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Tuesday, November 7, 2023

Methamphetamine

From Wikipedia, the free encyclopedia
Methamphetamine
INN: Metamfetamine
A racemic image of the methamphetamine compound
A 3d image of the levo-methamphetamine compound A 3d image of the dextro-methamphetamine compound
Clinical data
Pronunciation/ˌmɛθæmˈfɛtəmn/
(METH-am-FET-ə-meen), /ˌmɛθəmˈfɛtəmn/
(METH-əm-FET-ə-meen), /ˌmɛθəmˈfɛtəmən/
(METH-əm-FET-ə-mən)
Trade namesDesoxyn, Methedrine
Other namesN-methylamphetamine, N,α-dimethylphenethylamine, desoxyephedrine
AHFS/Drugs.comMonograph
License data
Dependence
liability
Physical: None; Psychological: High
Addiction
liability
High
Routes of
administration
Medical: oral (ingestion)
Recreational: oral, intravenous, intramuscular, subcutaneous, vapour inhalation, insufflation, rectal, vaginal
ATC code
Legal status
Legal status
Pharmacokinetic data
BioavailabilityOral: 67%
Intranasal: 79%Inhalation: 67–90%
Intravenous: 100%
Protein bindingVaries widely
MetabolismCYP2D6 and FMO3
Onset of actionOral: 3 hours (peak)
Intranasal: <15 minutes
Inhalation: <18 minutesIntravenous: <15 minutes
Elimination half-life9–12 hours (range 5–30 hours) (irrespective of route)
Duration of action8–12 hours
ExcretionPrimarily kidney
Identifiers

CAS Number
PubChem CID
IUPHAR/BPS
DrugBank
ChemSpider
UNII
KEGG
ChEBI
ChEMBL
PDB ligand
CompTox Dashboard (EPA)
ECHA InfoCard100.007.882 Edit this at Wikidata
Chemical and physical data
FormulaC10H15N
Molar mass149.237 g·mol−1
3D model (JSmol)
ChiralityRacemic mixture
Melting point170 °C (338 °F) 
Boiling point212 °C (414 °F) at 760 mmHg



Methamphetamine (contracted from N-methylamphetamine) is a potent central nervous system (CNS) stimulant that is mainly used as a recreational drug and less commonly as a second-line treatment for attention deficit hyperactivity disorder and obesity. Methamphetamine was discovered in 1893 and exists as two enantiomers: levo-methamphetamine and dextro-methamphetamine. Methamphetamine properly refers to a specific chemical substance, the racemic free base, which is an equal mixture of levomethamphetamine and dextromethamphetamine in their pure amine forms, but the hydrochloride salt, commonly called crystal meth, is widely used. Methamphetamine is rarely prescribed over concerns involving human neurotoxicity and potential for recreational use as an aphrodisiac and euphoriant, among other concerns, as well as the availability of safer substitute drugs with comparable treatment efficacy such as Adderall and Vyvanse. Dextromethamphetamine is a stronger CNS stimulant than levomethamphetamine.

Both racemic methamphetamine and dextromethamphetamine are illicitly trafficked and sold owing to their potential for recreational use. The highest prevalence of illegal methamphetamine use occurs in parts of Asia and Oceania, and in the United States, where racemic methamphetamine and dextromethamphetamine are classified as schedule II controlled substances. Levomethamphetamine is available as an over-the-counter (OTC) drug for use as an inhaled nasal decongestant in the United States. Internationally, the production, distribution, sale, and possession of methamphetamine is restricted or banned in many countries, owing to its placement in schedule II of the United Nations Convention on Psychotropic Substances treaty. While dextromethamphetamine is a more potent drug, racemic methamphetamine is illicitly produced more often, owing to the relative ease of synthesis and regulatory limits of chemical precursor availability.

In low to moderate doses, methamphetamine can elevate mood, increase alertness, concentration and energy in fatigued individuals, reduce appetite, and promote weight loss. At very high doses, it can induce psychosis, breakdown of skeletal muscle, seizures and bleeding in the brain. Chronic high-dose use can precipitate unpredictable and rapid mood swings, stimulant psychosis (e.g., paranoia, hallucinations, delirium, and delusions) and violent behavior. Recreationally, methamphetamine's ability to increase energy has been reported to lift mood and increase sexual desire to such an extent that users are able to engage in sexual activity continuously for several days while binging the drug. Methamphetamine is known to possess a high addiction liability (i.e., a high likelihood that long-term or high dose use will lead to compulsive drug use) and high dependence liability (i.e. a high likelihood that withdrawal symptoms will occur when methamphetamine use ceases). Withdrawal from methamphetamine after heavy use may lead to a post-acute-withdrawal syndrome, which can persist for months beyond the typical withdrawal period. Methamphetamine is neurotoxic to human midbrain dopaminergic neurons and, to a lesser extent, serotonergic neurons at high doses. Methamphetamine neurotoxicity causes adverse changes in brain structure and function, such as reductions in grey matter volume in several brain regions, as well as adverse changes in markers of metabolic integrity.

Methamphetamine belongs to the substituted phenethylamine and substituted amphetamine chemical classes. It is related to the other dimethylphenethylamines as a positional isomer of these compounds, which share the common chemical formula C10H15N.

Uses

Medical

Desoxyn (methamphetamine hydrochloride) 100 tablets

In the United States, methamphetamine hydrochloride, under the trade name Desoxyn, has been approved by the FDA for treating ADHD and obesity in both adults and children; however, the FDA also indicates that the limited therapeutic usefulness of methamphetamine should be weighed against the inherent risks associated with its use. To avoid toxicity and risk of side effects, FDA guidelines recommend an initial dose of methamphetamine at doses 5–10 mg/day for ADHD in adults and children over six years of age, and may be increased at weekly intervals of 5 mg, up to 25 mg/day, until optimum clinical response is found; the usual effective dose is around 20–25 mg/day. Methamphetamine is sometimes prescribed off label for narcolepsy and idiopathic hypersomnia. In the United States, methamphetamine's levorotary form is available in some over-the-counter (OTC) nasal decongestant products.

As methamphetamine is associated with a high potential for misuse, the drug is regulated under the Controlled Substances Act and is listed under Schedule II in the United States. Methamphetamine hydrochloride dispensed in the United States is required to include a boxed warning regarding its potential for recreational misuse and addiction liability.

Desoxyn and Desoxyn Gradumet are both pharmaceutical forms of the drug. The latter is no longer produced and is a extended-release form of the drug, flattening the curve of the effect of the drug while extending it.

Recreational

Methamphetamine is often used recreationally for its effects as a potent euphoriant and stimulant as well as aphrodisiac qualities.

According to a National Geographic TV documentary on methamphetamine, an entire subculture known as party and play is based around sexual activity and methamphetamine use. Participants in this subculture, which consists almost entirely of homosexual male methamphetamine users, will typically meet up through internet dating sites and have sex. Because of its strong stimulant and aphrodisiac effects and inhibitory effect on ejaculation, with repeated use, these sexual encounters will sometimes occur continuously for several days on end. The crash following the use of methamphetamine in this manner is very often severe, with marked hypersomnia (excessive daytime sleepiness). The party and play subculture is prevalent in major US cities such as San Francisco and New York City.

Desoxyn tablet
Desoxyn tablets – pharmaceutical methamphetamine hydrochloride
 
Crystal meth
Crystal meth – illicit methamphetamine hydrochloride

Contraindications

Methamphetamine is contraindicated in individuals with a history of substance use disorder, heart disease, or severe agitation or anxiety, or in individuals currently experiencing arteriosclerosis, glaucoma, hyperthyroidism, or severe hypertension. The FDA states that individuals who have experienced hypersensitivity reactions to other stimulants in the past or are currently taking monoamine oxidase inhibitors should not take methamphetamine. The FDA also advises individuals with bipolar disorder, depression, elevated blood pressure, liver or kidney problems, mania, psychosis, Raynaud's phenomenon, seizures, thyroid problems, tics, or Tourette syndrome to monitor their symptoms while taking methamphetamine. Owing to the potential for stunted growth, the FDA advises monitoring the height and weight of growing children and adolescents during treatment.

Adverse effects

A 2010 study ranking various illegal and legal drugs based on statements by drug-harm experts. Methamphetamine was found to be the fourth most damaging to users.

Physical

The physical effects of methamphetamine can include loss of appetite, hyperactivity, dilated pupils, flushed skin, excessive sweating, increased movement, dry mouth and teeth grinding (leading to "meth mouth"), headache, irregular heartbeat (usually as accelerated heartbeat or slowed heartbeat), rapid breathing, high blood pressure, low blood pressure, high body temperature, diarrhea, constipation, blurred vision, dizziness, twitching, numbness, tremors, dry skin, acne, and pale appearance. Long-term meth users may have sores on their skin; these may be caused by scratching due to itchiness or the belief that insects are crawling under their skin, and the damage is compounded by poor diet and hygiene. Numerous deaths related to methamphetamine overdoses have been reported.

Meth mouth

A suspected case of meth mouth

Methamphetamine users and addicts may lose their teeth abnormally quickly, regardless of the route of administration, from a condition informally known as meth mouth. The condition is generally most severe in users who inject the drug, rather than swallow, smoke, or inhale it. 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)". As dry mouth is also a common side effect of other stimulants, which are not known to contribute severe tooth decay, many researchers suggest that methamphetamine-associated tooth decay is more due to users' other choices. They suggest the side effect has been exaggerated and stylized to create a stereotype of current users as a deterrence for new ones.

Sexually transmitted infection

Methamphetamine use was found to be related to higher frequencies of unprotected sexual intercourse in both HIV-positive and unknown casual partners, an association more pronounced in HIV-positive participants. These findings suggest that methamphetamine use and engagement in unprotected anal intercourse are co-occurring risk behaviors, behaviors that potentially heighten the risk of HIV transmission among gay and bisexual men. Methamphetamine use allows users of both sexes to engage in prolonged sexual activity, which may cause genital sores and abrasions as well as priapism in men. Methamphetamine may also cause sores and abrasions in the mouth via bruxism, increasing the risk of sexually transmitted infection.

Besides the sexual transmission of HIV, it may also be transmitted between users who share a common needle. The level of needle sharing among methamphetamine users is similar to that among other drug injection users.

Psychological

The psychological effects of methamphetamine can include euphoria, dysphoria, changes in libido, alertness, apprehension and concentration, decreased sense of fatigue, insomnia or wakefulness, self-confidence, sociability, irritability, restlessness, grandiosity and repetitive and obsessive behaviors. Peculiar to methamphetamine and related stimulants is "punding", persistent non-goal-directed repetitive activity. Methamphetamine use also has a high association with anxiety, depression, amphetamine psychosis, suicide, and violent behaviors.

Neurotoxic and neuroimmunological

This diagram depicts the neuroimmune mechanisms that mediate methamphetamine-induced neurodegeneration in the human brain. The NF-κB-mediated neuroimmune response to methamphetamine use which results in the increased permeability of the blood–brain barrier arises through its binding at and activation of sigma receptors, the increased production of reactive oxygen species (ROS), reactive nitrogen species (RNS), and damage-associated molecular pattern molecules (DAMPs), the dysregulation of glutamate transporters (specifically, EAAT1 and EAAT2) and glucose metabolism, and excessive Ca2+ ion influx in glial cells and dopamine neurons.

Methamphetamine is directly neurotoxic to dopaminergic neurons in both lab animals and humans. Excitotoxicity, oxidative stress, metabolic compromise, UPS dysfunction, protein nitration, endoplasmic reticulum stress, p53 expression and other processes contributed to this neurotoxicity. In line with its dopaminergic neurotoxicity, methamphetamine use is associated with a higher risk of Parkinson's disease. In addition to its dopaminergic neurotoxicity, a review of evidence in humans indicated that high-dose methamphetamine use can also be neurotoxic to serotonergic neurons. It has been demonstrated that a high core temperature is correlated with an increase in the neurotoxic effects of methamphetamine. Withdrawal of methamphetamine in dependent persons may lead to post-acute withdrawal which persists months beyond the typical withdrawal period.

Magnetic resonance imaging studies on human methamphetamine users have also found evidence of neurodegeneration, or adverse neuroplastic changes in brain structure and function. In particular, methamphetamine appears to cause hyperintensity and hypertrophy of white matter, marked shrinkage of hippocampi, and reduced gray matter in the cingulate cortex, limbic cortex, and paralimbic cortex in recreational methamphetamine users. Moreover, evidence suggests that adverse changes in the level of biomarkers of metabolic integrity and synthesis occur in recreational users, such as a reduction in N-acetylaspartate and creatine levels and elevated levels of choline and myoinositol.

Methamphetamine has been shown to activate TAAR1 in human astrocytes and generate cAMP as a result. Activation of astrocyte-localized TAAR1 appears to function as a mechanism by which methamphetamine attenuates membrane-bound EAAT2 (SLC1A2) levels and function in these cells.

Methamphetamine binds to and activates both sigma receptor subtypes, σ1 and σ2, with micromolar affinity.] Sigma receptor activation may promote methamphetamine-induced neurotoxicity by facilitating hyperthermia, increasing dopamine synthesis and release, influencing microglial activation, and modulating apoptotic signaling cascades and the formation of reactive oxygen species.

Addictive

Addiction and dependence glossary
Signaling cascade in the nucleus accumbens that results in psychostimulant addiction
This diagram depicts the signaling events in the brain's reward center that are induced by chronic high-dose exposure to psychostimulants that increase the concentration of synaptic dopamine, like amphetamine, methamphetamine, and phenethylamine. Following presynaptic dopamine and glutamate co-release by such psychostimulants, postsynaptic receptors for these neurotransmitters trigger internal signaling events through a cAMP-dependent pathway and a calcium-dependent pathway that ultimately result in increased CREB phosphorylation. Phosphorylated CREB increases levels of ΔFosB, which in turn represses the c-Fos gene with the help of corepressors; c-Fos repression acts as a molecular switch that enables the accumulation of ΔFosB in the neuron. A highly stable (phosphorylated) form of ΔFosB, one that persists in neurons for 1–2 months, slowly accumulates following repeated high-dose exposure to stimulants through this process. ΔFosB functions as "one of the master control proteins" that produces addiction-related structural changes in the brain, and upon sufficient accumulation, with the help of its downstream targets (e.g., nuclear factor kappa B), it induces an addictive state.
 

Current models of addiction from chronic drug use involve alterations in gene expression in certain parts of the brain, particularly the nucleus accumbens. The most important transcription factors that produce these alterations are ΔFosB, cAMP response element binding protein (CREB), and nuclear factor kappa B (NFκB). ΔFosB plays a crucial role in the development of drug addictions, since its overexpression in D1-type medium spiny neurons in the nucleus accumbens is necessary and sufficient for most of the behavioral and neural adaptations that arise from addiction. Once ΔFosB is sufficiently overexpressed, it induces an addictive state that becomes increasingly more severe with further increases in ΔFosB expression. It has been implicated in addictions to alcohol, cannabinoids, cocaine, methylphenidate, nicotine, opioids, phencyclidine, propofol, and substituted amphetamines, among others.

ΔJunD, a transcription factor, and G9a, a histone methyltransferase enzyme, both directly oppose the induction of ΔFosB in the nucleus accumbens (i.e., they oppose increases in its expression). Sufficiently overexpressing ΔJunD in the nucleus accumbens with viral vectors can completely block many of the neural and behavioral alterations seen in chronic drug use (i.e., the alterations mediated by ΔFosB). ΔFosB also plays an important role in regulating behavioral responses to natural rewards, such as palatable food, sex, and exercise. Since both natural rewards and addictive drugs induce expression of ΔFosB (i.e., they cause the brain to produce more of it), chronic acquisition of these rewards can result in a similar pathological state of addiction. ΔFosB is the most significant factor involved in both amphetamine addiction and amphetamine-induced sex addictions, which are compulsive sexual behaviors that result from excessive sexual activity and amphetamine use. These sex addictions (i.e., drug-induced compulsive sexual behaviors) are associated with a dopamine dysregulation syndrome which occurs in some patients taking dopaminergic drugs, such as amphetamine or methamphetamine.

Epigenetic factors

Methamphetamine addiction is persistent for many individuals, with 61% of individuals treated for addiction relapsing within one year. About half of those with methamphetamine addiction continue with use over a ten-year period, while the other half reduce use starting at about one to four years after initial use.

The frequent persistence of addiction suggests that long-lasting changes in gene expression may occur in particular regions of the brain, and may contribute importantly to the addiction phenotype. In 2014, a crucial role was found for epigenetic mechanisms in driving lasting changes in gene expression in the brain.

A review in 2015 summarized a number of studies involving chronic methamphetamine use in rodents. Epigenetic alterations were observed in the brain reward pathways, including areas like ventral tegmental area, nucleus accumbens, and dorsal striatum, the hippocampus, and the prefrontal cortex. Chronic methamphetamine use caused gene-specific histone acetylations, deacetylations and methylations. Gene-specific DNA methylations in particular regions of the brain were also observed. The various epigenetic alterations caused downregulations or upregulations of specific genes important in addiction. For instance, chronic methamphetamine use caused methylation of the lysine in position 4 of histone 3 located at the promoters of the c-fos and the C-C chemokine receptor 2 (ccr2) genes, activating those genes in the nucleus accumbens (NAc). c-fos is well known to be important in addiction. The ccr2 gene is also important in addiction, since mutational inactivation of this gene impairs addiction.

In methamphetamine addicted rats, epigenetic regulation through reduced acetylation of histones, in brain striatal neurons, caused reduced transcription of glutamate receptors. Glutamate receptors play an important role in regulating the reinforcing effects of misused illicit drugs.

Administration of methamphetamine to rodents causes DNA damage in their brain, particularly in the nucleus accumbens region. During repair of such DNA damages, persistent chromatin alterations may occur such as in the methylation of DNA or the acetylation or methylation of histones at the sites of repair. These alterations can be epigenetic scars in the chromatin that contribute to the persistent epigenetic changes found in methamphetamine addiction.

Treatment and management

A 2018 systematic review and network meta-analysis of 50 trials involving 12 different psychosocial interventions for amphetamine, methamphetamine, or cocaine addiction found that combination therapy with both contingency management and community reinforcement approach had the highest efficacy (i.e., abstinence rate) and acceptability (i.e., lowest dropout rate). Other treatment modalities examined in the analysis included monotherapy with contingency management or community reinforcement approach, cognitive behavioral therapy, 12-step programs, non-contingent reward-based therapies, psychodynamic therapy, and other combination therapies involving these.

As of December 2019, there is no effective pharmacotherapy for methamphetamine addiction.[91][92][93] A systematic review and meta-analysis from 2019 assessed the efficacy of 17 different pharmacotherapies used in randomized controlled trials (RCTs) for amphetamine and methamphetamine addiction; it found only low-strength evidence that methylphenidate might reduce amphetamine or methamphetamine self-administration.[92] There was low- to moderate-strength evidence of no benefit for most of the other medications used in RCTs, which included antidepressants (bupropion, mirtazapine, sertraline), antipsychotics (aripiprazole), anticonvulsants (topiramate, baclofen, gabapentin), naltrexone, varenicline, citicoline, ondansetron, prometa, riluzole, atomoxetine, dextroamphetamine, and modafinil.

Dependence and withdrawal

Tolerance is expected to develop with regular methamphetamine use and, when used recreationally, this tolerance develops rapidly. In dependent users, withdrawal symptoms are positively correlated with the level of drug tolerance. Depression from methamphetamine withdrawal lasts longer and is more severe than that of cocaine withdrawal.

According to the current Cochrane review on drug dependence and withdrawal in recreational users of methamphetamine, "when chronic heavy users abruptly discontinue [methamphetamine] use, many report a time-limited withdrawal syndrome that occurs within 24 hours of their last dose". Withdrawal symptoms in chronic, high-dose users are frequent, occurring in up to 87.6% of cases, and persist for three to four weeks with a marked "crash" phase occurring during the first week. Methamphetamine withdrawal symptoms can include anxiety, drug craving, dysphoric mood, fatigue, increased appetite, increased movement or decreased movement, lack of motivation, sleeplessness or sleepiness, and vivid or lucid dreams.

Methamphetamine that is present in a mother's bloodstream can pass through the placenta to a fetus and be secreted into breast milk. Infants born to methamphetamine-abusing mothers may experience a neonatal withdrawal syndrome, with symptoms involving of abnormal sleep patterns, poor feeding, tremors, and hypertonia. This withdrawal syndrome is relatively mild and only requires medical intervention in approximately 4% of cases.

Summary of addiction-related plasticity
Form of neuroplasticity
or behavioral plasticity
Type of reinforcer
Opiates Psychostimulants High fat or sugar food Sexual intercourse Physical exercise
(aerobic)
Environmental
enrichment
ΔFosB expression in
nucleus accumbens D1-type MSNsTooltip medium spiny neurons

Behavioral plasticity
Escalation of intake Yes Yes Yes



Psychostimulant
cross-sensitization
Yes Not applicable Yes Yes Attenuated Attenuated
Psychostimulant
self-administration


Psychostimulant
conditioned place preference

Reinstatement of drug-seeking behavior


Neurochemical plasticity
CREBTooltip cAMP response element-binding protein phosphorylation
in the nucleus accumbens


Sensitized dopamine response
in the nucleus accumbens
No Yes No Yes


Altered striatal dopamine signaling DRD2, ↑DRD3 DRD1, ↓DRD2, ↑DRD3 DRD1, ↓DRD2, ↑DRD3
DRD2 DRD2
Altered striatal opioid signaling No change or
μ-opioid receptors
μ-opioid receptors
κ-opioid receptors
μ-opioid receptors μ-opioid receptors No change No change
Changes in striatal opioid peptides dynorphin
No change: enkephalin
dynorphin enkephalin
dynorphin dynorphin
Mesocorticolimbic synaptic plasticity
Number of dendrites in the nucleus accumbens



Dendritic spine density in
the nucleus accumbens




Neonatal

Unlike other drugs, babies with prenatal exposure to methamphetamine do not show immediate signs of withdrawal. Instead, cognitive and behavioral problems start emerging when the children reach school age.

A prospective cohort study of 330 children showed that at the age of 3, children with methamphetamine exposure showed increased emotional reactivity, as well as more signs of anxiety and depression; and at the age of 5, children showed higher rates of externalizing and attention deficit/hyperactivity disorders.

Overdose

A methamphetamine overdose may result in a wide range of symptoms. A moderate overdose of methamphetamine may induce symptoms such as: abnormal heart rhythm, confusion, difficult and/or painful urination, high or low blood pressure, high body temperature, over-active and/or over-responsive reflexes, muscle aches, severe agitation, rapid breathing, tremor, urinary hesitancy, and an inability to pass urine. An extremely large overdose may produce symptoms such as adrenergic storm, methamphetamine psychosis, substantially reduced or no urine output, cardiogenic shock, bleeding in the brain, circulatory collapse, hyperpyrexia (i.e., dangerously high body temperature), pulmonary hypertension, kidney failure, rapid muscle breakdown, serotonin syndrome, and a form of stereotypy ("tweaking"). A methamphetamine overdose will likely also result in mild brain damage owing to dopaminergic and serotonergic neurotoxicity. Death from methamphetamine poisoning is typically preceded by convulsions and coma.

Psychosis

Use of methamphetamine can result in a stimulant psychosis which may present with a variety of symptoms (e.g., paranoia, hallucinations, delirium, and delusions). A Cochrane Collaboration review on treatment for amphetamine, dextroamphetamine, and methamphetamine use-induced psychosis states that about 5–15% of users fail to recover completely. The same review asserts that, based upon at least one trial, antipsychotic medications effectively resolve the symptoms of acute amphetamine psychosis. Amphetamine psychosis may also develop occasionally as a treatment-emergent side effect.

Emergency treatment

Acute methamphetamine intoxication is largely managed by treating the symptoms and treatments may initially include administration of activated charcoal and sedation. There is not enough evidence on hemodialysis or peritoneal dialysis in cases of methamphetamine intoxication to determine their usefulness. Forced acid diuresis (e.g., with vitamin C) will increase methamphetamine excretion but is not recommended as it may increase the risk of aggravating acidosis, or cause seizures or rhabdomyolysis. Hypertension presents a risk for intracranial hemorrhage (i.e., bleeding in the brain) and, if severe, is typically treated with intravenous phentolamine or nitroprusside. Blood pressure often drops gradually following sufficient sedation with a benzodiazepine and providing a calming environment.

Antipsychotics such as haloperidol are useful in treating agitation and psychosis from methamphetamine overdose. Beta blockers with lipophilic properties and CNS penetration such as metoprolol and labetalol may be useful for treating CNS and cardiovascular toxicity. The mixed alpha- and beta-blocker labetalol is especially useful for treatment of concomitant tachycardia and hypertension induced by methamphetamine. The phenomenon of "unopposed alpha stimulation" has not been reported with the use of beta-blockers for treatment of methamphetamine toxicity.

Interactions

Methamphetamine is metabolized by the liver enzyme CYP2D6, so CYP2D6 inhibitors will prolong the elimination half-life of methamphetamine. Methamphetamine also interacts with monoamine oxidase inhibitors (MAOIs), since both MAOIs and methamphetamine increase plasma catecholamines; therefore, concurrent use of both is dangerous. Methamphetamine may decrease the effects of sedatives and depressants and increase the effects of antidepressants and other stimulants as well. Methamphetamine may counteract the effects of antihypertensives and antipsychotics owing to its effects on the cardiovascular system and cognition respectively. The pH of gastrointestinal content and urine affects the absorption and excretion of methamphetamine. Specifically, acidic substances will reduce the absorption of methamphetamine and increase urinary excretion, while alkaline substances do the opposite. Owing to the effect pH has on absorption, proton pump inhibitors, which reduce gastric acid, are known to interact with methamphetamine.

Pharmacology

An image of methamphetamine pharmacodynamics
This illustration depicts the normal operation of the dopaminergic terminal to the left, and the dopaminergic terminal in the presence of methamphetamine to the right. Methamphetamine reverses the action of the dopamine transporter (DAT) by activating TAAR1 (not shown). TAAR1 activation also causes some of the dopamine transporters to move into the presynaptic neuron and cease transport (not shown). At VMAT2 (labeled VMAT), methamphetamine causes dopamine efflux (release).

Pharmacodynamics

Methamphetamine has been identified as a potent full agonist of trace amine-associated receptor 1 (TAAR1), a G protein-coupled receptor (GPCR) that regulates brain catecholamine systems. Activation of TAAR1 increases cyclic adenosine monophosphate (cAMP) production and either completely inhibits or reverses the transport direction of the dopamine transporter (DAT), norepinephrine transporter (NET), and serotonin transporter (SERT). When methamphetamine binds to TAAR1, it triggers transporter phosphorylation via protein kinase A (PKA) and protein kinase C (PKC) signaling, ultimately resulting in the internalization or reverse function of monoamine transporters.  Methamphetamine is also known to increase intracellular calcium, an effect which is associated with DAT phosphorylation through a Ca2+/calmodulin-dependent protein kinase (CAMK)-dependent signaling pathway, in turn producing dopamine efflux. TAAR1 has been shown to reduce the firing rate of neurons through direct activation of G protein-coupled inwardly-rectifying potassium channels. TAAR1 activation by methamphetamine in astrocytes appears to negatively modulate the membrane expression and function of EAAT2, a type of glutamate transporter.

In addition to its effect on the plasma membrane monoamine transporters, methamphetamine inhibits synaptic vesicle function by inhibiting VMAT2, which prevents monoamine uptake into the vesicles and promotes their release. This results in the outflow of monoamines from synaptic vesicles into the cytosol (intracellular fluid) of the presynaptic neuron, and their subsequent release into the synaptic cleft by the phosphorylated transporters. Other transporters that methamphetamine is known to inhibit are SLC22A3 and SLC22A5. SLC22A3 is an extraneuronal monoamine transporter that is present in astrocytes, and SLC22A5 is a high-affinity carnitine transporter.

Methamphetamine is also an agonist of the alpha-2 adrenergic receptors and sigma receptors with a greater affinity for σ1 than σ2, and inhibits monoamine oxidase A (MAO-A) and monoamine oxidase B (MAO-B). Sigma receptor activation by methamphetamine may facilitate its central nervous system stimulant effects and promote neurotoxicity within the brain. Dextromethamphetamine is a stronger psychostimulant, but levomethamphetamine has stronger peripheral effects, a longer half-life, and longer perceived effects among addicts. At high doses, both enantiomers of methamphetamine can induce similar stereotypy and methamphetamine psychosis, but levomethamphetamine has shorter psychodynamic effects.

Pharmacokinetics

The bioavailability of methamphetamine is 67% orally, 79% intranasally, 67 to 90% via inhalation (smoking), and 100% intravenously. Following oral administration, methamphetamine is well-absorbed into the bloodstream, with peak plasma methamphetamine concentrations achieved in approximately 3.13–6.3 hours post ingestion. Methamphetamine is also well absorbed following inhalation and following intranasal administration. Because of the high lipophilicity of methamphetamine, it can readily move through the blood–brain barrier faster than other stimulants, where it is more resistant to degradation by monoamine oxidase. The amphetamine metabolite peaks at 10–24 hours. Methamphetamine is excreted by the kidneys, with the rate of excretion into the urine heavily influenced by urinary pH. When taken orally, 30–54% of the dose is excreted in urine as methamphetamine and 10–23% as amphetamine. Following IV doses, about 45% is excreted as methamphetamine and 7% as amphetamine. The elimination half-life of methamphetamine varies with a range of 5–30 hours, but it is on average 9 to 12 hours in most studies. The elimination half-life of methamphetamine does not vary by route of administration, but is subject to substantial interindividual variability.

CYP2D6, dopamine β-hydroxylase, flavin-containing monooxygenase 3, butyrate-CoA ligase, and glycine N-acyltransferase are the enzymes known to metabolize methamphetamine or its metabolites in humans. The primary metabolites are amphetamine and 4-hydroxymethamphetamine; other minor metabolites include: 4-hydroxyamphetamine, 4-hydroxynorephedrine, 4-hydroxyphenylacetone, benzoic acid, hippuric acid, norephedrine, and phenylacetone, the metabolites of amphetamine. Among these metabolites, the active sympathomimetics are amphetamine, 4‑hydroxyamphetamine, 4‑hydroxynorephedrine, 4-hydroxymethamphetamine, and norephedrine. Methamphetamine is a CYP2D6 inhibitor.

The main metabolic pathways involve aromatic para-hydroxylation, aliphatic alpha- and beta-hydroxylation, N-oxidation, N-dealkylation, and deamination. The known metabolic pathways include:

Metabolic pathways of methamphetamine in humans
The primary metabolites of methamphetamine are amphetamine and 4-hydroxymethamphetamine. Human microbiota, particularly Lactobacillus, Enterococcus, and Clostridium species, contribute to the metabolism of methamphetamine via an enzyme which N-demethylates methamphetamine and 4-hydroxymethamphetamine into amphetamine and 4-hydroxyamphetamine respectively.

Detection in biological fluids

Methamphetamine and amphetamine are often measured in urine or blood as part of a drug test for sports, employment, poisoning diagnostics, and forensics. Chiral techniques may be employed to help distinguish the source of the drug to determine whether it was obtained illicitly or legally via prescription or prodrug. Chiral separation is needed to assess the possible contribution of levomethamphetamine, which is an active ingredients in some OTC nasal decongestants, toward a positive test result. Dietary zinc supplements can mask the presence of methamphetamine and other drugs in urine.

Chemistry

Methamphetamine hydrochloride
Shards of pure methamphetamine hydrochloride, also known as crystal meth

Methamphetamine is a chiral compound with two enantiomers, dextromethamphetamine and levomethamphetamine. At room temperature, the free base of methamphetamine is a clear and colorless liquid with an odor characteristic of geranium leaves. It is soluble in diethyl ether and ethanol as well as miscible with chloroform.

In contrast, the methamphetamine hydrochloride salt is odorless with a bitter taste. It has a melting point between 170 and 175 °C (338 and 347 °F) and, at room temperature, occurs as white crystals or a white crystalline powder. The hydrochloride salt is also freely soluble in ethanol and water. The crystal structure of either enantiomer is monoclinic with P21 space group; at 90 K (−183.2 °C; −297.7 °F), it has lattice parameters a = 7.10 Å, b = 7.29 Å, c = 10.81 Å, and β = 97.29°.

Degradation

A 2011 study into the destruction of methamphetamine using bleach showed that effectiveness is correlated with exposure time and concentration. A year-long study (also from 2011) showed that methamphetamine in soils is a persistent pollutant. In a 2013 study of bioreactors in wastewater, methamphetamine was found to be largely degraded within 30 days under exposure to light.

Synthesis

Racemic methamphetamine may be prepared starting from phenylacetone by either the Leuckart or reductive amination methods. In the Leuckart reaction, one equivalent of phenylacetone is reacted with two equivalents of N-methylformamide to produce the formyl amide of methamphetamine plus carbon dioxide and methylamine as side products. In this reaction, an iminium cation is formed as an intermediate which is reduced by the second equivalent of N-methylformamide. The intermediate formyl amide is then hydrolyzed under acidic aqueous conditions to yield methamphetamine as the final product. Alternatively, phenylacetone can be reacted with methylamine under reducing conditions to yield methamphetamine.

Methamphetamine synthesis
Diagram of methamphetamine synthesis by reductive amination
Method of methamphetamine synthesis of methamphetamine via reductive amination
Diagram of methamphetamine synthesis by Leuckart reaction
Methods of methamphetamine synthesis via the Leuckart reaction

History, society, and culture

A methamphetamine tablet container
Pervitin, a methamphetamine brand used by German soldiers during World War II, was dispensed in these tablet containers.
U.S. drug overdose related fatalities in 2017 were 70,200, including 10,333 of those related to psychostimulants (including methamphetamine).

Amphetamine, discovered before methamphetamine, was first synthesized in 1887 in Germany by Romanian chemist Lazăr Edeleanu who named it phenylisopropylamine. Shortly after, methamphetamine was synthesized from ephedrine in 1893 by Japanese chemist Nagai Nagayoshi. Three decades later, in 1919, methamphetamine hydrochloride was synthesized by pharmacologist Akira Ogata via reduction of ephedrine using red phosphorus and iodine.

From 1938, methamphetamine was marketed on a large scale in Germany as a nonprescription drug under the brand name Pervitin, produced by the Berlin-based Temmler pharmaceutical company. It was used by all branches of the combined armed forces of the Third Reich, for its stimulant effects and to induce extended wakefulness. Pervitin became colloquially known among the German troops as "Stuka-Tablets" (Stuka-Tabletten) and "Herman-Göring-Pills" (Hermann-Göring-Pillen), as a snide allusion to Göring's widely-known addiction to drugs. However, the side effects, particularly the withdrawal symptoms, were so serious that the army sharply cut back its usage in 1940. By 1941, usage was restricted to a doctor's prescription, and the military tightly controlled its distribution. Soldiers would only receive a couple of tablets at a time, and were discouraged from using them in combat. Historian Łukasz Kamieński says,

A soldier going to battle on Pervitin usually found himself unable to perform effectively for the next day or two. Suffering from a drug hangover and looking more like a zombie than a great warrior, he had to recover from the side effects.

Some soldiers turned violent, committing war crimes against civilians; others attacked their own officers. At the end of the war, it was used as part of a new drug: D-IX.

Obetrol, patented by Obetrol Pharmaceuticals in the 1950s and indicated for treatment of obesity, was one of the first brands of pharmaceutical methamphetamine products. Because of the psychological and stimulant effects of methamphetamine, Obetrol became a popular diet pill in America in the 1950s and 1960s. Eventually, as the addictive properties of the drug became known, governments began to strictly regulate the production and distribution of methamphetamine. For example, during the early 1970s in the United States, methamphetamine became a schedule II controlled substance under the Controlled Substances Act. Currently, methamphetamine is sold under the trade name Desoxyn, trademarked by the Danish pharmaceutical company Lundbeck. As of January 2013, the Desoxyn trademark had been sold to Italian pharmaceutical company Recordati.

Trafficking

The Golden Triangle (Southeast Asia), specifically Shan State, Myanmar, is the world's leading producer of methamphetamine as production has shifted to Yaba and crystalline methamphetamine, including for export to the United States and across East and Southeast Asia and the Pacific.

Concerning the accelerating synthetic drug production in the region, the Cantonese Chinese syndicate Sam Gor, also known as The Company, is understood to be the main international crime syndicate responsible for this shift. It is made up of members of five different triads. Sam Gor is primarily involved in drug trafficking, earning at least $8 billion per year. Sam Gor is alleged to control 40% of the Asia-Pacific methamphetamine market, while also trafficking heroin and ketamine. The organization is active in a variety of countries, including Myanmar, Thailand, New Zealand, Australia, Japan, China, and Taiwan. Sam Gor previously produced meth in Southern China and is now believed to manufacture mainly in the Golden Triangle, specifically Shan State, Myanmar, responsible for much of the massive surge of crystal meth in circa 2019. The group is understood to be headed by Tse Chi Lop, a gangster born in Guangzhou, China who also holds a Canadian passport.

Liu Zhaohua was another individual involved in the production and trafficking of methamphetamine until his arrest in 2005. It was estimated over 18 tonnes of methamphetamine were produced under his watch.

Legal status

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.

Research

It has been suggested, based on animal research, that calcitriol, the active metabolite of vitamin D, can provide significant protection against the DA- and 5-HT-depleting effects of neurotoxic doses of methamphetamine.

Illegal drug trade in China

From Wikipedia, the free encyclopedia

The illegal drug trade in China is influenced by factors such as history, location, size, population, and current economic conditions. China has one-sixth of the world's population and a large and expanding economy. China's large land mass, close proximity to the Golden Triangle, Golden Crescent, and numerous coastal cities with large and modern port facilities make it an attractive transit center for drug traffickers. Opium has played an important role in the country's history since before the First and Second Opium Wars in the mid-19th century.

China's status in drug trafficking has changed significantly since the 1980s, when the country for the first time opened its borders to trade and tourism after 40 years of relative isolation. As trade with Southeast Asia and elsewhere increased, so did the flow of illicit drugs and precursor chemicals from, into, and through China.

Overview

China is a major source of precursor chemicals necessary for the production of fentanyl, cocaine, heroin, MDMA and crystal methamphetamine, which are used by many Southeast Asian and Pacific Rim nations. China produces over 100,000 metric tons of acetic anhydride each year, and imports an additional 20,000 metric tons from the United States and Singapore. Reports indicate that acetic anhydride is diverted from China to morphine and heroin refineries in the Golden Triangle. China is also a leading exporter of bulk ephedrine and has been a source country for much of the ephedrine and pseudoephedrine imported into Mexico; these precursor chemicals are subsequently used to manufacture methamphetamine destined for the United States. China is developing a significant MDMA production, trafficking, and consumption problem. Although China has taken actions through legislation and regulation of production and exportation of precursor chemicals, extensive action is required to control the illicit diversion and smuggling of precursor chemicals.

China not only continues to be a major transit route for Southeast Asian heroin bound for international drug markets, but also for Southwest Asian heroin entering northwestern China from Afghanistan, Pakistan, and Tajikistan. A majority of the Southeast Asian heroin that enters China from Myanmar transits southern China to various international markets by maritime transport. Drug traffickers take advantage of expanding port facilities in coastal cities, such as Qingdao, Shanghai, Tianjin, and Guangdong, to ship heroin along maritime routes. Southwest Asian heroin (mainly from Afghanistan) represents as much as 22 percent of the heroin entering northwest China. Chinese authorities believe that these trends will increase and they attribute these increases to the continuing development of the infrastructure and economy in China. China is being forced to develop a complex counter-drug strategy that includes prevention, education, eradication, interdiction, and rehabilitation.

Cultivation and processing

Cannabis

Cannabis grows naturally throughout southwestern China, and is legally cultivated in some areas of China for use in commercial rope manufacturing. Most of the illicit cultivation of cannabis as a drug in China appears in Xinjiang and Yunnan and is primarily cultivated for domestic use. In 2002, approximately 1.3 metric tons of cannabis were seized in China, with over 80 percent of cannabis seized being less than 20 grams.

Ephedra

The Chinese Government owns and operates ephedra farms, where ephedra grass (ephedra sinica) is cultivated under strict government control. The active alkaloids, pseudoephedrine and ephedrine, are chemically extracted from the plant material and processed for pharmaceutical purposes. These chemicals are then sold domestically and for export. China and India are the major producers of these chemicals extracted from the ephedra plant. In addition to government-controlled farms, the ephedra plant grows wildly in many parts of the northern areas of China.

Opium

Illicit cultivation of the opium poppy in China is negligible in provinces such as Yunnan, Ningxia, Inner Mongolia, and the remote regions of the northwest frontier. Opium produced in these areas is not converted into heroin, but is consumed locally by ethnic minority groups in these isolated areas. Chinese officials report that in the last several years no heroin laboratories have been seized in China.

Legal cultivation of the opium poppy occurs on farms controlled by the Ministry of Agriculture and the National Drug Administration Bureau of the State Council. According to United Nations (UN) International Narcotics Control Board (INCB) data, China produces approximately 14 metric tons (31,000 lb) of legal opium per year for use in the domestic pharmaceutical industry. China reports that none of this opium is exported.

The Mao Zedong government is generally credited with eradicating both consumption and production of opium during the 1950s using unrestrained repression and social reform. Ten million addicts were forced into compulsory treatment, dealers were executed, and opium-producing regions were planted with new crops. Remaining opium production shifted south of the Chinese border into the Golden Triangle region. The remnant opium trade primarily served Southeast Asia, but spread to American soldiers during the Vietnam War, with 20 per cent of soldiers regarding themselves as addicted during the peak of the epidemic in 1971. In 2003, China was estimated to have four million regular drug users and one million registered drug addicts.

Synthetic drugs

Manufacture of crystal methamphetamine (ice, shabu, bingdu) is facilitated by the availability of precursor chemicals, such as pseudoephedrine and ephedrine. The unrestricted availability of these chemicals in the country facilitates the production of large quantities of crystal methamphetamine. Seizure information indicates that methamphetamine laboratories are located in provinces along the eastern and southeastern coastal areas. Many of the traffickers for the clandestine crystal methamphetamine laboratories are from organized crime groups based in Hong Kong, Taiwan, and Japan.

Because of its increasing popularity with young party goers in Beijing, Shanghai, Nanjing, Guangzhou, and Shenzhen, Chinese law enforcement officials report significant increases in the domestic production of MDMA (Ecstasy). Most MDMA production in China is for domestic consumption. MDMA tablets are also imported from the Netherlands into China to meet the demand.

Some laboratory operators in China mix MDMA powder, imported from Europe, with substances, such as caffeine and ketamine, while making the Ecstasy tablets. Given the availability of the precursor chemicals needed, open source reporting in 2006 indicates that MDMA tablets in China cost only US$0.06 to produce, while the tablets sell for as much as US$36 in Shanghai.

Trafficking

Drug-related arrests in China,
1991–2003
Sources: Chinese Government Information,1991–2002, and the International Narcotics Control Strategy Report (INCSR), U.S. Department of State, 2002, and INCSR January 2003-June 2003.
Year Arrests Convictions
1991 8,080 5,285
1992 7,025 6,588
1993 7,677 6,137
1994 10,434 7,883
1995 12,990 9,801
1996 18,860 13,787
1997 24,873 18,878
1998 34,287 27,229
1999 37,627 33,641
2000 39,604 33,203
2001 40,602 33,895
2002 42,854 32,222
2003 31,400 25,879

Trafficking groups

Many of the individuals involved in the international trafficking of Southeast Asian heroin are ethnic Kokang, Yunnanese, Fujianese, Cantonese, or members of other ethnic Chinese minority groups that reside outside of China. These groups reside, and are actively involved in drug trafficking in regions such as Myanmar, Cambodia, Canada, Hong Kong, Taiwan, Thailand, and the United States.

Reporting on the activities of drug trafficking organizations in China is sparse. However, Chinese officials report that drug traffickers are dividing their large shipments into smaller ones in order to minimize losses in case of seizure. Chinese officials also report that drug traffickers are increasingly using women, children, and poor, uneducated farmers to body-carry drugs from the Golden Triangle area to Guangdong and other provinces in China.

In China many individuals and criminal organizations involved in drug trafficking are increasingly arming themselves with automatic weapons and grenades to protect their drug shipments from theft by rival organizations. Many firefights occur along the Myanmar–China border, where larger drug shipments are more prevalent. Traffickers also arm themselves to avoid being captured by the police, and some smugglers are better armed than the local police forces. Furthermore, many traffickers believe they have a better chance of surviving a firefight than the outcome of any legal proceedings. In China, sentencing for drug trafficking could include capital punishment. For example, the seizure of 50 grams or more of heroin or crystal methamphetamine could result in the use of the death penalty by the Government.

Hui Muslim drug dealers are accused by Uyghur Muslims of pushing heroin on Uyghurs. Heroin has been vended by Hui dealers. There is a typecast image in the public eye of heroin being the province of Hui dealers. Hui have been involved in the Golden Triangle drug area.

Drug seizures

Drug seizures in China (in metric tons) 1995-2003
Source: Chinese Government, 1995–2001; DEA Beijing, 2002 and INCSR (China), January 2003-June 2003.

1995 1996 1997 1998 1999 2000 2001 2002 2003
Heroin 2,376 4,347 5,478 7,358 5,364 6,281 13.2 9.29 4.07
Opium 1.11 1,745 1,880 1,215 1,193 2,428 2.82 1.2 N/A
Precursor chemicals 86 219 383 344 272 215 208 300 N/A
Marijuana 0,466 4,876 2,408 5,079 0,106 4,493 0,751 1.3 N/A
Crystal methamphetamine 1,304 1,599 1,334 1,608 16,059 20.9 4.82 3.19 4.53

Heroin

China's borders

China shares a 2000 km border with Myanmar, as well as smaller but significant borders with Laos and Vietnam. Chinese officials state that the majority of heroin entering China comes over the border from Myanmar. This heroin then transits southern China, through Yunnan or Guangxi, to Guangdong or Fujian to the southeastern coastal areas, and then on to international markets. Heroin is transported by various overland methods to ports in China's southeastern provinces of Guangdong and Fujian.

Heroin is transported to Guangdong and to the cities of Xiamen and Fuzhou in Fujian for shipment to international drug markets. Traffickers take advantage of expanding port facilities in northeast cities, such as Qingdao, Shanghai, and Tianjin, to ship heroin via maritime routes. Increased Chinese interdiction efforts along the Myanmar–China border have forced some traffickers to send heroin from Myanmar to China's southeastern provinces by fishing trawlers.

In addition to Southeast Asian heroin entering into China, Southwest Asian heroin enters northwestern China from Afghanistan, Pakistan, and Tajikistan. Chinese authorities state that Southwest Asian heroin (mainly originating from Afghanistan) represents as much as 20 percent of the heroin that enters the northwest Xinjiang. This trend is increasing, and is attributed to the continuing development of the infrastructure and economy in the western parts of China.

Synthetic drugs

Due to the availability of the precursor chemicals, traffickers produce large amounts of crystal methamphetamine. Although much of the crystal methamphetamine is consumed locally, some is available for shipment to other markets throughout Southeast Asia. Several ports in southern China serve as transit points for crystal methamphetamine transported by containerized cargo to international drug markets.

Some MDMA traffickers in China are linked directly to the United States. In June 2001, tablets from seizures in two DEA San Francisco investigations were linked to the same source as a 300,000-tablet seizure in Shenzhen, China that had occurred days before. Although the San Francisco seizures were much smaller than the Shenzhen seizure, the capabilities of these trafficking groups appear to be significant. Chinese officials seized over 3 million Ecstasy tablets in China in 2002.

Another case involved Liu Zhaohua, who produced up to 31 tonnes of methamphetamine and made more than $5.5 billion USD from it. In 2006, during the term of Hu Jintao, Liu was sentenced to death for drug trafficking, and in 2009 Liu was executed.

Precursor chemicals

China is of paramount importance in global cooperative efforts to prevent the diversion of precursor chemicals. With its large chemical industry, China remains a source country for legitimately produced chemicals that are diverted for production of heroin and cocaine, as well as many amphetamine-type stimulants. China and its neighbor India are the leading exporters of bulk ephedrine in the world. China produces over 100,000 metric tons of acetic anhydride each year, and imports an additional 20,000 metric tons from the United States and Singapore. China is also the second largest producer of potassium permanganate in the world.

To combat the diversion of precursor chemicals, China implemented several regulations on the control of precursor chemicals between 1992 and 1998, including adoption of the 1988 U.N. Convention Against Illicit Traffic in Narcotic Drugs and Psychotropic Substances in 1993. Additionally, the Government further improved regulations to strengthen control of ephedrine during 1999 and 2000.

China fully participates in the DEA's Operations TOPAZ and PURPLE, which are international monitoring initiatives that target acetic anhydride and potassium permanganate, respectively. Acetic anhydride is used to synthesize morphine base into heroin, and potassium permanganate is used as an oxidizer in cocaine production. Both chemicals are targeted because they are the chemicals most often preferred, and most widely used, by illicit drug manufacturers. However, the effectiveness of Operation PURPLE has been declining recently, since participant nations are exporting significant amounts of potassium permanganate to non-participant countries.

Additionally, Chinese authorities further control the export of ephedrine and pseudoephedrine through the voluntary use of the Letter of Non-Objection (LONO) system. China will not allow exports of ephedrine or pseudoephedrine without a positive affirmation by authorities in the importing country as to the bona fides of the consignee. For those countries that do not issue import permits, a letter of non-objection must be provided to Chinese authorities.

China is a source country for significant amounts of the ephedrine and pseudoephedrine exported to Mexico, and subsequently used to manufacture methamphetamine destined for the United States.

Increases in pseudoephedrine diversion were noted, beginning with the seizures in March and April 2003 of four shipments of product destined for Mexico. The seizures occurred in the United States and Panama, and totaled over 22 million, 60-milligram pseudoephedrine tablets. The source of supply has been identified as legitimate pharmaceutical companies in Hong Kong. Additional investigations have revealed other companies in Hong Kong that have been engaged in supplying substantial amounts of pseudoephedrine to firms, sometime fictitious, shells or fronts, in Mexico.

Also, reports indicate that acetic anhydride is diverted from China to morphine/heroin refineries found in the Golden Triangle. Domestically, Chinese officials express concern over the increasing number of synthetic drug production operations in their country. Seizures of precursor chemicals in China increased from 50 metric tons in 1991 to 383 metric tons in 1997; only 300 metric tons were seized in 2002.

Drug-related money laundering

In the past money laundering was not considered a significant problem in China. However, with the booming economy promoting greater trade investment and the ever-increasing number of foreign bank branches opening throughout the country, it appears that China may become an emerging money laundering center.

China, however, has taken some initial steps to begin investigation of money laundering activities. An Economic Crimes Investigation Department was established in the Ministry of Public Security to focus on illicit activities. The People's Bank of China (China's central bank) began several structural reforms such as the establishment of two new divisions, the Payment Trade Supervisory Division and the Money Laundering Working Division. The People's Bank of China also prepared guidelines for use by financial institutions to report suspicious transactions, and to sensitize the public about new regulations on money laundering and terrorist financing issues.

Drug abuse and treatment

Drugs of choice

Wholesale drug prices in China (U.S. dollars),
January 2003
Source: DEA Beijing
Drug Location Price
Southeast Asian heroin (price per 1 unit = 700 grams) Guangzhou $18,000
Fuzhou 18,000
Burmese border 5,000
Crystal methamphetamine (price per kilogram) Guangzhou 3,700
Xiamen 4,000
MDMA (price per tablet) Beijing 27-36
Shanghai 27-36
Guangzhou 9
Fuzhou 9

The major drugs of choice are injectable heroin, morphine, smokeable opium, crystal methamphetamine, nimetazepam, temazepam, and MDMA. Preferences between opium and heroin/morphine, and methods of administration, differ from region to region within China. The use of heroin and opium has increased among the younger population, as income has grown and the youth have more free time. China considers crystal methamphetamine abuse second to heroin/morphine as a major drug problem. The use of MDMA has only recently become popular in China's growing urban areas.

The South China Morning Post reports the rise in the use of ketamine, easy to mass-produce in illicit labs in southern China, particularly among the young. Because of its low cost, and low profit margin, drug peddlers rely on mass distribution to make money, thus increasing its penetrative power to all, including schoolchildren. The journal cites social workers saying that four people can get high by sharing just HK$20 worth of ketamine, and estimates 80 per cent of young drug addicts take 'K'.

Addict population

As of 2013, there were 2,475,000 registered drug addicts in China, 1,326,000 of which were addicted to heroin, accounting for 53.6% of the addict population. Some unofficial estimates range as high as 12 million drug addicts. Of the registered drug addicts, 83.7 percent are male and 73.9 percent are under the age of 35.

In 2001, intravenous heroin users accounted for 70.9 percent of the confirmed 22,000 human immunodeficiency virus (HIV) and acquired immune deficiency syndrome (AIDS) cases. Chinese officials are becoming increasingly concerned about the abuse of methamphetamine and other amphetamine-type stimulants.

Treatment and demand reduction programs

Both voluntary and compulsory drug treatment programs are provided in China, although the compulsory treatment is more common. Most addicts who attend these centers do so involuntarily upon orders from the Government. Voluntary treatment is provided at centers operated by Public Health Bureaus, but these programs are more expensive and many people cannot afford to attend them. Addicts who return to drug use after having received treatment, and cannot be cured by other means, may be sentenced to rehabilitation in labor camps for re-education through labor. These centers are run under conditions similar to prisons, including isolation from the outside world, restricted patient movement and a paramilitary routine.

Demand reduction efforts target individuals between the ages of 17 and 35, since this is the largest segment of drug users. These efforts include, but are not limited to, media campaigns and establishment of drug-free communities.

Drug law enforcement agencies and legislation

At the national level, the agencies specifically responsible for the control of legal and illicit drugs are the Ministry of Health, the Ministry of Public Security, and the Customs General Administration. The State Food and Drug Administration oversees implementation of the laws regulating the pharmaceutical industry. In the Customs General Administration, the Smuggling Prevention Department plays the major role in intercepting illegal drug shipments. The Narcotics Control Bureau of the Ministry of Public Security handles all criminal investigations involving opium, heroin, and methamphetamine.

In 1990, the Chinese government set up the National Narcotics Control Commission [zh] (NNCC), composed of 25 departments, including the Ministry of Public Security, Ministry of Health and General Administration of Customs. The NNCC leads the nation's drug control work in a unified way, and is responsible for international drug control cooperation, with an operational agency based in the Ministry of Public Security.

Treaties and conventions

China is a party to the 1988 U.N. Drug Convention, the 1961 U.N. Single Convention on Narcotic Drugs as amended by the 1972 Protocol, and the 1971 U.N. Convention on Psychotropic Substances. China is a member of the International Criminal Police Organization (INTERPOL), and has been a member of the INCB since 1984.

China also participates in a drug control program with Iran, Pakistan, Tajikistan, Turkmenistan, Uzbekistan, Russia, and the United States. This program is designed to enhance information sharing and coordination of drug law enforcement activities by countries in and around the Central Asian Region.

In June 2000, China and the United States signed a Mutual Legal Assistance Agreement (MLAT). This treaty subsequently went into effect on March 8, 2001. In 1999, China and the United States signed a Bilateral Customs Mutual Assistance Agreement. However, this agreement has not yet been activated. A May 1997 United States and China Memorandum of Understanding on law enforcement cooperation allows the two countries to provide assistance on drug investigations and prosecutions on a case-by-case basis.

China has over 30 MLATs with 24 nations covering both civil and criminal matters. In 1996, China signed MLATs that gave specific attention to drug trafficking with Russia, Mexico, and Pakistan. China also signed a drug control cooperation agreement with India.

China and Myanmar continue dialogue on counter-drug issues, such as drug trafficking by the United Wa State Army along the China–Myanmar border. The Government of China encourages and provides assistance for alternative crop programs in Myanmar along the China–Myanmar border. China is also building on Memoranda of Understanding that are currently in place with Myanmar, Cambodia, Laos, Thailand, Vietnam, and the United Nations Office on Drugs and Crime.

History of opium in China

From Wikipedia, the free encyclopedia
https://en.wikipedia.org/wiki/History_of_opium_in_China

The history of opium in China began with the use of opium for medicinal purposes during the 7th century. In the 17th century the practice of mixing opium with tobacco for smoking spread from Southeast Asia, creating a far greater demand.

Imports of opium into China stood at 200 chests annually in 1729, when the first anti-opium edict was promulgated. By the time Chinese authorities reissued the prohibition in starker terms in 1799, the figure had leaped; 4,500 chests were imported in the year 1800. The decade of the 1830s witnessed a rapid rise in opium trade, and by 1838, just before the First Opium War, it had climbed to 40,000 chests. The rise continued on after the Treaty of Nanking (1842) that concluded the war. By 1858 annual imports had risen to 70,000 chests (4,480 long tons (4,550 t)), approximately equivalent to global production of opium for the decade surrounding the year 2000.

By the late 19th century Chinese domestic opium production challenged and then surpassed imports. The 20th century opened with effective campaigns to suppress domestic farming, and in 1907 the British government signed a treaty to eliminate imports. The fall of the Qing dynasty in 1911, however, led to a resurgence in domestic production. The Nationalist Government, provincial governments, the revolutionary base areas of the Chinese Communist Party (CCP), and the British colonial government of Hong Kong all depended on opium taxes as major sources of revenue, as did the Japanese occupation governments during the Second Sino-Japanese War (1937–1945). After 1949, both the respective governments of the People's Republic of China on the mainland and of the Republic of China on Taiwan claimed to have successfully suppressed the widespread growth and use of opium.

Early history

Historical accounts suggest that opium first arrived in China during the Tang dynasty (618–907) as part of the merchandise of Arab traders. Later on, Song Dynasty (960–1279) poet and pharmacologist Su Dongpo recorded the use of opium as a medicinal herb: "Daoists often persuade you to drink the jisu water, but even a child can prepare the yingsu soup."

Initially used by medical practitioners to control bodily fluid and preserve qi or vital force, during the Ming dynasty (1368–1644), the drug also functioned as an aphrodisiac or chunyao (春药) as Xu Boling records in his mid-fifteenth century Yingjing Juan:

It is mainly used to treat masculinity, strengthen sperm, and regain vigour. It enhances the art of alchemists, sex and court ladies. Frequent use helps to cure the chronic diarrhea that causes the loss of energy ... Its price equals that of gold.

Ming rulers obtained opium via the tributary system, when it was known as wuxiang (烏香) or "black spice". The Collected Statutes of the Ming Dynasty record gifts to successive Ming emperors of up to 100 kilograms (220 lb) of wuxiang amongst tribute from the Kingdom of Siam, which also included frankincense, costus root, pepper, ivory, rhino horn and peacock feathers.

First listed as a taxable commodity in 1589, opium remained legal until the end of Ming dynasty, 1637.

Growth of the opium trade

Storage of opium at a British East India Company warehouse in India

In the 16th century the Portuguese became aware of the lucrative medicinal and recreational trade of opium into China, and from their factories across Asia chose to supply the Canton System, to satisfy both the medicinal and the recreational use of the drug. By 1729 the Yongzheng Emperor had criminalised the new recreational smoking of opium in his empire.

Following the 1764 Battle of Buxar, the British East India Company (EIC) became the rulers of Bengal, Bihar, and Orissa. The EIC gained control of tax collection, along with the opium monopoly of the defeated Mughal Empire. The East India Company Act, 1793 formally established this monopoly. The EIC was £28 million in debt as a result of the Indian war, and found it difficult to raise silver to pay for Chinese tea that it sold to the British market, which had to be paid for in silver.

As the textile industry developed in Britain during the Industrial Revolution, the EIC drove Indian farmers out of cotton cultivation and shutting down Indian weaving operations. The EIC encouraged farmers to cultivate opium instead, over time resulting in opium crops far in excess of the demand for medicinal use.

The EIC began auctions of opium in Calcutta to raise revenues. Since importation of opium into China was banned by Chinese law, the EIC established an indirect trading scheme relying partially on legal markets and also leveraging illicit ones. British merchants would first buy tea in Canton (Guangzhou) on credit. They would pay their debts by selling opium at auction in Calcutta. This opium was then transported to the Chinese coast aboard British ships, where it was sold to native merchants who would sell it in China. According to 19th Century sinologist Edward Parker, there were four types of opium smuggled into China from India: kung pan t'ou (公班土, gongban tu or "Patna"); Pak t'ou (白土, bai tu or "Malwa"); Persian, Kem fa t'ou (金花土, jinhua tu) and the "smaller kong pan", which was of a "dearer sort", i.e. more expensive. A description of the cargo aboard Hercules at Lintin in July 1833 distinguished between "new" and "old" Patna, "new" and "old" Benares, and Malwa; the accounting also specifies the number of chests of each type, and the price per chest. The "chests" contained small balls of opium that had originated in the Indian provinces of Bengal and Madras.

In 1797 the EIC further tightened its grip on the opium trade by enforcing direct trade between opium farmers and the British, and ending the role of Bengali purchasing agents. British exports of opium to China grew from an estimated 15 long tons (15,000 kg) in 1730 to 75 long tons (76,000 kg) in 1773 shipped in over two thousand chests. The Jiaqing Emperor issued a decree banning imports of the drug in 1799. While China had trade relations with Britain, in order to balance financial books between the two Britain sold China opium from India which added to availability of opium in China's society. By 1804 the trade deficit had turned into a surplus, leading to seven million silver dollars going to India between 1806 and 1809. Meanwhile, Americans entered the opium trade with less expensive but inferior Turkish opium and by 1810 had around 10% of the trade in Canton. The EIC opium processed in Patna and Benares was supplemented in the 1820s with opium from Malwa in the non-British controlled part of India. Competition drove prices down, but production was stepped up.

Opium smokers c1880 by Lai Afong.

In the same year the Emperor issued a further edict:

Opium has a harm. Opium is a poison, undermining our good customs and morality. Its use is prohibited by law. Now the commoner, Yang, dares to bring it into the Forbidden City. Indeed, he flouts the law! However, recently the purchasers, eaters, and consumers of opium have become numerous. Deceitful merchants buy and sell it to gain profit....If we confine our search for opium to the seaports, we fear the search will not be sufficiently thorough. We should also order the general commandant of the police and police- censors at the five gates to prohibit opium and to search for it at all gates. If they capture any violators, they should immediately punish them and should destroy the opium at once. As to Kwangtung (Guangdong) and Fukien (Fujian), the provinces from which opium comes, we order their viceroys, governors, and superintendents of the maritime customs to conduct a thorough search for opium, and cut off its supply.

The decree had little effect. By Qianlong's time opium had become a mainstream recreation among scholars and officials, and by the 1830s the practice had become widespread in cities. The increase in popularity was a result of both social and economic shifts between the Ming and the Qing dynasties in which there was a boost in commercialization, consumerism, and urbanization of opium within the general public. “Opium,” says one recent scholar, became “leisurely, urban, cultured and a status symbol” as an evidence of wealth, leisure, and culture. The Qing government, far away in Beijing, was unable to halt opium smuggling in the southern provinces. A porous Chinese border and rampant local demand facilitated the trade. By 1838 there were millions of Chinese opium users — opium was the main painkiller in a pre-aspirin age. They were less reliable workers and the silver they sent abroad was hurting the economy. More and more Chinese were smoking British opium as a recreational drug. But for many, what started as recreation soon became a punishing addiction: many people who stopped ingesting opium suffered chills, nausea, and cramps, and sometimes died from withdrawal. Once addicted, people would often do almost anything to continue to get access to the drug. Therefore, the Daoguang Emperor demanded action. Officials at the court who advocated legalizing and taxing the trade were defeated by those who advocated suppressing it. The Emperor sent the leader of the hard line faction, Special Imperial Commissioner Lin Zexu, to Canton, where he quickly arrested Chinese opium dealers and summarily demanded that foreign firms turn over their stocks with no compensation. When they refused, Lin stopped trade altogether and placed the foreign residents under virtual siege in their factories, eventually forcing the merchants to surrender their opium. Lin destroyed the confiscated opium, a total of some 1,000 long tons (1,016 t), a process which took 23 days.

First Opium War

China's crackdown on the use of opium clashed with Britain, which advocated for free trade as British merchants were the source of trading opium into China. In compensation for the opium destroyed by Commissioner Lin, British traders demanded compensation from their home government. This put pressure on India from China as the overwhelming demand for opium was straining as the fixed supply simply no longer reached demands. However, British authorities believed that the Chinese were responsible for payment and sent expeditionary forces from India, which defeated the Qing army and navy in a series of battles and brought China to the negotiating table. The 1842 Treaty of Nanking not only opened the way for further opium trade, but ceded the territory of Hong Kong, unilaterally fixed Chinese tariffs at a low rate, gave Britain most favored nation status and permitted them diplomatic representation. Three million dollars in compensation for debts that the Hong merchants in Canton owed British merchants for the destroyed opium was also to be paid under Article V.

Anglophone capitalists linked their opium trade to the trade in coolie labor, describing them together as "poison and pigs."

Second Opium War

Despite the new ports available for trade under the Treaty of Nanking, by 1854 Britain's imports from China had reached nine times their exports to the country. At the same time British imperial finances came under further pressure from the expense of administering the burgeoning colonies of Hong Kong and Singapore in addition to India. Only the latter's opium could balance the deficit. Along with various complaints about the treatment of British merchants in Chinese ports and the Qing government's refusal to accept further foreign ambassadors, the relatively minor "Arrow Incident" provided the pretext the British needed to expand their opium trade in China.

The Arrow was a merchant lorcha with an expired British registration that the Qing authorities seized for alleged salt smuggling. British authorities complained to the Governor-general of Liangguang, Ye Mingchen, that the seizure breached Article IX of the 1843 Treaty of the Bogue with regard to extraterritoriality. Matters quickly escalated and led to the Second Opium War, sometimes referred to as the "Arrow War" or the "Second Anglo-Chinese War", which broke out in 1856. A number of clashes followed until the war ended with the signature of the Treaty of Tientsin in 1860. Although the new treaty did not expressly legalise opium, it opened a further five ports to trade and for the first time allowed foreign traders access to the vast hinterland of China beyond the coast.

Aftermath of the Opium Wars

The treaties with the British soon led to similar arrangements with the United States and France. These later became known as the Unequal Treaties, while the Opium Wars, according to Chinese historians, represented the start of China's "Century of humiliation".

The opium trade faced intense enmity from the later British Prime Minister William Ewart Gladstone. As a member of Parliament, Gladstone called it "most infamous and atrocious" referring to the opium trade between China and British India in particular. Gladstone was fiercely against both of the Opium Wars and ardently opposed to the British trade in opium to China. He lambasted it as "Palmerston's Opium War" and said that he felt "in dread of the judgments of God upon England for our national iniquity towards China" in May 1840. Gladstone criticized it as "a war more unjust in its origin, a war more calculated in its progress to cover this country with permanent disgrace,". His hostility to opium stemmed from the effects of opium brought upon his sister Helen. Due to the First Opium war brought on by Palmerston, there was initial reluctance to join the government of Peel on part of Gladstone before 1841.

Domestication and suppression in the last decades of the Qing dynasty

Chinese opium smokers c. 1858

Once the turmoil caused by the mid-century Taiping Rebellion died down, the economy came to depend on opium to play several roles. Merchants found the substance useful as a substitute for cash, as it was readily accepted in the interior provinces such as Sichuan and Yunnan while the drug weighed less than the equivalent amount of copper. Since poppies could be grown in almost any soil or weather, cultivation quickly spread. Local officials could then meet their tax quotas by relying on poppy growers even in areas where other crops had not recovered. Although the government continued to require suppression, local officials often merely went through the motions both because of bribery and because they wanted to avoid antagonizing local farmers who depended on this lucrative crop. One official complained that when people heard a government inspector was coming, they would merely pull up a few poppy stalks to spread by the side of the road to give the appearance of complying. A provincial governor observed that opium, once regarded as a poison, was now treated in the same way as tea or rice. In the Qing dynasty all aspects of society had been affected by opium by the 1800s. Recreational use of opium expanded to all areas of China from the urban inland to the rural county sides. It also filtered down from the urban elites and middle class to the lower, working class citizens. By the 1880s, even governors who had initially suppressed opium smoking and poppy production now depended on opium taxes.

China opium den, circa 1896

The historian Jonathan Spence notes that the harm opium caused has long been clear, but that in a stagnating economy, opium supplied fluid capital and created new sources of taxes. Smugglers, poor farmers, coolies, retail merchants and officials all depended on opium for their livelihood. In the last decade of the dynasty, however, a focused moral outrage overcame these vested interests.

I
1908 opium production by province in "piculs." A picul is equal to 133.33 lbs.

When the Qing government launched new opium suppression campaigns after 1901, the opposition no longer came from the British, whose sales had suffered greatly from domestic competition in any case, but from Chinese farmers who would be wiped out by the loss of their most profitable crop-derivative. Further opposition to the government moves came from wholesalers and retailers as well as from the millions of opium users, many of whom came from influential families. The government persevered, creating further dissent amongst the people, and at the same time promoted cooperation with international anti-narcotic agencies. Nevertheless, despite the imposition of new blanket import duties under the 1902 Mackay Treaty, Indian opium remained exempt and taxable at 110 taels per chest with the treaty stating "there was no intention of interfering with China's right to tax native opium".

The International Opium Commission observed that opium smoking was a fashionable, even refined pastime, especially among the young, yet many in society condemned the habit. At this time the act of opium smoking was prevalent among students, soldiers, urban middle class, and wealthier peasants. One of the most influential groups was the sex industry that dominated the scene as the combination of both opium smoking and sex was the favoured pastime. In 1907 Great Britain signed a treaty agreeing to gradually eliminate opium exports to China over the next decade while China agreed to eliminate domestic production over that period. Estimates of domestic production fell from 35,000 metric tons (34,000 long tons) in 1906 to 4,000 metric tons (3,900 long tons) in 1911.

Republican China

The combination of foreign and domestic efforts proved largely successful, but the fall of the Qing government in 1911 effectively meant the end of the anti-opium campaign. Local and provincial governments quickly turned back to opium as a source of revenue, and foreign governments no longer felt obliged to continue their efforts to eliminate the trade.

Opium Smokers in illegal den, Beijing (1932)

In the northern provinces of Ningxia and Suiyuan in China, Chinese Muslim General Ma Fuxiang both prohibited and engaged in the opium trade. It was hoped that Ma Fuxiang would have improved the situation, since Chinese Muslims were well known for opposition to smoking opium. Ma Fuxiang officially prohibited opium and made it illegal in Ningxia, but the Guominjun reversed his policy; by 1933, people from every level of society were abusing the drug, and Ningxia was left in destitution. In 1923, an officer of the Bank of China from Baotou found out that Ma Fuxiang was assisting the drug trade in opium which helped finance his military expenses. He earned $2 million from taxing those sales in 1923. General Ma had been using the bank, a branch of the Government of China's exchequer, to arrange for silver currency to be transported to Baotou to use it to sponsor the trade.

The Nationalist Government under General Chiang Kai Shek during the Nanjing Decade (1928- 1937) followed contradictory opium policies. Chiang himself was morally opposed to opium use, but other government ministers saw opium as a source of much needed revenue. The government first attempted to reform the people into proper citizens to conform to the modern standards, then raised the official price, which discouraged a certain number of people, then sometimes shot the recidivists (strangely about one per county). Chiang also turned to the Green Gang mob boss Du Yuesheng to head the Shanghai Opium Suppression Bureau. Remarked one American diplomat, "the real motive appears to be to increase revenues by drawing within the orbit of the Opium Suppression Bureau the opium traffic in the Settlement and French Concessions." Prohibition, that is, was a guise to extend the government opium monopoly. "Suppression" officials talked openly of their duty to realize more opium revenue for the government.

During the Second Sino-Japanese War, to raise funds, the CCP in the Shaan-Gan-Ning Border Region cultivated and taxed opium (alias "特货", lit 'special good') production and dealing, selling to Japanese-occupied and Kuomintang provinces. By 1945, opium taxes generated over 40 percent of the CCP's revenue. According to Jonathan Marshall, Chongqing also regard opium as a key commodity in the smuggling from KMT controlled zone including Sichuan and Yunnan to Japanese occupied zone for compensating urgent government expeditions and military costing during protracted war era. To raise necessary revenue, Chongqing also permitted Shanghai Green Gang leader Du Yuesheng possessing many connections with Japanese controlled territory to manage opium smuggling business. Du's operation was under general Taili who took charge of anti-smuggling bureau's supervision.

Under Mao

The Mao Zedong government is generally credited with eradicating both consumption and production of opium during the 1950s using unrestrained repression and social reform. Ten million addicts were forced into compulsory treatment, dealers were executed, and opium-producing regions were planted with new crops. Remaining opium production shifted south of the Chinese border into the Golden Triangle region. The remnant opium trade primarily served Southeast Asia, but spread to American soldiers during the Vietnam War, with 20 percent of soldiers regarding themselves as addicted during the peak of the epidemic in 1971. In 2003, China was estimated to have four million regular drug users and one million registered drug addicts.

Lie group

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Lie_group In mathematics , a Lie gro...