken and the route of administration. Cocaine can be in the form of fine white powder, bitter to the taste. When inhaled or injected, it causes a numbing effect. Crack cocaine is a smokeable form of cocaine made into small “rocks” by processing cocaine with sodium bicarbonate (baking soda) and water.
Cocaine increases alertness, feelings of well-being and euphoria, energy and motor activity, feelings of competence and sexuality. Cocaine's effects are very similar to that of amphetamine, however cocaine's effects tend to be much shorter lasting, but more prominent. Cocaine, due to its effects of increased alertness and feelings of well-being, is under consideration and trials along with MDMA, for the treatment of posttraumatic stress syndrome and attention deficit hyperactivity disorder. Anxiety, paranoia and restlessness can also occur, especially during the comedown. With excessive dosage, tremors, convulsions and increased body temperature are observed. Severe cardiac adverse events, particularly sudden cardiac death, become a serious risk at high doses due to cocaine's blocking effect on cardiac sodium channels.
With excessive or prolonged use, the drug can cause itching, fast heart rate, hallucinations, and paranoid delusions. Overdoses cause hyperthermia and a marked elevation of blood pressure, which can be life-threatening, arrhythmias, and death.
Chronic cocaine intake causes strong imbalances of transmitter levels in order to compensate extremes. Thus, receptors 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 and upregulation. However, studies suggest cocaine abusers do not show normal age-related loss of striatal dopamine transporter (DAT) sites, suggesting cocaine has neuroprotective properties for dopamine neurons. Possible side effects include insatiable hunger, aches, insomnia/oversleeping, lethargy, and persistent runny nose. Depression with suicidal ideation may develop in very heavy users. Finally, a loss of vesicular monoamine transporters, neurofilament proteins, and other morphological changes appear to indicate a long term damage of dopamine neurons. 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. Physical withdrawal is not dangerous. Physiological changes caused by cocaine withdrawal include vivid and unpleasant dreams, insomnia or hypersomnia, increased appetite and psychomotor retardation or agitation.
Physical side effects from chronic smoking of cocaine include coughing up blood, bronchospasm, itching, fever, diffuse alveolar infiltrates without effusions, pulmonary and systemic eosinophilia, chest pain, lung trauma, sore throat, asthma, hoarse voice, dyspnea (shortness of breath), and an aching, flu-like syndrome. Cocaine constricts blood vessels, 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. A common but untrue belief 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. Additionally, stimulants like cocaine, methamphetamine, and even caffeine cause dehydration and dry mouth. Since saliva is an important mechanism in maintaining one's oral pH level, chronic stimulant abusers who do not hydrate sufficiently may experience demineralization of their teeth due to the pH of the tooth surface dropping too low (below 5.5).
Chronic intranasal usage can degrade the cartilage separating the nostrils (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.
Cocaine may also greatly increase this risk of developing rare autoimmune or connective tissue diseases such as lupus, Goodpasture syndrome, vasculitis, glomerulonephritis, Stevens–Johnson syndrome, and other diseases. It can also cause a wide array of kidney diseases and kidney failure.
Addiction and dependence
The first synthesis and elucidation of the cocaine molecule was by Richard Willstätter in 1898. Willstätter's synthesis derived cocaine from tropinone. Since then, Robert Robinson and Edward Leete have made significant contributions to the mechanism of the synthesis. (-NO3)
The additional carbon atoms required for the synthesis of cocaine are derived from acetyl-CoA, by addition of two acetyl-CoA units to the N-methyl-Δ1-pyrrolinium cation. The first addition is a Mannich-like reaction with the enolate anion from acetyl-CoA acting as a nucleophile towards the pyrrolinium cation. The second addition occurs through a Claisen condensation. This produces a racemic mixture of the 2-substituted pyrrolidine, with the retention of the thioester from the Claisen condensation. In formation of tropinone from racemic ethyl [2,3-13C2]4(Nmethyl-2-pyrrolidinyl)-3-oxobutanoate there is no preference for either stereoisomer. In the biosynthesis of cocaine, however, only the (S)-enantiomer can cyclize to form the tropane ring system of cocaine. The stereoselectivity of this reaction was further investigated through study of prochiral methylene hydrogen discrimination. This is due to the extra chiral center at C-2. This process occurs through an oxidation, which regenerates the pyrrolinium cation and formation of an enolate anion, and an intramolecular Mannich reaction. The tropane ring system undergoes hydrolysis, SAM-dependent methylation, and reduction via NADPH for the formation of methylecgonine. The benzoyl moiety required for the formation of the cocaine diester is synthesized from phenylalanine via cinnamic acid. Benzoyl-CoA then combines the two units to form cocaine.
The biosynthesis begins with L-Glutamine, which is derived to L-ornithine in plants. The major contribution of L-ornithine and L-arginine as a precursor to the tropane ring was confirmed by Edward Leete. Ornithine then undergoes a pyridoxal phosphate-dependent decarboxylation to form putrescine. In animals, however, the urea cycle derives putrescine from ornithine. L-ornithine is converted to L-arginine, which is then decarboxylated via PLP to form agmatine. Hydrolysis of the imine derives N-carbamoylputrescine followed with hydrolysis of the urea to form putrescine. The separate pathways of converting ornithine to putrescine in plants and animals have converged. A SAM-dependent N-methylation of putrescine gives the N-methylputrescine product, which then undergoes oxidative deamination by the action of diamine oxidase to yield the aminoaldehyde. Schiff base formation confirms the biosynthesis of the N-methyl-Δ1-pyrrolinium cation.
Robert Robinson's acetonedicarboxylate
The biosynthesis of the tropane alkaloid, however, is still uncertain. Hemscheidt proposes that Robinson's acetonedicarboxylate emerges as a potential intermediate for this reaction. Condensation of N-methylpyrrolinium and acetonedicarboxylate would generate the oxobutyrate. Decarboxylation leads to tropane alkaloid formation.
Reduction of tropinone
The reduction of tropinone is mediated by NADPH-dependent reductase enzymes, which have been characterized in multiple plant species. These plant species all contain two types of the reductase enzymes, tropinone reductase I and tropinone reductase II. TRI produces tropine and TRII produces pseudotropine. Due to differing kinetic and pH/activity characteristics of the enzymes and by the 25-fold higher activity of TRI over TRII, the majority of the tropinone reduction is from TRI to form tropine.
Cocaine in its purest form is a white, pearly product. Cocaine appearing in powder form is a salt, typically cocaine hydrochloride (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. Adulterated cocaine is often a white, off-white or pinkish powder.
The color of “crack” cocaine depends upon several factors including the origin of the cocaine used, the method of preparation – with ammonia or baking soda – 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.
Cocaine is a weakly alkaline compound (an "alkaloid"), and can therefore combine with acidic compounds to form various salts. The hydrochloride (HCl) salt of cocaine is by far the most commonly encountered, although the sulfate (-SO4) and the nitrate (-NO3) are occasionally seen. Different salts dissolve to a greater or lesser extent in various solvents – the hydrochloride salt is polar in character and is quite soluble in water.
Smoking freebase cocaine has the additional effect of releasing methylecgonidine into the user's system due to the pyrolysis of the substance (a side effect which insufflating or injecting powder cocaine does not create). Some research suggests that smoking freebase cocaine can be even more cardiotoxic than other routes of administration because of methylecgonidine's effects on lung tissue and liver tissue.
Pure cocaine is prepared by neutralizing its compounding salt with an alkaline solution which will precipitate to non-polar basic cocaine. It is further refined through aqueous-solvent liquid-liquid extraction.
Crack is a lower purity form of free-base cocaine that is usually produced by neutralization of cocaine hydrochloride with a solution of baking soda (sodium bicarbonate, NaHCO3) and water, producing a very hard/brittle, off-white-to-brown colored, amorphous material that contains sodium carbonate, entrapped water, and other by-products as the main impurities.
The "freebase" and "crack" forms of cocaine are usually administered by vaporization of the powdered substance into smoke, which is then inhaled.
The origin of the name "crack" comes from the "crackling" sound (and hence the onomatopoeic moniker “crack”) that is produced when the cocaine and its impurities (i.e. water, sodium bicarbonate) are heated past the point of vaporization.
Pure cocaine base/crack can be smoked because it vaporizes smoothly, with little or no decomposition at 98 °C (208 °F), which is below the boiling point of water. The smoke produced from cocaine base is usually described as having a very distinctive, pleasant taste.
In contrast, cocaine hydrochloride does not vaporize until heated to a much higher 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.
Smoking or vaporizing cocaine and inhaling it into the lungs produces an almost immediate "high" that can be very powerful (and addicting) quite rapidly – this initial crescendo of stimulation is known as a "rush". While the stimulating effects may last for hours, the euphoric sensation is very brief, prompting the user to smoke more immediately.
Coca leaf infusions
|This article needs additional citations for verification. (April 2014)|
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.
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. Importantly, these results also suggest strongly that the primary pharmacologically active metabolite in coca leaf infusions is actually cocaine and not the secondary alkaloids.[improper synthesis?]
Routes of administration
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", "gummers", or "cocoa puffs" for this type of administration. This is mostly done with the small amounts of cocaine remaining on a surface after insufflation (snorting). Another oral method is to wrap up some cocaine in rolling paper and swallow (parachute) it. This is sometimes called a "snow bomb."
Coca leaves are typically mixed with an alkaline substance (such as lime) and chewed into a wad that is retained in the mouth between gum and cheek (much in 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. 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 an inefficient one.
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% 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.
Contrary to popular belief, both ingestion and insufflation result in approximately the same proportion of the drug being absorbed: 30 to 60%. 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.
Coca tea, an infusion of coca leaves, is also a traditional method of consumption. The tea has often been recommended for travelers in the Andes to prevent altitude sickness. However, its actual effectiveness has never been systematically studied. This method of consumption has been practised for many centuries by the indigenous 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.
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.” 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 mood elevation, and the tea was essentially harmless. Despite this, the DEA seized several shipments in Hawaii, Chicago, Georgia, and several locations on the East Coast of the United States, and the product was removed from the shelves.
Nasal insufflation (known colloquially as "snorting," "sniffing," or "blowing") is the most common method of ingestion of recreational powdered cocaine in the Western world. The drug coats and is absorbed through the mucous membranes lining the sinuses. When insufflating cocaine, absorption through the nasal membranes is approximately 30–60%, 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 of cocaine users, the average time taken to reach peak subjective effects was 14.6 minutes. Any damage to the inside of the nose is because cocaine highly constricts blood vessels – and therefore blood and oxygen/nutrient flow – to that area. Nosebleeds after cocaine insufflation are due to irritation and damage of mucus membranes by foreign particles and adulterants and not the cocaine itself; as a vasoconstrictor, cocaine acts to reduce bleeding.
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.
Rolled up banknotes, hollowed-out pens, cut straws, pointed ends of keys, specialized spoons, long fingernails, and (clean) tampon applicators 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, CD case or book) and divided into "bumps", "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 35 mg (a "bump") to 100 mg (a "rail")[dubious ]. As tolerance builds rapidly in the short-term (hours), many lines are often snorted to produce greater effects.
Drug injection provides the highest blood levels of drug in the shortest amount of time. Subjective effects not commonly shared with other methods of administration include a ringing in the ears moments after injection (usually when in excess of 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. The euphoria passes quickly. Aside from the toxic effects of cocaine, there is also danger of circulatory 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 infections if sterile injecting equipment is not available or used. Additionally, because cocaine is a vasoconstrictor, and usage often entails multiple injections within several hours or less, subsequent injections are progressively more difficult to administer, which in turn may lead to more injection attempts and more sequelae from improperly performed injection.
An injected mixture of cocaine and heroin, known as “speedball” is a particularly 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, including celebrities such as John Belushi, Chris Farley, Mitch Hedberg, River Phoenix and Layne Staley.
Inhalation or smoking is one of the several means cocaine is administered. Cocaine is smoked by inhaling the vapor by sublimating solid cocaine by heating. In a 2000 Brookhaven National Laboratory medical department study, based on self reports of 32 abusers who participated in the study,"peak high" was found at mean of 1.4min +/- 0.5 minutes.
Smoking freebase or crack cocaine is most often accomplished using a pipe made from a small glass tube, often taken from "love roses," small glass tubes with a paper rose that are promoted as romantic gifts. These are sometimes called "stems", "horns", "blasters" and "straight shooters". A small piece of clean heavy copper or occasionally stainless steel scouring pad – often called a "brillo" (actual Brillo Pads contain soap, and are not used) or "chore" (named for Chore Boy brand copper scouring pads) – serves as a reduction base and flow modulator in which the "rock" can be melted and boiled to vapor. Crack smokers also sometimes smoke through a soda can with small holes in the bottom.
Crack is smoked by placing it at the end of the pipe; a flame held close to it produces vapor, which is then inhaled by the smoker. The effects, felt almost immediately after smoking, are very intense and do not last long – usually 5 to 15 minutes.
When smoked, cocaine is sometimes combined with other drugs, such as cannabis, often rolled into a joint or blunt. Powdered cocaine is also sometimes smoked, though heat destroys much of the chemical; smokers often sprinkle it on cannabis.
The language referring to paraphernalia and practices of smoking cocaine vary, as do the packaging methods in the street level sale.
Little research has been focused on the suppository (anal or vaginal insertion) method of administration, also known as "plugging". This method of administration is commonly administered using an oral syringe. Cocaine can be dissolved in water and withdrawn into an oral syringe which may then be lubricated and inserted into the anus or vagina before the plunger is pushed. Anecdotal evidence of its effects are infrequently discussed, possibly due to social taboos in many cultures. The rectum and the vaginal canal is where the majority of the drug would likely be taken up, through the membranes lining its walls.
Mechanism of action
The pharmacodynamics of cocaine involve the complex relationships of neurotransmitters (inhibiting monoamine uptake in rats with ratios of about: serotonin:dopamine = 2:3, serotonin:norepinephrine = 2:5) The most extensively studied effect of cocaine on the central nervous system is the blockade of the dopamine transporter protein. 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 presynaptic neuron, where it is taken up into storage 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. This results in an enhanced and prolonged postsynaptic effect of dopaminergic signaling 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 down-regulation of dopamine receptors and enhanced signal transduction. The decreased dopaminergic signaling after chronic cocaine use may contribute to depressive mood disorders and sensitize this important brain reward circuit to the reinforcing effects of cocaine (for example, enhanced dopaminergic signalling only when cocaine is self-administered). This sensitization contributes to the intractable nature of addiction and relapse.
Dopamine-rich brain regions such as the ventral tegmental area, nucleus accumbens, and prefrontal cortex are frequent targets of cocaine addiction research. Of particular interest is the pathway consisting of dopaminergic neurons originating in the ventral tegmental area that terminate in the nucleus accumbens. This projection may function as a "reward center", in that it seems to show activation in response to drugs of abuse like cocaine in addition to natural rewards like food or sex. While the precise role of dopamine in the subjective experience of reward is highly controversial among neuroscientists, the release of dopamine in the nucleus accumbens is widely considered to be at least partially responsible for cocaine's rewarding effects. This hypothesis is largely based on laboratory data involving rats that are trained to self-administer cocaine. If dopamine antagonists are infused directly into the nucleus accumbens, 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.
Cocaine's effects on serotonin (5-hydroxytryptamine, 5-HT) show across multiple serotonin receptors, and is shown to inhibit the re-uptake of 5-HT3 specifically as an important contributor to the effects of cocaine. The overabundance of 5-HT3 receptors in cocaine conditioned rats display this trait, however the exact effect of 5-HT3 in this process is unclear. The 5-HT2 receptor (particularly the subtypes 5-HT2AR, 5-HT2BR and 5-HT2CR) show influence in the evocation of hyperactivity displayed in cocaine use.
In addition to the mechanism shown on the above chart, cocaine has been demonstrated to bind as to directly stabilize the 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 habituation of the substance so much as the conformation and binding properties to where & how on the transporter the molecule binds.
Sigma receptors are affected by cocaine, as cocaine functions as a sigma ligand agonist. Further specific receptors it has been demonstrated to function on are NMDA and the D1 dopamine receptor.
Cocaine also blocks sodium channels, thereby interfering with the propagation of action potentials; 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 phenyltropanes analogues which have that removed. In addition to this cocaine has some target binding to the site of the Kappa-opioid receptor as well. 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 and clock genes in behavioral actions of cocaine.
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 do not 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.
Cocaine can often cause reduced food intake, many chronic users lose their appetite and can experience severe malnutrition and significant weight loss. Cocaine effects, further, are shown to be potentiated for the user when used in conjunction with new surroundings and stimuli, and otherwise novel environs.
Metabolism and excretion
Cocaine is extensively metabolized, primarily in the liver, with only about 1% excreted unchanged in the urine. The metabolism is dominated by hydrolytic ester cleavage, so the eliminated metabolites consist mostly of benzoylecgonine (BE), the major metabolite, and other significant metabolites in lesser amounts such as ecgonine methyl ester (EME) and ecgonine. Further minor metabolites of cocaine include norcocaine, p-hydroxycocaine, m-hydroxycocaine, p-hydroxybenzoylecgonine (pOHBE), and m-hydroxybenzoylecgonine.
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.
If consumed with alcohol, cocaine combines with alcohol in the liver to form cocaethylene. Studies have suggested cocaethylene is both more euphorigenic, and has a higher cardiovascular toxicity than cocaine by itself.
A study in mice has suggested that capsaicin found in pepper spray may interact with cocaine with potentially fatal consequences. The method through which they would interact however, is not known.
Detection in biological fluids
Cocaine and its major metabolites may be quantitated in blood, plasma or urine to monitor for abuse, confirm a diagnosis of poisoning or assist in the forensic investigation of a traffic or other criminal violation or a sudden death. Most commercial cocaine immunoassay screening tests cross-react appreciably with the major cocaine metabolites, but 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. In 2011, researchers at John Jay College of Criminal Justice reported that dietary zinc supplements can mask the presence of cocaine and other drugs in urine. Similar claims have been made in web forums on that topic.
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 anesthetics such as benzocaine, proparacaine, lignocaine-xylocaine-lidocaine, 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 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 before the procedure, thus performing the dual role of both numbing the area to be cauterized, and vasoconstriction. Even when used this way, some of the used cocaine may be absorbed through oral or nasal mucosa and give systemic effects.
In 2005, researchers from Kyoto University Hospital proposed the use of cocaine in conjunction with phenylephrine administered in the form of an eye drop as a diagnostic test for Parkinson's disease.
||The examples and perspective in this article deal primarily with Western culture and do not represent a worldwide view of the subject. (December 2014)|
According to a 2007 United Nations report, Spain is the country with the highest rate of cocaine usage (3.0% of adults in the previous year). Other countries where the usage rate meets or exceeds 1.5% are the United States (2.8%), England and Wales (2.4%), Canada (2.3%), Italy (2.1%), Bolivia (1.9%), Chile (1.8%), and Scotland (1.5%).
Cocaine is the second most popular illegal recreational drug in Europe (behind cannabis). Since the mid-1990s, overall cocaine usage in Europe has been on the rise, but usage rates and attitudes tend to vary between countries. Countries with the highest usage rates are: The United Kingdom, Spain, Italy, and Republic of Ireland.
Approximately 12 million Europeans (3.6%) have used cocaine at least once, 4 million (1.2%) in the last year, and 2 million in the last month (0.5%).
About 3.5 million or 87.5% of those who have used the drug in the last year[when?] are young adults (15–34 years old). Usage is particularly prevalent among this demographic: 4% to 7% of males have used cocaine in the last year in Spain, Denmark, Republic of Ireland, Italy, and the United Kingdom. The ratio of male to female users is approximately 3.8:1, but this statistic varies from 1:1 to 13:1 depending on country.
Cocaine is the second most popular illegal recreational drug in the United States (behind cannabis) and the U.S. is the world's largest consumer of cocaine. Cocaine is commonly used in middle to upper class communities and is known as a "rich man's drug". It is also popular amongst college students, as a party drug. A study throughout the entire United States has reported that around 48 percent of people who graduated high school in 1979 have used Cocaine recreationally during some point in their lifetime, compared to approximately 20 percent of students who graduated between the years of 1980 and 1995.  Its users span over different ages, races, and professions. In the 1970s and 1980s, the drug became particularly popular in the disco culture as cocaine usage was very common and popular in many discos such as Studio 54.
For over a thousand years South American indigenous peoples have chewed the leaves of Erythroxylon coca, a plant that contains vital nutrients as well as numerous alkaloids, including cocaine. The coca leaf was, and still is, chewed almost universally by some indigenous communities. The remains of coca leaves have been found with ancient Peruvian mummies, and pottery from the time period depicts humans with bulged cheeks, indicating the presence of something on which they are chewing. There is also evidence that these cultures used a mixture of coca leaves and saliva as an anesthetic for the performance of trepanation.
When the Spanish arrived in South America, most at first ignored aboriginal claims that the leaf gave them strength and energy, and declared the practice of chewing it the work of the Devil. But after discovering that these claims were true, they legalized and taxed the leaf, taking 10% off the value of each crop. In 1569, Nicolás Monardes described the indigenous peoples' practice of chewing a mixture of tobacco and coca leaves to induce "great contentment":
When they wished to make themselves drunk and out of judgment they chewed a mixture of tobacco and coca leaves which make them go as they were out of their wittes.
Coca protects the body from many ailments, and our doctors use it in powdered form to reduce the swelling of wounds, to strengthen broken bones, to expel cold from the body or prevent it from entering, and to cure rotten wounds or sores that are full of maggots. And if it does so much for outward ailments, will not its singular virtue have even greater effect in the entrails of those who eat it?
Isolation and naming
Although the stimulant and hunger-suppressant properties of coca had been known for many centuries, the isolation of the cocaine alkaloid was not achieved until 1855. Various European scientists had attempted to isolate cocaine, but none had been successful for two reasons: the knowledge of chemistry required was insufficient at the time. Additionally contemporary conditions of sea-shipping from South America could degrade the cocaine in the plant samples available to Europeans.
The cocaine alkaloid was first isolated by the German chemist Friedrich Gaedcke in 1855. Gaedcke named the alkaloid "erythroxyline", and published a description in the journal Archiv der Pharmazie.
In 1856, Friedrich Wöhler asked Dr. Carl Scherzer, a scientist aboard the Novara (an Austrian frigate sent by Emperor Franz Joseph to circle the globe), to bring him a large amount of coca leaves from South America. In 1859, the ship finished its travels and Wöhler received a trunk full of coca. Wöhler passed on the leaves to Albert Niemann, a Ph.D. student at the University of Göttingen in Germany, who then developed an improved purification process.
Niemann described every step he took to isolate cocaine in his dissertation titled Über eine neue organische Base in den Cocablättern (On a New Organic Base in the Coca Leaves), which was published in 1860—it earned him his Ph.D. and is now in the British Library. He wrote of the alkaloid's "colourless transparent prisms" and said that, "Its solutions have an alkaline reaction, a bitter taste, promote the flow of saliva and leave a peculiar numbness, followed by a sense of cold when applied to the tongue." Niemann named the alkaloid "cocaine" from "coca" (from Quechua "cuca") + suffix "ine". Because of its use as a local anesthetic, a suffix "-caine" was later extracted and used to form names of synthetic local anesthetics.
The first synthesis and elucidation of the structure of the cocaine molecule was by Richard Willstätter in 1898. The synthesis started from tropinone, a related natural product and took five steps.
With the discovery of this new alkaloid, Western medicine was quick to exploit the possible uses of this plant.
In 1879, Vassili von Anrep, of the University of Würzburg, devised an experiment to demonstrate the analgesic properties of the newly discovered alkaloid. He prepared two separate jars, one containing a cocaine-salt solution, with the other containing merely salt water. He then submerged a frog's legs into the two jars, one leg in the treatment and one in the control solution, and proceeded to stimulate the legs in several different ways. The leg that had been immersed in the cocaine solution reacted very differently from the leg that had been immersed in salt water.
Karl Koller (a close associate of Sigmund Freud, who would write about cocaine later) experimented with cocaine for ophthalmic usage. In an infamous experiment in 1884, he experimented upon himself by applying a cocaine solution to his own eye and then pricking it with pins. His findings were presented to the Heidelberg Ophthalmological Society. Also in 1884, Jellinek demonstrated the effects of cocaine as a respiratory system anesthetic. In 1885, William Halsted demonstrated nerve-block anesthesia, and James Leonard Corning demonstrated peridural anesthesia. 1898 saw Heinrich Quincke use cocaine for spinal anesthesia.
Today, cocaine has very limited medical use. See the section Cocaine as a local anesthetic
In 1859, an Italian doctor, Paolo Mantegazza, returned from Peru, where he had witnessed first-hand the use of coca by the local indigenous peoples. He proceeded to experiment on himself and upon his return to Milan he wrote a paper in which he described the effects. In this paper he declared coca and cocaine (at the time they were assumed to be the same) as being useful medicinally, in the treatment of "a furred tongue in the morning, flatulence, and whitening of the teeth."
A chemist named Angelo Mariani who read Mantegazza's paper became immediately intrigued with coca and its economic potential. In 1863, Mariani started marketing a wine called Vin Mariani, which had been treated with coca leaves, to become cocawine. The ethanol in wine acted as a solvent and extracted the cocaine from the coca leaves, altering the drink's effect. It contained 6 mg cocaine per ounce of wine, but Vin Mariani which was to be exported contained 7.2 mg per ounce, to compete with the higher cocaine content of similar drinks in the United States. A "pinch of coca leaves" was included in John Styth Pemberton's original 1886 recipe for Coca-Cola, though the company began using decocainized leaves in 1906 when the Pure Food and Drug Act was passed. The actual amount of cocaine that Coca-Cola contained during the first 20 years of its production is practically impossible to determine.
In 1879 cocaine began to be used to treat morphine addiction. Cocaine was introduced into clinical use as a local anesthetic in Germany in 1884, about the same time as Sigmund Freud published his work Über Coca, in which he wrote that cocaine causes:
Exhilaration and lasting euphoria, which in no way differs from the normal euphoria of the healthy person. You perceive an increase of self-control and possess more vitality and capacity for work. In other words, you are simply normal, and it is soon hard to believe you are under the influence of any drug. Long intensive physical work is performed without any fatigue. This result is enjoyed without any of the unpleasant after-effects that follow exhilaration brought about by alcoholic beverages. No craving for the further use of cocaine appears after the first, or even after repeated taking of the drug.
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."
By the late Victorian era cocaine use had appeared as a vice in literature. For example, it was injected by Arthur Conan Doyle's fictional Sherlock Holmes, generally to offset the boredom he felt when he was not working on a case.
In early 20th-century Memphis, Tennessee, cocaine was sold in neighborhood drugstores on Beale Street, costing five or ten cents for a small boxful. Stevedores along the Mississippi River used the drug as a stimulant, and white employers encouraged its use by black laborers.
||The examples and perspective in this section deal primarily with the United States and do not represent a worldwide view of the subject. (August 2012)|
Prohibition of cocaine in the United States
Calls for prohibition began long before the Harrison Act was passed by Congress in 1914 – a law requiring cocaine and narcotics to be dispensed only with a doctor's order. Before this, various factors and groups acted on primarily a state level influencing a move towards prohibition and away from a laissez-faire attitude. Cocaine consumption had grown in 1903 to about five times that of 1890, predominately by non-medical users outside the middle-aged, white, professional class. Cocaine became associated with laborers, youths, blacks and the urban underworld.
Popularization of cocaine is first evident with laborers who used it as a stimulant to increase productivity, often supplied by employers. African American workers were believed by employers to be better at physical work and it was thought that it provided added strength to their constitution which, according to the Medical News, made blacks “impervious to the extremes of heat and cold.” Instead, cocaine use quickly acquired a reputation as dangerous and in 1897, the first state bill of control for cocaine sales came from a mining county in Colorado. Laborers from other races used cocaine, such as in northern cities, where cocaine was often cheaper than alcohol. In the Northeast in particular, cocaine became popular amongst workers in factories, textile mills and on rail roads. In some instances, cocaine use supplemented or replaced caffeine as the drug-of-choice to keep workers awake and working overtime.
Fears of coerced cocaine use, and in particular that young girls would become addicted and thereby enter prostitution, were widespread. Tales of the corruption of the youth by cocaine were common but there is little evidence to support their veracity. Mainstream media reported cocaine epidemics as early as 1894 in Dallas, Texas. Reports of the cocaine epidemic would foreshadow a familiar theme in later so-called epidemics, namely that cocaine presented a social threat more dangerous than simple health effects and had insidious results when used by blacks and members of the lower class. Similar anxiety-ridden reports appeared throughout cities in the South leading some to declare that “the cocaine habit has assumed the proportions of an epidemic among the colored people.” In 1900, state legislatures in Alabama, Georgia and Tennessee considered anti-cocaine bills for the first time.
Hyperbolic reports of the effect of cocaine on African Americans went hand-in-hand with this hysteria. In 1901, the Atlanta Constitution reported that “Use of the drug [cocaine] among negroes is growing to an alarming extent.” The New York Times reported that under the influence of cocaine, “sexual desires are increased and perverted … peaceful negroes become quarrelsome, and timid negroes develop a degree of 'Dutch courage' that is sometimes almost incredible.” A medical doctor even wrote “cocaine is often the direct incentive to the crime of rape by the negroes.” To complete the characterization, a judge in Mississippi declared that supplying a “negro” with cocaine was more dangerous than injecting a dog with rabies.
These attitudes not only influenced drug law and policy but also led to increased violence against African Americans. In 1906, a major race riot led by whites erupted; it was sparked by reports of crimes committed by black ‘cocaine fiends.’ Indeed, white-led, race riots spawning from reports of blacks under the influence of cocaine were not uncommon. Police in the South widely adopted the use of a heavier caliber handguns so as to better stop a cocaine-crazed black person – believed to be empowered with super-human strength. Another dangerous myth perpetuated amongst police was that cocaine imbued African Americans with tremendous accuracy with firearms and therefore police were better advised to shoot first in questionable circumstances. Ultimately public opinion rested against the cocaine user. Criminality was commonly believed to be a natural result of cocaine use. Much of the influence for these kind of perceptions came from the widespread publicity given to notorious cases. While the historical reality of cocaine’s effect on violence and crime is difficult to disentangle from inflamed perceptions, it does appear that public opinion was swayed by the image of the violent, cocaine-crazed fiend and pushed over the edge by a few violent episodes. It was an image of the cocaine-user that carried acute racial overtones.
Before any substantive federal regulation of cocaine, state and local municipalities evoked their own means to regulate cocaine. Because of the initial lack of targeted legislation, on both federal and state level, the most typical strategy by law enforcement was the application of nuisance laws pertaining to vagrancy and disturbing the peace. Subsequent legislative actions aimed at controlling the distribution of cocaine rather than its manufacture. Reformers took this approach in part because of legal precedents which made it easier to control distributors such as pharmacies; state and local boards of health or boards of pharmacy often took the place of regulatory bodies for controlling the distribution of cocaine. Some states took the position of outright banning of all forms of cocaine sale; Georgia was the first to do this in 1902. A New Orleans ordinance banned cocaine sales as well but left an ill-defined exception for therapeutic uses. A more common requirement was to restrict the sale of cocaine or impose labeling requirements. A 1907 California law limiting sale of cocaine to only those with a physician’s prescription resulted in the arrest of over 50 store owners and clerks in the first year. A 1913 New York state law limited druggists’ cocaine stocks to under 5 ounces. Labeling requirements initially operated on a state level with some states even going so far as to require that cocaine and cocaine-containing products be labeled as poison.
Eventually the federal government stepped in and instituted a national labeling requirement for cocaine and cocaine-containing products through the Food and Drug Act of 1906. 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 set up a regulatory and licensing regime. 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 – leading the Journal of American Medicine to remark, “[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.” The Harrison Act left manufacturers of cocaine untouched so long as they met certain purity and labeling standards. Despite that cocaine was typically illegal to sell and legal outlets were more rare, the quantities of legal cocaine produced declined very little. Legal cocaine quantities did not decrease until the Jones-Miller Act of 1922 put serious restrictions on cocaine manufactures.
In many countries, cocaine is a popular recreational drug. In the United States, the development of "crack" cocaine introduced the substance to a generally poorer inner-city market. Use of the powder form has stayed relatively constant, experiencing a new height of use during the late 1990s and early 2000s in the U.S., and has become much more popular in the last few years in the UK.[when?]
Cocaine use is prevalent across all socioeconomic strata, including age, demographics, economic, social, political, religious, and livelihood.
The estimated U.S. cocaine market exceeded US$70 billion in street value for the year 2005, exceeding revenues by corporations such as Starbucks. There is a tremendous demand for cocaine in the U.S. market, particularly among those who are making incomes affording luxury spending, such as single adults and professionals with discretionary income. Cocaine’s status as a club drug shows its immense popularity among the "party crowd".
In 1995 the World Health Organization (WHO) and the United Nations Interregional Crime and Justice Research Institute (UNICRI) announced in a press release the publication of the results of the largest global study on cocaine use ever undertaken. However, a decision by an American representative in the World Health Assembly banned the publication of the study, because it seemed to make a case for the positive uses of cocaine. An excerpt of the report strongly conflicted with accepted paradigms, for example "that occasional cocaine use does not typically lead to severe or even minor physical or social problems." In the sixth meeting of the B committee the US representative threatened that "If WHO activities relating to drugs failed to reinforce proven drug control approaches, funds for the relevant programs should be curtailed". This led to the decision to discontinue publication. A part of the study has been recuperated. Available are profiles of cocaine use in 20 countries.
It was reported in October 2010 that the use of cocaine in Australia has doubled since monitoring began in 2003.
A problem with illegal cocaine use, especially in the higher volumes used to combat fatigue (rather than increase euphoria) by long-term users, is the risk of ill effects or damage caused by the compounds used in adulteration. Cutting or "stepping on" the drug is commonplace, using compounds which simulate ingestion effects, such as Novocain (procaine) producing temporary anesthaesia as many users believe a strong numbing effect is the result of strong and/or pure cocaine, ephedrine or similar stimulants that are to produce an increased heart rate. The normal adulterants for profit are inactive sugars, usually mannitol, creatine or glucose, so introducing active adulterants gives the illusion of purity and to 'stretch' or make it so a dealer can sell more product than without the adulterants. The adulterant of sugars therefore allows the dealer to sell the product for a higher price because of the illusion of purity and allows to sell more of the product at that higher price, enabling dealers to significantly increase revenue with little additional cost for the adulterants. A study by the European Monitoring Centre for Drugs and Drug Addiction in 2007 showed that the purity levels for street purchased cocaine was often under 5% and on average under 50% pure.
Society and culture
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.
Some countries, such as Peru and Bolivia permit the cultivation of coca leaf for traditional consumption by the local indigenous population, but nevertheless prohibit the production, sale and consumption of cocaine. In addition, some parts of Europe and Australia allow processed cocaine for medicinal uses only.
In 2004, according to the United Nations, 589 tonnes of cocaine were seized globally by law enforcement authorities. Colombia seized 188 t, the United States 166 t, Europe 79 t, Peru 14 t, Bolivia 9 t, and the rest of the world 133 t.
Because of the drugs potential for addiction and overdose, cocaine is generally treated as a '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, are occasionally purchased and sold, but this is exceedingly rare as it is much easier and more profitable to conceal and smuggle it in powdered form. The scale of the market is immense: 770 tonnes times $100 per gram retail = up to $77 billion.
Until 2012, Colombia was the world's leading producer of cocaine. Three-quarters of the world's annual yield of cocaine has been produced in Colombia, both from cocaine base imported from Peru (primarily the Huallaga Valley) and Bolivia, and from locally grown coca. There was a 28% 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.
An interview with a coca farmer published in 2003 described a mode of production by acid-base extraction that has changed little since 1905. Roughly 625 pounds (283 kg) of leaves were harvested per hectare, six times per year. The leaves were dried for half a day, then chopped into small pieces with a strimmer and sprinkled with a small amount of powdered cement (replacing sodium carbonate from former times). Several hundred pounds of this mixture was soaked in 50 US gallons (190 L) of gasoline for a day, then the gasoline was removed and the leaves were pressed for remaining liquid, after which they could be discarded. Then battery acid (weak sulfuric acid) was used, one bucket per 55 lb (25 kg) of leaves, to create a phase separation in which the cocaine free base in the gasoline was acidified and extracted into a few buckets of "murky-looking smelly liquid". Once powdered caustic soda was added to this, the cocaine precipitated and could be removed by filtration through a cloth. The resulting material, when dried, was termed pasta and sold by the farmer. The 3750 pound yearly harvest of leaves from a hectare produced 6 lb (2.5 kg) of pasta, approximately 40–60% cocaine. Repeated recrystallization from solvents, producing pasta lavada and eventually crystalline cocaine, were performed at specialized laboratories after the sale.
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. Although production fell temporarily, coca crops rebounded in numerous smaller fields in Colombia, rather than the larger plantations.
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.
|Net cultivation km2 (sq mi)||1,875 (724)||2,218 (856)||2,007.5 (775.1)||1,663 (642)||1,662 (642)|
|Potential pure cocaine production (tonnes)||770||925||830||680||645|
The latest estimate provided by the U.S. authorities on the annual production of cocaine in Colombia refers to 290 metric tons. As of the end of 2011, the seizure operations of Colombian cocaine carried out in different countries have totaled 351.8 metric tons of cocaine, i.e. 121.3% of Colombia’s annual production according to the U.S. Department of State’s estimates. 
Synthetic cocaine would be highly desirable to the illegal drug industry, as it would eliminate the high visibility and low reliability of offshore sources and international smuggling, replacing them with clandestine domestic laboratories, as are common for illicit methamphetamine. However, natural cocaine remains the lowest cost and highest quality supply of cocaine. Actual full synthesis of cocaine is rarely done. Formation of inactive enantiomers (cocaine has 4 chiral centres – 1R, 2R, 3S, and 5S – hence a total potential of 16 possible enantiomers and diastereoisomers) plus synthetic by-products limits the yield and purity. Names like "synthetic cocaine" and "new cocaine" have been misapplied to phencyclidine (PCP) and various designer drugs.
Trafficking and distribution
Organized criminal gangs operating on a large scale dominate the cocaine trade. Most cocaine is grown and processed in South America, particularly in Colombia, Bolivia, Peru, and smuggled into the United States and Europe, the United States being the world's largest consumer of cocaine, where it is sold at huge markups; usually in the US at $80–$120 for 1 gram, and $250–300 for 3.5 grams (⅛ of an ounce, or an "eight ball").
Caribbean and Mexican routes
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 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.
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 to 700 kg (1,102 to 1,543 lb) in the Bahama Islands or off the coast of Puerto Rico, mid-ocean boat-to-boat transfers of 500 to 2,000 kg (1,102 to 4,409 lb), and the commercial shipment of tonnes of cocaine through the port of Miami.
Another route of cocaine traffic goes through Chile, this route is primarily used for cocaine produced in Bolivia since the nearest seaports lie in northern Chile. The arid Bolivia-Chile border is easily crossed by 4x4 vehicles that then head to the seaports of Iquique and Antofagasta. While the price of cocaine is higher in Chile than in Peru and Bolivia, the final destination is usually Europe, especially Spain where drug dealing networks exist among South American immigrants.
Cocaine is also carried in small, concealed, kilogram quantities across the border by couriers known as “mules” (or “mulas”), who cross a border either legally, for example, through a port or airport, or illegally elsewhere. 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 alone.
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 boats, as those used by the local populations.
Sophisticated drug subs are the latest tool drug runners are using to bring cocaine north from Colombia, it was reported on 20 March 2008. Although the vessels were once viewed as a quirky sideshow in the drug war, they are becoming faster, more seaworthy, and capable of carrying bigger loads of drugs than earlier models, according to those charged with catching them.
Sales to consumers
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, Miami, and Boston. In the West, cocaine usage was lower, which was thought to be due to a switch to methamphetamine among some users; methamphetamine is cheaper, three and a half times more powerful, and lasts 12 to 24 times longer with each dose. Nevertheless, the number of cocaine users remain high, with a large concentration among urban youth.
In addition to the amounts previously mentioned, cocaine can be sold in "bill sizes": for example, $10 might purchase a "dime bag," a very small amount (0.1–0.15 g) of cocaine. Twenty dollars might purchase 0.15–0.3 g. However, in lower Texas, it is sold cheaper due to it being easier to receive: a dime for $10 is 0.4g, a 20 is 0.8–1.0 gram and an 8-ball (3.5g) is sold for $60 to $80, depending on the quality and dealer. These amounts and prices are very popular among young people because they are inexpensive and easily concealed on one's body. Quality and price can vary dramatically depending on supply and demand, and on geographic region.
The European Monitoring Centre for Drugs and Drug Addiction reports that the typical retail price of cocaine varied between €50 and €75 per gram in most European countries, although Cyprus, Romania, Sweden and Turkey reported much higher values.
World annual cocaine consumption, as of 2000, stands at around 600 tonnes, with the United States consuming around 300 t, 50% of the total, Europe about 150 t, 25% of the total, and the rest of the world the remaining 150 t or 25%.
The 2010 UN World Drug Report concluded that "it appears that the North American cocaine market has declined in value from US$47 billion in 1998 to US$38 billion in 2008. Between 2006 and 2008, the value of the market remained basically stable."
- Black cocaine
- CART, a purported "endogenous cocaine"
- Coca alkaloids
- Coca eradication
- Coca Museum
- Cocaine (data page)
- Cocaine Anonymous
- Cocaine intoxication
- Cocaine paste ("paco")
- Cocaine: An Unauthorized Biography (book)
- Crack epidemic
- Crack lung
- Disco subculture, in which cocaine played a major role
- Ecgonine benzoate
- Legal status of cocaine
- List of cocaine analogues
- Prenatal cocaine exposure
- Route 36, cocaine bar in Bolivia
- Fattinger K, Benowitz NL, Jones RT, Verotta D (2000). "Nasal mucosal versus gastrointestinal absorption of nasally administered cocaine". Eur. J. Clin. Pharmacol. 56 (4): 305–10. doi:10.1007/s002280000147. PMID 10954344.
- Barnett G, Hawks R, Resnick R (1981). "Cocaine pharmacokinetics in humans". J Ethnopharmacol 3 (2–3): 353–66. doi:10.1016/0378-8741(81)90063-5. PMID 7242115.
- Jeffcoat AR, Perez-Reyes M, Hill JM, Sadler BM, Cook CE (1989). "Cocaine disposition in humans after intravenous injection, nasal insufflation (snorting), or smoking". Drug Metab. Dispos. 17 (2): 153–9. PMID 2565204.
- Wilkinson P, Van Dyke C, Jatlow P, Barash P, Byck R (1980). "Intranasal and oral cocaine kinetics". Clin. Pharmacol. Ther. 27 (3): 386–94. doi:10.1038/clpt.1980.52. PMID 7357795.
- Aggrawal, Anil (1995). Narcotic Drugs. National Book Trust, India. pp. 52–3. ISBN 978-81-237-1383-0.
- Fattore L, Piras G, Corda MG, Giorgi O (2009). "The Roman high- and low-avoidance rat lines differ in the acquisition, maintenance, extinction, and reinstatement of intravenous cocaine self-administration". Neuropsychopharmacology 34 (5): 1091–101. doi:10.1038/npp.2008.43. PMID 18418365.
- Nutt, D.; King, L. A.; Saulsbury, W.; Blakemore, C. (2007). "Development of a rational scale to assess the harm of drugs of potential misuse". The Lancet 369 (9566): 1047–1053. doi:10.1016/S0140-6736(07)60464-4. PMID 17382831.
- Sharma, HS; Muresanu, D; Sharma, A; Patnaik, R (2009). "Cocaine-induced breakdown of the blood brain barrier and neurotoxicity". International Review of Neurobiology. International Review of Neurobiology 88: 297–334. doi:10.1016/S0074-7742(09)88011-2. ISBN 978-0-12-374504-0. PMID 19897082.
- Dietrich, JB (2009). "Alteration of blood-brain barrier function by methamphetamine and cocaine". Cell and tissue research 336 (3): 385–392. doi:10.1007/s00441-009-0777-y. PMID 19350275.
- Dopamine reuptake transporter (DAT) ``inverse agonism`` - A novel hypothesis to explain the enigmatic pharmacology of cocaine 2014-12-24 17:08:48 2014-12-25 00:28:27
- GBD 2013 Mortality and Causes of Death, Collaborators (17 December 2014). "Global, regional, and national age-sex specific all-cause and cause-specific mortality for 240 causes of death, 1990-2013: a systematic analysis for the Global Burden of Disease Study 2013.". Lancet. doi:10.1016/S0140-6736(14)61682-2. PMID 25530442.
- Sawada, H. et al. (23 February 2005). "Cocaine and Phenylephrine Eye Drop Test for Parkinson Disease". JAMA the Journal of the American Medical Association (Journal of the American Medical Association) 293 (8): 932–4. doi:10.1001/jama.293.8.932-c. PMID 15728162.
- World Health Organization (2004). Neuroscience of psychoactive substance use and dependence. p. 89. ISBN 9789241562355.
- World Health Organization (2007). International medical guide for ships. p. 242. ISBN 9789241547208.
- "cocaine (Topical route)". drugs.com. Retrieved 14 January 2015.
- Zhao, Wei (2008). Mechanisms Mediating Sex Differences in the Effects of Cocaine. ProQuest. p. 3. ISBN 0-549-99458-0. Retrieved 25 September 2012.
- Hugo D'haenen; Johan A. den Boer; P. Willner, eds. (2002). Biological Psychiatry 2 (2 ed.). Wiley. p. 528. ISBN 978-0-471-49198-9.
- Lowinson, Joyce, H; Ruiz, Pedro. Millman, Robert B. (2004). Substance abuse: a comprehensive textbook (4th ed.). Lippincott Williams & Wilkins. p. 204. ISBN 978-0-7817-3474-5. Retrieved 5 January 2014.
- Baigent, Michael (2003). "Physical complications of substance abuse: what the psychiatrist needs to know". Curr Opin Psychiatry 16 (3): 291–296. doi:10.1097/00001504-200305000-00004.
- Pagliaro, Louis; Ann Marie Pagliaro (2004). Pagliaros’ Comprehensive Guide to Drugs and Substances of Abuse. Washington, D.C.: American Pharmacists Association. ISBN 978-1-58212-066-9.
- "More bad news for cocaine users: Drug can triple risk of aneurysm". Scienceblog.com. 1999. Retrieved 10 July 2007.
- Trozak D, Gould W (1984). "Cocaine abuse and connective tissue disease". J Am Acad Dermatol 10 (3): 525. doi:10.1016/S0190-9622(84)80112-7. PMID 6725666.
- Ramón Peces; Navascués, RA; Baltar, J; Seco, M; Alvarez, J (1999). "Antiglomerular Basement Membrane Antibody-Mediated Glomerulonephritis after Intranasal Cocaine Use". Nephron 81 (4): 434–438. doi:10.1159/000045328. PMID 10095180.
- Moore PM, Richardson B (1998). "Neurology of the vasculitides and connective tissue diseases". J. Neurol. Neurosurg. Psychiatr. 65 (1): 10–22. doi:10.1136/jnnp.65.1.10. PMC 2170162. PMID 9667555.
- Jared A. Jaffe; Kimmel, PL (2006). "Chronic Nephropathies of Cocaine and Heroin Abuse: A Critical Review". Clinical Journal of the American Society of Nephrology (American Society of Nephrology) 1 (4): 655–67. doi:10.2215/CJN.00300106. PMID 17699270.
- Fokko J. van der Woude (2000). "Cocaine use and kidney damage". Nephrology Dialysis Transplantation (Oxford University Press) 15 (3): 299–301. doi:10.1093/ndt/15.3.299. PMID 10692510.
- Susan Jeffrey, Charles Vega (17 April 2008) [16 April 2007]. "Stimulant Abuse May Increase Stroke Among Young Adults". Retrieved 6 February 2011. (registration required (. ))
- Vasica G, Tennant CC (2002). "Cocaine use and cardiovascular complications". Med. J. Aust. 177 (5): 260–2. PMID 12197823.
- Humphrey AJ, O'Hagan D (2001). "Tropane alkaloid biosynthesis. A century old problem unresolved". Nat Prod Rep 18 (5): 494–502. doi:10.1039/b001713m. PMID 11699882.
- Dewick, P. M. (2009). Medicinal Natural Products. Chicester: Wiley-Blackwell. ISBN 978-0-470-74276-1.
- R. J. Robins, T. W. Abraham, A. J. Parr, J. Eagles and N. J. Walton (1997). "The Biosynthesis of Tropane Alkaloids in Datura stramonium: The Identity of the Intermediates between N-Methylpyrrolinium Salt and Tropinone". J. Am. Chem. Soc. 119 (45): 10929. doi:10.1021/ja964461p.
- Hoye TR, Bjorklund JA, Koltun DO, Renner MK (2000). "N-methylputrescine oxidation during cocaine biosynthesis: study of prochiral methylene hydrogen discrimination using the remote isotope method". Org. Lett. 2 (1): 3–5. doi:10.1021/ol990940s. PMID 10814231.
- E. Leete, J. A. Bjorklund, M. M. Couladis and S. H. Kim (1991). "Late intermediates in the biosynthesis of cocaine: 4-(1-methyl-2-pyrrolidinyl)-3-oxobutanoate and methyl ecgonine". J. Am. Chem. Soc. 113 (24): 9286. doi:10.1021/ja00024a039.
- E. Leete, J. A. Bjorklund and S. H. Kim (1988). "The biosynthesis of the benzoyl moiety of cocaine". Phytochemistry 27 (8): 2553. doi:10.1016/0031-9422(88)87026-2.
- Leete E, Marion L, Sspenser ID (1954). "Biogenesis of hyoscyamine". Nature 174 (4431): 650–1. doi:10.1038/174650a0. PMID 13203600.
- Robins RJ, Waltons NJ, Hamill JD, Parr AJ, Rhodes MJ (1991). "Strategies for the genetic manipulation of alkaloid-producing pathways in plants". Planta Med. 57 (7 Suppl): S27–35. doi:10.1055/s-2006-960226. PMID 17226220.
- T. Hemscheidt; Vederas, John C. (2000). Leeper, Finian J.; Vederas, John C., eds. "Tropane and Related Alkaloids". Top. Curr. Chem. Topics in Current Chemistry 209: 175. doi:10.1007/3-540-48146-X. ISBN 978-3-540-66573-1.
- A. Portsteffen, B. Draeger and A. Nahrstedt (1992). "Two tropinone reducing enzymes from Datura stramonium transformed root cultures". Phytochemistry 31 (4): 1135. doi:10.1016/0031-9422(92)80247-C.
- Boswell HD, Dräger B, McLauchlan WR (1999). "Specificities of the enzymes of N-alkyltropane biosynthesis in Brugmansia and Datura". Phytochemistry 52 (5): 871–8. doi:10.1016/S0031-9422(99)00293-9. PMID 10626376.
- Smith, Michael Valentine. "Psychedelic Chemistry: Cocaine". Designer-drugs.com. Archived from the original on 15 February 2006.
- Scheidweiler, K. B.; Plessinger, MA; Shojaie, J; Wood, RW; Kwong, TC (15 October 2003). "Pharmacokinetics and Pharmacodynamics of Methylecgonidine, a Crack Cocaine Pyrolyzate". Journal of Pharmacology and Experimental Therapeutics 307 (3): 1179–87. doi:10.1124/jpet.103.055434. PMID 14561847.
- Yang Y, Ke Q, Cai J, Xiao YF, Morgan JP (2001). "Evidence for cocaine and methylecgonidine stimulation of M2 muscarinic receptors in cultured human embryonic lung cells". Br. J. Pharmacol. 132 (2): 451–60. doi:10.1038/sj.bjp.0703819. PMC 1572570. PMID 11159694.
- Fandiño AS, Toennes SW, Kauert GF (2002). "Studies on hydrolytic and oxidative metabolic pathways of anhydroecgonine methyl ester (methylecgonidine) using microsomal preparations from rat organs". Chem. Res. Toxicol. 15 (12): 1543–8. doi:10.1021/tx0255828. PMID 12482236.
- "Substances – Cocaine". The Steinhardt School of Culture, Education, and Human Development. Retrieved 1 August 2009.
- George, Nelson (1998). Hip Hop America. Viking Penguin. p. 40.
- Ries, Richard K.; Miller, Sharon C.; Fiellin, David A. (2009). Principles of addiction medicine. Lippincott Williams & Wilkins. p. 137. ISBN 0-7817-7477-2. Retrieved 5 January 2014.
- Barnett, G; Hawks, R; Resnick, R (1981). "Cocaine pharmacokinetics in humans". Journal of Ethnopharmacology 3 (2–3): 353–66. doi:10.1016/0378-8741(81)90063-5. PMID 7242115.; Jones, supra note 19; Wilkinson et al., Van Dyke et al.
- Luks, Andrew M. (2010). "Wilderness Medical Society Consensus Guidelines for the Prevention and Treatment of Acute Altitude Illness" 21 (2). Wilderness & Environmental Medicine. pp. 146–155. (mirror: )
- Siegel RK, Elsohly MA, Plowman T, Rury PM, Jones RT (3 January 1986). "Cocaine in herbal tea". Journal of the American Medical Association 255 (1): 40. doi:10.1001/jama.255.1.40. PMID 3940302.
- Nora D. Volkow et al. (2000). "Effects of route of administration on cocaine induced dopamine transporter blockade in the human brain". Life Sciences 67 (12): 1507–1515. doi:10.1016/S0024-3205(00)00731-1. PMID 10983846.
- cesar.umd.edu "Cocaine terminology".
- Bonkovsky HL, Mehta S (2001). "Hepatitis C: a review and update". J. Am. Acad. Dermatol. 44 (2): 159–82. doi:10.1067/mjd.2001.109311. PMID 11174373.
- Dimitrijevic N, Dzitoyeva S, Manev H (2004). "An automated assay of the behavioral effects of cocaine injections in adult Drosophila". J Neurosci Methods 137 (2): 181–184. doi:10.1016/j.jneumeth.2004.02.023. PMID 15262059.
- "Appendix B: Production of Cocaine Hydrochloride and Cocaine Base". US Justice Dep.
- Margaret Reist (16 January 2005). "A rose by another name: crack pipe". Lincoln Journal Star. Retrieved 21 August 2009.
- Rothman, Richard B. et al. (2001). "Amphetamine-Type Central Nervous System Stimulants Release Norepinepehrine more Potently than they Release Dopamine and Serotonin". Synapse 39 (1): 32–41. doi:10.1002/1098-2396(20010101)39:1<32::AID-SYN5>3.0.CO;2-3. PMID 11071707. (Table V. on page 37)
- Spanagel R, Weiss F (1999). "The dopamine hypothesis of reward: past and current status". Trends Neurosci. 22 (11): 521–7. doi:10.1016/S0166-2236(99)01447-2. PMID 10529820.
- Carta M, Allan AM, Partridge LD, Valenzuela CF (2003). "Cocaine inhibits 5-HT3 receptor function in neurons from transgenic mice overexpressing the receptor". Eur. J. Pharmacol. 459 (2–3): 167–9. doi:10.1016/S0014-2999(02)02867-4. PMID 12524142.
- Filip M, Bubar MJ, Cunningham KA (2004). "Contribution of serotonin (5-hydroxytryptamine; 5-HT) 5-HT2 receptor subtypes to the hyperlocomotor effects of cocaine: acute and chronic pharmacological analyses". J. Pharmacol. Exp. Ther. 310 (3): 1246–54. doi:10.1124/jpet.104.068841. PMID 15131246.
- Beuming, Thijs et al. (2008). "The binding sites for cocaine and dopamine in the dopamine transporter overlap". Nature Neuroscience 11 (7): 780–9. doi:10.1038/nn.2146. PMC 2692229. PMID 18568020.
- "Sigma Receptors Play Role In Cocaine-induced Suppression Of Immune System". Sciencedaily.com. 6 May 2003. Retrieved 9 March 2010.
- Lluch J, Rodríguez-Arias M, Aguilar MA, Miñarro J (2005). "Role of dopamine and glutamate receptors in cocaine-induced social effects in isolated and grouped male OF1 mice". Pharmacol. Biochem. Behav. 82 (3): 478–87. doi:10.1016/j.pbb.2005.10.003. PMID 16313950.
- "Drugbank website "drug card", "(DB00907)" for Cocaine: Giving ten targets of the molecule in vivo, including dopamine/serotonin sodium channel affinity & K-opioid affinity". Drugbank.ca. Retrieved 9 March 2010.
- Uz T, Akhisaroglu M, Ahmed R, Manev H (2003). "The pineal gland is critical for circadian Period 1 expression in the striatum and for circadian cocaine sensitization in mice". Neuropsychopharmacology 28 (12): 2117–2123. doi:10.1038/sj.npp.1300254. PMID 12865893.
- McClung C, Sidiropoulou K, Vitaterna M, Takahashi J, White F, Cooper D, Nestler E (2005). "Regulation of dopaminergic transmission and cocaine reward by the Clock gene". Proc Natl Acad Sci USA 102 (26): 9377–81. doi:10.1073/pnas.0503584102. PMC 1166621. PMID 15967985.
- Carey RJ, Damianopoulos EN, Shanahan AB (2008). "Cocaine effects on behavioral responding to a novel object placed in a familiar environment". Pharmacol. Biochem. Behav. 88 (3): 265–71. doi:10.1016/j.pbb.2007.08.010. PMID 17897705.
- Kolbrich EA, Barnes AJ, Gorelick DA, Boyd SJ, Cone EJ, Huestis MA (2006). "Major and minor metabolites of cocaine in human plasma following controlled subcutaneous cocaine administration". J Anal Toxicol 30 (8): 501–10. doi:10.1093/jat/30.8.501. PMID 17132243.
- Wilson LD, Jeromin J, Garvey L, Dorbandt A (2001). "Cocaine, ethanol, and cocaethylene cardiotoxity in an animal model of cocaine and ethanol abuse". Acad Emerg Med 8 (3): 211–22. doi:10.1111/j.1553-2712.2001.tb01296.x. PMID 11229942.
- Pan WJ, Hedaya MA (1999). "Cocaine and alcohol interactions in the rat: effect of cocaine and alcohol pretreatments on cocaine pharmacokinetics and pharmacodynamics". J Pharm Sci 88 (12): 1266–74. doi:10.1021/js990184j. PMID 10585221.
- Hayase T, Yamamoto Y, Yamamoto K (1999). "Role of cocaethylene in toxic symptoms due to repeated subcutaneous cocaine administration modified by oral doses of ethanol". J Toxicol Sci 24 (3): 227–35. doi:10.2131/jts.24.3_227. PMID 10478337.
- Barley, Shanta (13 November 2009). "Cocaine and pepper spray – a lethal mix?". New Scientist. Retrieved 14 November 2009.
- Mendelson, John E.; Tolliver, Bryan K.; Delucchi, Kevin L.; Baggott, Matthew J.; Flower, Keith; Harris, C. Wilson; Galloway, Gantt P.; Berger, Paul (2 October 2009). "Capsaicin, an active ingredient in pepper sprays, increases the lethality of cocaine". Forensic Toxicology 28: 33. doi:10.1007/s11419-009-0079-9. ISSN 1860-8973.
- R. Baselt, Disposition of Toxic Drugs and Chemicals in Man, 9th edition, Biomedical Publications, Seal Beach, CA, 2011, pp. 390–394.
- Venkatratnam, Abhishek; Nathan H. Lents (July 2011). "Zinc Reduces the Detection of Cocaine, Methamphetamine, and THC by ELISA Urine Testing". Journal of Analytical Toxicology 35 (6): 333–340. doi:10.1093/anatox/35.6.333. PMID 21740689.
- World Drug Report 2007 (PDF). New York: United Nations. 2007. p. 243. Retrieved 31 December 2013.
- The State of the Drugs Problem in Europe 2008 (PDF). Luxembourg: European Monitoring Centre for Drugs and Drug Addiction. 2008. pp. 58–62. Retrieved 31 December 2013.
- "Cocaine & Crack". Erowid.org. Archived from the original on 6 October 2007. Retrieved 10 July 2007.
- "Field Listing – Illicit drugs (by country)". Cia.gov. Retrieved 15 January 2011.
- http://connect.mcgraw-hill.com/connect/hmEBook.do?setTab=sectionTabs Johnson et al., 2012. Hoeksema, Susan Nolen. "Sign In." McGraw-Hill Connect. N.p., n.d. Web. 16 Apr. 2014.
- Altman AJ, Albert DM, Fournier GA (1985). "Cocaine's use in ophthalmology: our 100-year heritage". Surv Ophthalmol 29 (4): 300–6. doi:10.1016/0039-6257(85)90153-5. PMID 3885453.
- Gay GR, Inaba DS, Sheppard CW, Newmeyer JA (1975). "Cocaine: history, epidemiology, human pharmacology, and treatment. a perspective on a new debut for an old girl". Clin. Toxicol. 8 (2): 149–78. doi:10.3109/15563657508988061. PMID 1097168.
- "Drug that spans the ages: The history of cocaine". London: The Independent (UK). 2006. Retrieved 30 April 2010.
- Monardes, Nicholas; Translated into English by J. Frampton (1925). Joyfull Newes out of the Newe Founde Worlde. New York, NY: Alfred Knopf.
- Gaedcke, F. (1855). "Ueber das Erythroxylin, dargestellt aus den Blättern des in Südamerika cultivirten Strauches Erythroxylon Coca". Archiv der Pharmazie 132 (2): 141–150. doi:10.1002/ardp.18551320208.
- Albert Niemann (1860). "Ueber eine neue organische Base in den Cocablättern". Archiv der Pharmazie 153 (2): 129–256. doi:10.1002/ardp.18601530202.
- Harper, Douglas. "Cocaine". Online Etymology Dictionary.
- Yentis SM, Vlassakov KV (1999). "Vassily von Anrep, forgotten pioneer of regional anesthesia". Anesthesiology 90 (3): 890–5. doi:10.1097/00000542-199903000-00033. PMID 10078692.
- Halsted W (1885). "Practical comments on the use and abuse of cocaine". New York Medical Journal 42: 294–295.
- Corning JL (1885). "An experimental study". New York Medical Journal 42: 483.
- "Experience Vin Mariani today | Grupo Mariani S.A". Cocanaturally.com. Retrieved 15 January 2011.
- Barlow, William. "Looking Up At Down": The Emergence of Blues Culture. Temple University Press (1989), p. 207. ISBN 978-0-87722-583-6.
- Streatfeild, Dominic (2003). Cocaine: An Unauthorized Biography. Picador. ISBN 978-0-312-42226-4.
- "Jeevan Vasagar: cocaine-based "wonder drug" tested on concentration camp inmates". Amphetamines.com. 19 November 2002. Retrieved 15 January 2011.
- (Madge 2001, p. 106)
- Spillane, p. 121
- Spillane, p. 91
- (Madge 2001, p. 84)
- Spillane, pp. 92–93
- Spillane, p. 93
- (Gootenberg 1999, p. 33)
- (Madge 2001, p. 102)
- Spillane, p. 94
- (Madge 2001, p. 85)
- (Madge 2001, p. 89)
- (Madge 2001, p. 88)
- Spillane, p. 120
- (Madge 2001, p. 90)
- (Madge 2001, p. 91)
- Spillane, p. 119
- Spillane, p. 111
- (Gootenberg 1999, p. 35)
- (Madge 2001, p. 82)
- (Gootenberg 1999, p. 37)
- (Madge 2001, p. 107)
- (Gootenberg 1999, p. 40)
- "Apple Sanity – Fetish – Blow: War on Drugs VS. Cocaine". Applesanity.com. 17 June 2008. Archived from the original on 17 June 2008. Retrieved 13 November 2011.
- "Cocaine Market". Havocscope.com. Archived from the original on 11 November 2012. Retrieved 9 March 2010.
- WHO/UNICRI (1995). "WHO Cocaine Project". Retrieved 8 June 2012.
- "Cocaine use doubles in a decade". Sydney Morning Herald. 15 October 2010. Retrieved 19 October 2010.
- EMCDDA (2007). "EMCDDA Retail Cocaine Purity Study". Retrieved 31 December 2013.
- "Cocaine: Seizures, 1998–2003". World Drug Report 2006 (PDF) 2. New York: United Nations. 2006.
- Colombia. CIA World Factbook
- Peru Overtakes Colombia as Top Cocaine Producer. NBC News (31 July 2012)
- Streatfeild, Dominic (2003). Cocaine: An Unauthorized Biography. Macmillan. ISBN 978-0-312-42226-4. Retrieved 5 January 2014.
- NDIC (2006). "National Drug Threat Assessment 2006".
- "Cocaine Seized Worldwide Highest Ever in 2011". Flare Network (Flarenetwork.org). 18 January 2012. Retrieved 5 January 2014.
- "Colombia". State.gov. Retrieved 26 March 2013.
- Jacobson, Robert (2005) Illegal Drugs: America's Anguish. Farmington Hills, MI: Thomson Gale, ISBN 1-4144-0419-0.
- "Coast Guard hunts drug-running semi-subs". CNN. 20 March 2008. Retrieved 20 March 2008.
- "Meth Info". Methproject.org. Archived from the original on 27 March 2010.
- "Drugs of Abuse". City of Denison Iowa. Retrieved 13 November 2011.
- "Drugs: Pricing Power". The Economist. 28 June 2007.
Prices: USA around $110/g, Israel/ Germany/ Britain around $46/g, Colombia $2/g, New Zealand recordbreaking $714.30/g.
- European Monitoring Centre for Drugs and Drug Addiction (2008). Annual report: the state of the drugs problem in Europe. Luxembourg: Office for Official Publications of the European Communities. p. 59. ISBN 978-92-9168-324-6. Retrieved 31 December 2013.
- The Cocaine Threat: A Hemispheric Perspective (PDF). United States Department of Defense. Archived from the original on 11 September 2008.
- United Nations (June 2010). World Drug Report 2010. United Nations Publications. p. 77. ISBN 978-92-1-148256-0.
- Gootenberg, Paul, ed. (1999). Cocaine: Global Histories. London: Routledge. ISBN 0-203-02646-2.
- Madge, Tim (2001). White Mischief: A Cultural History of Cocaine. Madge (Edinburgh: Mainstream Publishing Company). ISBN 978-1-84018-405-1.
- Spillane, Joseph F. (2000). Cocaine: From Medical Marvel to Modern Menace in the United States, 1884–1920. Baltimore and London: The Johns Hopkins University Press. ISBN 0-8018-6230-2.
- Feiling, Tom (2009). The Candy Machine: How Cocaine Took Over the World. London: Penguin. ISBN 978-0-14-103446-1.
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