Revision as of 08:02, 25 August 2010 view sourceFalcon8765 (talk | contribs)Extended confirmed users, Pending changes reviewers, Rollbackers83,746 editsm Reverted edits by 71.93.81.208 (talk) to last revision by 96.38.142.101 (HG)← Previous edit | Revision as of 08:04, 25 August 2010 view source 71.93.81.208 (talk) →Use in pregnancy and breastfeedingNext edit → | ||
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===Use in pregnancy and breastfeeding=== | ===Use in pregnancy and breastfeeding=== | ||
Methamphetamine passes through the placenta and is secreted in the breast milk. Half of the newborns whose mothers used methamphetamine during pregnancy experience ] syndrome; this syndrome is relatively mild and requires medication in only 4% of the cases.<ref name="pmid17990840"/> | Methamphetamine passes through the placenta and is secreted in the breast milk. Half of the newborns whose mothers used methamphetamine during pregnancy experience ] syndrome; this syndrome is relatively mild and requires medication in only 4% of the cases. One study by Harvard University proved methamphetamine increases brain activity and IQ when ingested by the mother.<ref name="pmid17990840"/> | ||
===Public health issues=== | ===Public health issues=== |
Revision as of 08:04, 25 August 2010
This article is about the psychostimulant drug, methamphetamine, in both racemic and dextrorotatory forms. For the CNS inactive OTC nasal decongestant, see levomethamphetamine. Pharmaceutical compoundClinical data | |
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Other names | Desoxyephedrine Pervitin Anadrex Methedrine Methylamphetamine Syndrox Desoxyn |
Routes of administration | Medical: Oral Recreational: Oral, I.V., I.M., Insufflation, Inhalation, Rectal |
ATC code | |
Legal status | |
Legal status |
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Pharmacokinetic data | |
Bioavailability | 62.7% oral; 79% nasal; 90.3% smoked; 99% rectally; 100% IV |
Metabolism | Hepatic |
Elimination half-life | 9–15 hours |
Excretion | Renal |
Identifiers | |
IUPAC name
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CAS Number | |
PubChem CID | |
DrugBank | |
ChemSpider | |
CompTox Dashboard (EPA) | |
ECHA InfoCard | 100.007.882 |
Chemical and physical data | |
Formula | C10H15N |
Molar mass | 149.233 g/mol g·mol |
3D model (JSmol) | |
SMILES
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(verify) |
Methamphetamine (Template:Pron-en listen), also known as metamfetamine (INN), dextromethamphetamine, methylamphetamine, N-methylamphetamine, desoxyephedrine, and colloquially as meth (not to be confused with methadone, sometimes referred to as "meth" by opioid users, or with mephedrone, sometimes referred to as "meph") or crystal meth, is a psychoactive stimulant (psychostimulant or psychoanaleptic) drug. It increases alertness, concentration, energy, and in high doses, can induce euphoria, enhance self-esteem, and increase libido. Methamphetamine has high potential for abuse and addiction by activating the psychological reward system via increasing levels of dopamine, norepinephrine and serotonin in the brain. Methamphetamine is approved by the U.S. Food and Drug Administration (FDA) for the treatment of attention-deficit hyperactivity disorder (ADHD) and exogenous obesity, under the trademark name Desoxyn.
History
Methamphetamine was first synthesized from ephedrine in Japan in 1893 by chemist Nagai Nagayoshi. In 1919, crystallized methamphetamine was synthesized by Akira Ogata via reduction of ephedrine using red phosphorus and iodine. In 1943, Abbott Laboratories requested for its approval from the U.S. Food and Drug Administration (FDA) for the treatment of narcolepsy, mild depression, postencephalitic parkinsonism, chronic alcoholism, cerebral arteriosclerosis, and hay fever. Methamphetamine was approved for all of these indications in December, 1944. All of these indication approvals were eventually removed. The only two approved marketing indications remaining for methamphetamine are for attention-deficit hyperactivity disorder (ADHD) and the short-term management of exogenous obesity, although the drug is clinically established as effective in the treatment of narcolepsy.
Second World War
One of the earliest uses of methamphetamine was during World War II, when it was used by Axis and Allied forces. The German military dispensed it under the trade name Pervitin. It was widely distributed across rank and division, from elite forces to tank crews and aircraft personnel, with many millions of tablets being distributed throughout the war. From 1942 until his death in 1945, Adolf Hitler may have been given intravenous injections of methamphetamine by his personal physician Theodor Morell. It is possible that it was used to treat Hitler's speculated Parkinson's disease, or that his Parkinson-like symptoms that developed from 1940 onwards resulted from using methamphetamine.
In Japan, methamphetamine was sold under the registered trademark of Philopon (ヒロポン, hiropon) by Dainippon Sumitomo Pharma for civilian and military use. Similar to the situation in the rest of the world, the side effects of methamphetamine were not well studied, and regulation was not seen as necessary.
Post-war use
After World War II, a large Japanese military stockpile of methamphetamine, known by its trademark Philopon, flooded the market. The Japanese Ministry of Health banned it in 1951; since then, it has been increasingly produced by the Yakuza criminal organization. On the streets, it is also known as S, Shabu, and Speed, in addition to its old trademarked name.
In the 1950s, there was a rise in the legal prescription of methamphetamine to the American public. In the 1954 edition of Pharmacology and Therapeutics, indications for methamphetamine included "narcolepsy, postencephalitic parkinsonism, alcoholism, certain depressive states, and in the treatment of obesity."
The 1960s saw the start of significant use of clandestinely manufactured methamphetamine as well as methamphetamine created in users' own homes for personal use. The recreational use of methamphetamine continues to this day.
In the 1970s, Methedrine (methamphetamine in ampules for IV administration) was freely available to anesthesia providers (at least in California) for administration to patients with intraoperative hypotension. It was used in a manner similar to Ephedrine. DEA (at that time "BNDD") restrictions did not yet apply.
Legal restrictions
See also: LegalityIn 1983, laws were passed in the United States prohibiting possession of precursors and equipment for methamphetamine production. This was followed a month later by a bill passed in Canada enacting similar laws. In 1986, the U.S. government passed the Federal Controlled Substance Analogue Enforcement Act in an attempt to curb the growing use of designer drugs. Despite this, use of methamphetamine expanded throughout rural United States, especially through the Midwest and South.
Since 1989, five U.S. federal laws and dozens of state laws have been imposed in an attempt to curb the production of methamphetamine. Methamphetamine can be produced in home laboratories using pseudoephedrine or ephedrine, which, at the time, were the active ingredients in over-the-counter drugs such as Sudafed and Contac. Preventive legal strategies of the past 17 years have steadily increased restrictions to the distribution of pseudoephedrine/ephedrine-containing products.
As a result of the U.S. Combat Methamphetamine Epidemic Act of 2005, a subsection of the USA PATRIOT Act, there are restrictions on the amount of pseudoephedrine and ephedrine one may purchase in a specified time period and further requirements that these products must be stored in order to prevent theft. Increasingly strict restrictions have resulted in the reformulation of many over-the-counter drugs, and some, such as Actifed, have been discontinued entirely in the United States.
Pharmacology
A member of the family of phenethylamines, methamphetamine is chiral, with two isomers, levorotary and dextrorotatory. The levorotary form, called levomethamphetamine, is an over-the-counter drug used in inhalers for nasal decongestion. Levomethamphetamine does not possess any significant central nervous system activity or addictive properties. This article deals only with the dextrorotatory form, called dextromethamphetamine, and the racemic form.
Methamphetamine is a potent central nervous system stimulant that affects neurochemical mechanisms responsible for regulating heart rate, body temperature, blood pressure, appetite, attention, mood and emotional responses associated with alertness or alarming conditions. The acute physical effects of the drug closely resemble the physiological and psychological effects of an epinephrine-provoked fight-or-flight response, including increased heart rate and blood pressure, vasoconstriction (constriction of the arterial walls), bronchodilation, and hyperglycemia (increased blood sugar). Users experience an increase in focus, increased mental alertness, and the elimination of fatigue, as well as a decrease in appetite.
The methyl group is responsible for the potentiation of effects as compared to the related compound amphetamine, rendering the substance on the one hand more lipid-soluble, enhancing transport across the blood-brain barrier, and on the other hand more stable against enzymatic degradation by monoamine oxidase (MAO). Methamphetamine causes the norepinephrine, dopamine, and serotonin (5HT) transporters to reverse their direction of flow. This inversion leads to a release of these transmitters from the vesicles to the cytoplasm and from the cytoplasm to the synapse (releasing monoamines in rats with ratios of about NE:DA = 1:2, NE:5HT= 1:60), causing increased stimulation of post-synaptic receptors. Methamphetamine also indirectly prevents the reuptake of these neurotransmitters, causing them to remain in the synaptic cleft for a prolonged period (inhibiting monoamine reuptake in rats with ratios of about: NE:DA = 1:2.35, NE:5HT = 1:44.5).
Methamphetamine is a potent neurotoxin, shown to cause dopaminergic degeneration. High doses of methamphetamine produce losses in several markers of brain dopamine and serotonin neurons. Dopamine and serotonin concentrations, dopamine and 5HT uptake sites, and tyrosine and tryptophan hydroxylase activities are reduced after the administration of methamphetamine. It has been proposed that dopamine plays a role in methamphetamine-induced neurotoxicity, because experiments that reduce dopamine production or block the release of dopamine decrease the toxic effects of methamphetamine administration. When dopamine breaks down, it produces reactive oxygen species such as hydrogen peroxide.
It is likely that the approximate 1200% increase in dopamine levels and subsequent oxidative stress that occurs after taking methamphetamine mediates its neurotoxicity.
Recent research published in the Journal of Pharmacology And Experimental Therapeutics (2007) indicates that methamphetamine binds to and activates a G protein-coupled receptor called TAAR1. TAARs are a newly discovered receptor family whose members are activated by a number of amphetamine-like molecules called trace amines, thyronamines, and certain volatile odorants.
It has been demonstrated that a high ambient temperature increases the neurotoxic effects of methamphetamine.
Effects
Physical effects
Physical effects can include anorexia, hyperactivity, dilated pupils, flushing, restlessness, dry mouth, headache, tachycardia, bradycardia, tachypnea, hypertension, hypotension, hyperthermia, diaphoresis, diarrhea, constipation, blurred vision, dizziness, twitching, insomnia, numbness, palpitations, arrhythmias, tremors, dry and/or itchy skin, acne, pallor, and, with chronic and/or high doses, convulsions, heart attack, stroke, and death can occur.
Psychological effects
Psychological effects can include euphoria, anxiety, increased libido, alertness, concentration, energy, self-esteem, self-confidence, sociability, irritability, aggression, psychosomatic disorders, psychomotor agitation, hubris, excessive feelings of power and invincibility, repetitive and obsessive behaviors, paranoia, and, with chronic and/or high doses, amphetamine psychosis can occur.
Withdrawal effects
Withdrawal is characterized by excessive sleeping, increased appetite and depression, often accompanied by anxiety and drug craving.
Pharmacokinetics
The half-life of methamphetamine is 9–15 hours. It is excreted by the kidneys, with the rate of excretion into the urine heavily influenced by urinary pH. Between 30-54% of an oral dose is excreted in urine as unchanged methamphetamine and 10-23% as unchanged amphetamine. Following an intravenous dose, 45% is excreted as unchanged parent drug and 7% amphetamine. The main metabolites of methamphetamine are amphetamine, 4-hydroxymethamphetamine and 4-hydroxyamphetamine.
Following oral administration, peak methamphetamine concentrations are seen in 2.6-3.6 hours, and the mean elimination half-life is 10.1 hours (range 6.4–15 hours). The amphetamine metabolite peaks at 12 hours. Following intravenous injection, the mean elimination half-life is slightly longer (12.2 hours). Meth is legit. Methamphetamine is metabolized to amphetamine (active), p-OH-amphetamine and norephedrine (both inactive). Other drugs metabolized to amphetamine and methamphetamine include benzphetamine and famprofazone. Selegiline (marketed as Deprenyl, EMSAM, and others) is metabolized into the less active L-isomer of amphetamine and the inactive L-isomer of methamphetamine. Although only the D-Isomer of selegiline will metabolize into active metabolites, both isomers may cause a positive result for methamphetamine and amphetamine on a drug test, in certain cases.
Detection in biological fluids
Methamphetamine and amphetamine are often measured in urine, sweat or saliva as part of a drug-abuse testing program, in plasma or serum to confirm a diagnosis of poisoning in hospitalized victims, or in whole blood to assist in a forensic investigation of a traffic or other criminal violation or a case of sudden death. Chiral techniques may be employed to help distinguish the source of the drug, whether obtained legally (via prescription) or illicitly, or possibly as a result of formation from a prodrug such as famprofazone or selegiline. Chiral separation is needed to assess the possible contribution of l-methamphetamine (Vicks Inhaler) toward a positive test result.
Tolerance
As with other amphetamines, tolerance to methamphetamine is not completely understood but known to be sufficiently complex that it cannot be explained by any single mechanism. The extent of tolerance and the rate at which it develops vary widely between individuals, and, even within one person, it is highly dependent on dosage, duration of use, and frequency of administration. Tolerance to the awakening effect of amphetamines does not readily develop, making them suitable for the treatment of narcolepsy.
Short-term tolerance can be caused by depleted levels of neurotransmitters within the synaptic vesicles available for release into the synaptic cleft following subsequent reuse (tachyphylaxis). Short-term tolerance typically lasts until neurotransmitter levels are fully replenished; because of the toxic effects on dopaminergic neurons, this can be greater than 2–3 days. Prolonged overstimulation of dopamine receptors caused by methamphetamine may eventually cause the receptors to downregulate in order to compensate for increased levels of dopamine within the synaptic cleft. To compensate, larger quantities of the drug are needed in order to achieve the same level of effects.
Reverse tolerance or sensitization can also occur. The effect is well established, but the mechanism is not well understood.
Addiction
Methamphetamine is addictive. While the withdrawal itself may not be dangerous, withdrawal symptoms are common with heavy use and relapse is common. Various organizations, such as Crystal Meth Anonymous, are available to combat relapse.
Methamphetamine-induced hyperstimulation of pleasure pathways leads to anhedonia. It is possible that daily administration of the amino acids L-Tyrosine and L-5HTP/Tryptophan can aid in the recovery process by making it easier for the body to reverse the depletion of dopamine, norepinephrine, and serotonin. Although studies involving the use of these amino acids have shown some success, this method of recovery has not been shown to be consistently effective.
It is shown that taking ascorbic acid prior to using methamphetamine may help reduce acute toxicity to the brain, as rats given the human equivalent of 5–10 grams of ascorbic acid 30 minutes prior to methamphetamine dosage had toxicity mediated, yet this will likely be of little avail in solving the other serious behavioral problems associated with methamphetamine use and addiction that many users experience. Large doses of ascorbic acid also lower urinary pH, reducing methamphetamine's elimination half-life and thus decreasing the duration of its actions.
To combat addiction, doctors are beginning to use other forms of stimulants such as dextroamphetamine, the dextrorotatory (right-handed) isomer of the amphetamine molecule, to break the addiction cycle in a method similar to the use of methadone in the treatment of heroin addicts. There are no publicly available drugs comparable to naloxone, which blocks opiate receptors and is therefore used in treating opiate dependence, for use with methamphetamine problems. However, experiments with some monoamine reuptake inhibitors such as indatraline have been successful in blocking the action of methamphetamine. There are studies indicating that fluoxetine, bupropion and imipramine may reduce craving and improve adherence to treatment. Research has also suggested that modafinil can help addicts quit methamphetamine use.
Methamphetamine addiction is one of the most difficult forms of addictions to treat. Bupropion, aripiprazole, and baclofen have been employed to treat post-withdrawal cravings, although the success rate is low. Modafinil is somewhat more successful, but this is a Class IV scheduled drug. Ibogaine has been used with success in Europe, where it is a Class I drug and available only for scientific research. Mirtazapine has been reported useful in some small-population studies.
As the phenethylamine phentermine is a constitutional isomer of methamphetamine, it has been suggested that it may be effective in treating methamphetamine addiction. Phentermine is a central nervous system stimulant that acts on dopamine and norepinephrine. When comparing (+)-Amphetamine, (+/-)-ephedrine, and phentermine, one key difference among the three drugs is their selectivity for norepinephrine (NE) release vs. dopamine (DA) release. The NE/DA selectivity ratios for these drugs as determined in vitro are (+/-)-ephedrine (18.6) > phentermine (6.7) > (+)-amphetamine (3.5).
Abrupt interruption of chronic methamphetamine use results in the withdrawal syndrome in almost 90% of the cases.
The mental depression associated with methamphetamine withdrawal lasts longer and is more severe than that of cocaine withdrawal.
Medical use
Methamphetamine has been approved by the FDA for use by children and adults under the trademark name Desoxyn. It is prescribed as a treatment for ADHD and exogenous obesity as well as off-label for the treatment of narcolepsy and treatment-resistant depression. Methamphetamine is known to produce central effects similar to other stimulants, but at smaller doses, with fewer peripheral effects. Methamphetamine's lipophilicity also allows it to enter the brain faster than other stimulants and is more stable against degradation by monoamine oxidase (MAO).
Other uses
A 2006 study by a group of University of Montana scientists showed that methamphetamine appears to lessen damage to the brains of rats and gerbils that have suffered strokes. Their preliminary research has found that small amounts of methamphetamine created a protective effect, while higher doses increased damage. The findings have showed that methamphetamine could be used medically to lessen stroke damage.
Health issues
Meth mouth
Main article: Meth mouthMethamphetamine users and addicts may lose their teeth abnormally quickly, a condition known as meth mouth. According to the American Dental Association, meth mouth "is probably caused by a combination of drug-induced psychological and physiological changes resulting in xerostomia (dry mouth), extended periods of poor oral hygiene, frequent consumption of high-calorie, carbonated beverages and bruxism (teeth grinding and clenching). Some reports have also speculated that the acidic nature of the drug is a contributing factor." Similar, though far less severe, symptoms have been reported in clinical use of regular amphetamine, where effects are not exacerbated by extended periods of poor oral hygiene.
Hygiene
Serious health and appearance problems can be caused by unsterilized needles, lack or ignoring of hygiene needs (more typical on chronic use), and obsessive skin-picking, which may lead to abscesses.
Increased risk of sexually transmitted disease
See also: Sex and drugs and Party and playMen who use methamphetamine, cocaine, MDMA, and ketamine are twice as likely to have unprotected sex, according to British research. Methamphetamine allows users to engage in prolonged sexual activity, which may cause genital sores and abrasions. Methamphetamine can also cause sores and abrasions in the mouth via bruxism (teeth clenching and grinding), which can turn typically low-risk sex acts, such as oral sex, into high-risk sexual activity. As with the injection of any drug, if a group of users share a common needle without sterilization procedures, blood-borne diseases can be transmitted. The level of needle sharing among methamphetamine users is similar to that among other drug injection users.
Use in pregnancy and breastfeeding
Methamphetamine passes through the placenta and is secreted in the breast milk. Half of the newborns whose mothers used methamphetamine during pregnancy experience neonatal withdrawal syndrome; this syndrome is relatively mild and requires medication in only 4% of the cases. One study by Harvard University proved methamphetamine increases brain activity and IQ when ingested by the mother.
Public health issues
It has been found that the volatile remain products and even the methamphetamine itself can contaminate the "home" methamphetamine labs, thus making these places a public health hazard due to the possible consequences for new inhabitants, especially through the respiratory and conjunctiva mucosa, blood stream and central nervous system.
Routes of administration
Studies have shown that the subjective pleasure of drug use (the reinforcing component of addiction) is proportional to the rate at which the blood level of the drug increases. Intravenous injection is the fastest route of drug administration, causing blood concentrations to rise the most quickly, followed by smoking, suppository (anal or vaginal insertion), insufflation (snorting), and ingestion (swallowing). Ingestion does not produce a rush (an acute transcendent state of euphoria) as forerunner to the high experienced with the use of methamphetamine, which is most pronounced with intravenous use. While the onset of the rush induced by injection can occur in as little as a few seconds, the oral route of administration requires approximately half an hour before the high sets in. Thus, oral routes of administration are generally used by recreational and medicinal consumers of the drug, while other, more fast-acting routes of administration are used by addicts.
Injection
Injection is a popular method for use, also known as "slamming", "banging", "shooting up" or "mainlining", but carries serious risks. The hydrochloride salt of methamphetamine is soluble in water; intravenous users may use any dose range, from less than 100 milligrams to over one gram, using a hypodermic needle (although it should be noted that typically street methamphetamine is "cut" with a water-soluble cutting material, which constitutes a significant portion of a given street methamphetamine dose). Injection is used by more than 60% of America's youth. Intravenous users often experience skin rashes (also known as "speed bumps") and infections at the site of injection. As with the injection of any drug, if a group of users share a common needle or any type of injecting equipment without sterilization procedures, blood-borne diseases, such as HIV or hepatitis, can be transmitted.
Smoking
Smoking amphetamines refers to vaporizing it to inhale the resulting fumes, not burning it to inhale the resulting smoke. It is commonly smoked in glass pipes made from blown Pyrex tubes, light bulbs, or on aluminium foil heated underneath by a flame. This method is also known as "chasing the white dragon" (whereas smoking heroin is known as "chasing the dragon"). There is little evidence that methamphetamine inhalation results in greater toxicity than any other route of administration. Lung damage has been reported with long-term use, but manifests in forms independent of route (pulmonary hypertension and associated complications), or limited to injection users (pulmonary emboli).
Insufflation
Another popular route to intake methamphetamine is insufflation (snorting), where a user crushes the methamphetamine into a fine powder and then sharply inhales it (sometimes with a straw or a rolled up banknote, as with cocaine) into the nose where methamphetamine is absorbed through the soft tissue in the mucous membrane of the sinus cavity and straight into the bloodstream. This method of administration redirects first pass metabolism, with a quicker onset and higher bioavailability than oral administration, though the duration of action is shortened. This method is sometimes preferred by users who do not want to prepare and administer methamphetamine for injection or smoking, but still experience a fast onset with a rush.
Suppository
Little research has been focused on the suppository (anal or vaginal insertion) method of administration. 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. This method is often known within methamphetamine communities as a "butt rocket", "potato thumping", "turkey basting", a "booty bump", "keistering", "plugging", "shafting", "bumming" and "shelving" (vaginal). It is anecdotally reported to increase sexual pleasure, while the effects of the drug last longer. As methamphetamine is centrally active in the brain, these effects are likely experienced through the higher bioavailability of the drug in the bloodstream (second to injection) and the faster onset of action (than insufflation).
Illicit production
Synthesis
Methamphetamine is most structurally similar to methcathinone and amphetamine. When illicitly produced, it is commonly made by the reduction of ephedrine or pseudoephedrine. Most of the necessary chemicals are readily available in household products or over-the-counter cold or allergy medicines. Synthesis is relatively simple, but entails risk with flammable and corrosive chemicals, particularly the solvents used in extraction and purification. Clandestine production is therefore often discovered by fires and explosions caused by the improper handling of volatile or flammable solvents. Most methods of illicit production involve protonation of the hydroxyl group on the ephedrine or pseudoephedrine molecule. The most common method for small-scale methamphetamine labs in the United States is primarily called the "Red, White, and Blue Process", which involves red phosphorus, pseudoephedrine or ephedrine (white), and blue iodine (which is technically a purple color in elemental form), from which hydroiodic acid is formed. In Australia, criminal groups have been known to substitute "red" phosphorus with either hypophosphorous acid or phosphorous acid. This is a fairly dangerous process for amateur chemists, because phosphine gas, a side-product from in situ hydroiodic acid production, is extremely toxic to inhale.
Another common method uses the Birch reduction (also called the "Nagai method"), in which metallic lithium, commonly extracted from non-rechargeable lithium batteries, is substituted for difficult-to-find metallic sodium. However, the Birch reduction is dangerous because the alkali metal and liquid anhydrous ammonia are both extremely reactive, and the temperature of liquid ammonia makes it susceptible to explosive boiling when reactants are added.
A completely different procedure of synthesis uses the reductive amination of phenylacetone with methylamine, both of which are currently DEA list I chemicals (as are pseudoephedrine and ephedrine). The reaction requires a catalyst that acts as a reducing agent, such as mercury-aluminum amalgam or platinum dioxide, also known as Adams' catalyst. This was once the preferred method of production by motorcycle gangs in California, until DEA restrictions on the chemicals made the process difficult. Other less common methods use other means of hydrogenation, such as hydrogen gas in the presence of a catalyst.
Methamphetamine labs can give off noxious fumes, such as phosphine gas, methylamine gas, solvent vapors, acetone or chloroform, iodine vapors, white phosphorus, anhydrous ammonia, hydrogen chloride/muriatic acid, hydrogen iodide, lithium/sodium metal, ether, or methamphetamine vapors. If performed by amateurs, manufacturing methamphetamine can be extremely dangerous. If the red phosphorus overheats, because of a lack of ventilation, phosphine gas can be produced. This gas is highly toxic and, if present in large quantities, is likely to explode upon autoignition from diphosphine, which is formed by overheating phosphorus.
In recent years, reports of a simplified "Shake 'n Bake" synthesis have surfaced. The method is suitable for such small batches that pseudoephedrine restrictions are less effective, it uses chemicals that are easier to obtain (though no less dangerous than traditional methods), and it is so easy to carry out that some addicts have made the drug while driving. Producing methamphetamine in this fashion can be extremely dangerous and has been linked to several fatalities.
Production and distribution
Until the early 1990s, methamphetamine for the U.S. market was made mostly in labs run by drug traffickers in Mexico and California. Since then, authorities have discovered increasing numbers of small-scale methamphetamine labs all over the United States, mostly in rural, suburban, or low-income areas. Indiana state police found 1,260 labs in 2003, compared to just 6 in 1995, although this may be partly a result of increased police activity. As of 2007, drug and lab seizure data suggests that approximately 80 percent of the methamphetamine used in the United States originates from larger laboratories operated by Mexican-based syndicates on both sides of the border and that approximately 20 percent comes from small toxic labs (STLs) in the United States.
Mobile and motel-based methamphetamine labs have caught the attention of both the U.S. news media and the police. Such labs can cause explosions and fires and expose the public to hazardous chemicals. Those who manufacture methamphetamine are often harmed by toxic gases. Many police departments have specialized task forces with training to respond to cases of methamphetamine production. The National Drug Threat Assessment 2006, produced by the Department of Justice, found "decreased domestic methamphetamine production in both small and large-scale laboratories", but also that "decreases in domestic methamphetamine production have been offset by increased production in Mexico." They concluded that "methamphetamine availability is not likely to decline in the near term."
In July 2007, Mexican officials at the port of Lázaro Cárdenas seized a ship carrying 19 tons of pseudoephedrine, a raw material needed for methamphetamine. The shipment originated in Hong Kong and passed through the United States at the port of Long Beach prior to its arrival in Mexico.
Methamphetamine is distributed by prison gangs, outlaw motorcycle gangs, street gangs, traditional organized crime operations, and impromptu small networks. In the United States, illicit methamphetamine comes in a variety of forms with prices varying widely over time. Most commonly, it is found as a colorless crystalline solid. Impurities may result in a brownish or tan color. Colorful flavored pills containing methamphetamine and caffeine are known as yaa baa (Thai for "crazy medicine").
An impure form of methamphetamine is sold as a crumbly brown or off-white rock, commonly referred to as "peanut butter crank". Methamphetamine found on the street is rarely pure, but adulterated with chemicals that were used to synthesize it. It may be diluted or cut with non-psychoactive substances like inositol, isopropylbenzylamine or dimethylsulfone. Another popular method is to combine methamphetamine with other stimulant substances such as caffeine or cathine into a pill known as a "Kamikaze", which can be particularly dangerous due to the synergistic effects of multiple stimulants. It may also be flavored with high-sugar candies, drinks, or drink mixes to mask the bitter taste of the drug. Coloring may be added to the meth, as is the case with "Strawberry Quick".
Natural occurrence
Methamphetamine has been reported to occur naturally in Acacia berlandieri, and possibly Acacia rigidula, trees that grow in West Texas. Methamphetamine and regular amphetamine were long thought to be strictly human-synthesized, but Acacia trees contain these and numerous other psychoactive compounds (e.g., mescaline, nicotine, dimethyltryptamine), and the related compound β-phenethylamine is known to occur from numerous Acacia species.
Terminology
Nicknames for methamphetamine are numerous and vary significantly from region to region. Some common nicknames for methamphetamine include "ice", "meth", "crystal", "crystal meth", "crank", "glass", "chalk", "fire", "go-fast", "tweak", "nazi dope", "gack" and "jib" (Canada), "shabu" (Japan, Philippines, Malaysia), "tik" (South Africa), "Sissonville Slim Fast" (West Virginia), "ya ba" (Thailand), and "P" (New Zealand). The name most commonly used in the gay community is "Tina". Methamphetamine may often be referred to as "speed", a term that is also used for regular amphetamine without the methyl group.
Legality
This section needs expansion. You can help by making an edit requestadding to it . (May 2010) |
The production, distribution, sale, and possession of methamphetamine is restricted or illegal in many jurisdictions. Methamphetamine has been placed in schedule II of the United Nations Convention on Psychotropic Substances treaty.
See also
- Amphetamine
- Childhelp Crystal Darkness
- Clandestine chemistry
- Dextroamphetamine
- G protein-coupled receptor
- Levomethamphetamine
- Methamphetamine Drug Trade
- Montana Meth Project
- Phenethylamine
- Propylhexedrine
- Releasing agent
- Rolling meth lab
Further reading
- Yudko, Errol (2008-10-29). Methamphetamine Use: Clinical and Forensic Aspects. 408 (2 ed.). Boca Raton, FL: CRC Press. ISBN 978-0849372735.
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References
- ^ Schepers RJ, Oyler JM, Joseph RE, Cone EJ, Moolchan ET, Huestis MA (2003). "Methamphetamine and amphetamine pharmacokinetics in oral fluid and plasma after controlled oral methamphetamine administration to human volunteers". Clinical Chemistry. 49 (1): 121–32. doi:10.1373/49.1.121. PMID 12507968.
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ignored (help)CS1 maint: multiple names: authors list (link) - Mack, Avram H.; Frances, Richard J.; Miller, Sheldon I. (2005). Clinical Textbook of Addictive Disorders, Third Edition. New York: The Guilford Press. p. 207. ISBN 1-59385-174-X.
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: CS1 maint: multiple names: authors list (link) - B.K. Logan. Methamphetamine - Effects on Human Performance and Behavior. Forensic Science Review, Vol. 14, no. 1/2 (2002), p. 142 Full PDF
- RxList | Desoxyn (Methamphetamine Hydrochloride)
- Nagai N. (1893). "Kanyaku maou seibun kenkyuu seiseki (zoku)". Yakugaku Zasshi. 127: 832–860.
- ^ Mitler MM, Hajdukovic R, Erman MK (1993). "Treatment of narcolepsy with methamphetamine". Sleep. 16 (4): 306–17. PMC 2267865. PMID 8341891.
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ignored (help)CS1 maint: multiple names: authors list (link) - Grinspoon (1975-01-01). Speed Culture: Amphetamine Use and Abuse in America. Harvard University Press. p. 18. ISBN 978-0674831926.
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ignored (help)CS1 maint: multiple names: authors list (link) - Grandy DK (2007). "Trace amine-associated receptor 1-Family archetype or iconoclast?". Pharmacology & Therapeutics. 116 (3): 355–90. doi:10.1016/j.pharmthera.2007.06.007. PMC 2767338. PMID 17888514.
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and|journal=
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- New Zealand Police - What is methamphetamine?
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External links
- NLM Hazardous Substances Data Bank - Entry for d-methamphetamine
- Erowid Methamphetamine Vault
- EMCDDA drugs profiles: Methamphetamine (2007)
- EMCDDA paper on Methamphetamine supply in Europe (2009)
- A Key to Methamphetamine-Related Literature - A comprehensive thematic index of methamphetamine research published in academic and scientific journals with links from citations to the PubMed abstracts.
- Meth FAQ - More detailed synthesis and synthesis from other sources.
- DEA's Methamphetamine News Releases
- Poison Information Monograph (PIM 334: Methamphetamine)
- Chronic Amphetamine Use and Abuse - a thorough review on the effects of chronic use (American College of Neuropsychopharmacology)
- - Self-help guide for family members and loved ones of methamphetamine addicts
- U.S. National Library of Medicine: Drug Information Portal - Methamphetamine
Documentaries
- The Ice Age - ABC Australia - 4 Corners — Australian methamphetamine use.
- Frontline - The Meth Epidemic - PBS United States — Frontline.
- The World's Most Dangerous Drug - National Geographic.
- The City Addicted to Crystal Meth - BBC (Louis Theroux)
Academic Sources
- History and Epidemiology of Amphetamine Abuse in United States
- Methamphetamine, the Crystal Method, and the War on Drugs
- The Methamphetamine Crisis in American Indian and Native Alaskan Communities
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