Methcathinone chemical structure
Find information on thousands of medical conditions and prescription drugs.

Methcathinone

Methcathinone is an addictive recreational drug that is cheap and simple to synthesize. It is usually snorted, but can be smoked, injected, or taken orally. Methcathinone is currently a DEA Schedule I chemical. more...

Home
Diseases
Medicines
A
B
C
D
E
F
G
H
I
J
K
L
M
Macrodantin
Maprotiline
Marcaine
Marezine
Marijuana
Marinol
Marplan
Matulane
Maxair
Maxalt
Maxolon
MDMA
Measurin
Mebendazole
Mebendazole
Meclofenoxate
Medrol
Mefenamic acid
Mefloquine
Melagatran
Melarsoprol
Meloxicam
Melphalan
Memantine
Metadate
Metamfetamine
Metamizole sodium
Metandienone
Metaxalone
Metenolone
Metformin
Methadone
Methamphetamine
Methaqualone
Metharbital
Methcathinone
Methenamine
Methionine
Methocarbamol
Methohexital
Methotrexate
Methotrexate
Methoxsalen
Methylcellulose
Methyldopa
Methylergometrine
Methylin
Methylphenidate
Methylphenobarbital
Methylprednisolone
Methyltestosterone
Methysergide
Metiamide
Metoclopramide
Metohexal
Metoprolol
Metrogel
Metronidazole
Metyrapone
Mobic
Moclobemide
Modafinil
Modicon
Monopril
Montelukast
Motrin
Moxidectin
Moxifloxacin
Moxonidine
MS Contin
Mucinex
Mucomyst
Mupirocin
Mupirocin
Muse
Mycitracin
Mycostatin
Myfortic
Mykacet
Mykinac
Myleran
Mylotarg
Mysoline
Phentermine
N
O
P
Q
R
S
T
U
V
W
X
Y
Z

History

Methcathinone was first synthesized in Germany in 1928. It was used in the Soviet Union during the 1930s and 1940s as an anti-depressant. Since the 1960s, methcathinone has been used as a recreational drug in the Soviet Union.

Circa 1994, the United States government informed the UN Secretary-General of its opinion that methcathinone should be added to Schedule I of the Convention on Psychotropic Substances.

Chemistry

Methcathinone is very similar in structure to cathinone, a stimulant alkaloid occurring in the shrub Catha edulis (Khat), the synthetic stimulant methamphetamine, and other phenethylamines.

Methcathinone has a single asymmetric carbon atom, thus yielding enantiomeric + and - forms. Chemical Abstract Services registry numbers for the racemic base and hydrochloride forms are 5650-44-2 and 49656-78-2, respectively. The Chemical Abstract Services registry numbers for the base and hydrochloride forms of the S absolute stereochemical configuration are 112117-24-5 and 66514-93-0, respectively.

Various names for methcathinone include:

  • 2-(methylamino)-propiophenone
  • α-methylamino-propiophenone
  • α-N-methyl-aminopropiophenone
  • 2-(methylamino)-1-phenylpropan-1-one
  • N-methylcathinone
  • N-monomethylcathinone
  • Methylcathinone
  • AL-464 (L isomer)
  • AL-422 (racemate)
  • AL-463 (D-isomer)
  • UR1431
  • UR(W)1431

Methcathinone hydrochloride increases spontaneous rodent locomotor activity, potentiates the release of radio-labelled dopamine from dopaminergic nerve terminals in the brain, and causes appetite suppression.

Methcathinone is most commonly made by the oxidation of ephedrine. Oxidation of ephedrine to methcathinone requires almost zero chemistry experience, making it easy to synthesize. Potassium permanganate (KMnO4) is most the commonly used as the oxidant.

Methcathinone can also be synthesized via the oxidation of l-ephedrine using sodium dichromate and sulfuric acid. This process is just as simple as oxidizing the ephedrine with potassium permanganate.

Synthesizing methcathinone from either potassium permanganate or various chromates is considered undesirable because of the low yields. A method that yields more methcathinone is oxidizing ephedrine with sodium hypochlorite.

Methcathinone acts on the body & brain much like methamphetamine & amphetamine do.

Effects

The effects of methcathinone are similar to those of methamphetamine, but generally less intense, and often more euphoric. The effects have been compared to those of cocaine, since it commonly causes hypertension (elevated blood pressure) and tachycardia (elevated heart rate). Reported effects include:

Read more at Wikipedia.org


[List your site here Free!]


They're synthetic. They're clandestine. They can heal. They can kill - amphetamine-type stimulants
From UN Chronicle, 6/22/98 by Sandeep Chawla

The ancient Greek word pharmakon meant both medicine and poison. It was the quantity, dose and pattern of use which determined the difference between one and the other, between use and abuse, recalls Sandeep Chawla, Senior Research Coordinator, UNDCP, in this contribution to the Chronicle.

Today, astonishing changes, many of them largely unnoticed, are taking place in the grey world of drag trafficking and abuse. The most significant of these is probably the emergence of clandestine synthetic drugs as a global problem. Recognition of this problem has long been delayed by control systems, national and international, which are mesmerized by the three "classical", botanical drugs: cocaine, heroin and cannabis. Present debates about the validity of controlling cannabis under the same strict regime as cocaine and heroin continue to divert attention from tackling the problem of clandestine synthetic drugs.

Another source of difficulty is the sheer complexity of the synthetic drug problem. Psychoactive drugs - drugs whose pharmacological effect is on the central nervous system (CNS) of the body - have been around for millennia: opium, coca leaf, betel nuts, even tea. They have always had a dual nature and switchback quality. They could be used medicinally, or they could be poisonous or toxic. The development of science and technology gradually perpetuated this duality. The effects of the drug, which were sought by the abuser, were precisely those which were treated as unwanted side-effects in medicine. Pharmaceutical research on CNS-active drugs was thus set on the path of finding ever greater benefit-to-risk ratios - effort to separate the desirable (therapeutic) effects from the undesirable (addictive) side-effects.

Starting from the nineteenth century, when the active ingredients of many plants were chemically isolated or extracted - for example morphine, caffeine, ephedrine and cocaine - a more complex category of semi-synthetic drags was created. These were still, however, based on the chemical and pharmacological models of the old natural drugs, which were the essential raw material. Only at the end of the nineteenth and the early twentieth centuries did a class of fully synthetic drugs emerge. These are substances which have no counterpart in nature and can be produced in unlimited amounts from readily available chemicals. Many of these drugs were designed as structural modifications of naturally occurring drugs, with similar though more specific or enhanced therapeutic effects.

Technological progress, allowing for the use of refined natural products or purely synthetic substances, was clearly a milestone in modern medicine. Yet the duality of the drug problem was still in evidence. A new era in the abuse of psychoactive drugs began. This implies the use of potent and pure substances instead of the plant material which contains the active ingredient together with other compounds - the distinctions, for example, between heroin and opium, or cocaine and the coca leaf. Or, as examples of fully synthetic drugs, amphetamine and methamphetamine, which have no botanical raw material, yet substitute the CNS-stimulant effect of cocaine. Another characteristic of the new era of drug abuse is the shift from instrumental use to recreational use. The former means the use of pharmaceutical products as a means to an end, such as medication or improving occupational performance. Recreational use means use as an end in itself, aimed exclusively at experiencing the pharmacological effects of the drags. As recreational use grows, the next stage is obviously the appearance on illicit markets of new drugs with no therapeutic use, designed exclusively for psychoactive mind-altering purposes.

Among the bewildering array of synthetic drugs available in illicit markets, the most common are probably a group of CNS-stimulants which share the basic chemical structure of amphetamine. They are consequently known as amphetamine-type stimulants (ATS) and provide a test case to illustrate the problem of synthetic drugs, of how to control them and how the shift from licit manufacture and use to illicit synthesis and abuse takes place.

ATS include two subgroups with slightly different pharmacological properties: the amphetamine group and the ecstasy group. The former includes amphetamine, methamphetamine and methcathinone. Most of them were developed as therapeutic drugs: amphetamine in 1887; methamphetamine in 1919. They began to appear in pharmaceutical markets in the 1930s. Their therapeutic utility was over-rated, primarily because they not only enhanced performance and endurance, but also had an anorectic (weight-losing) effect. They were widely used among combatants in both sides during the Second World War. Oversupply from licit sources created the first amphetamine epidemics after the war. The risks and addictive potential gradually became evident, and the amphetamine group now has few legitimate medical uses: for narcolepsy, obesity and attention deficit disorder. Illicit manufacture has meanwhile swollen to fulfil expanding demand.

The substance known commonly as "ecstasy" (MDMA) has given its name to a whole range of related substances. They are sometimes called the hallucinogenic amphetamines because, in addition to the CNS-stimulant effect, they produce effects of empathy, loquacity and serenity. MDMA was synthesized in 1914, but not used until the 1970s when its capacity to foster inter-personal communication gave it some uses in psychotherapy. Its dangerous potential was only recognized in the mid- 1980s, by when its abuse had spread widely, closely tied to the dance and "rave" subculture. It was then put under stringent international control.

Growth rates through the 1990s in the manufacture, trafficking and abuse of ATS have even surpassed those of heroin and cocaine. The challenges posed by ATS can be seen in at least four areas. First, the expanding demand for them. The need for stimulants in a modern performance-oriented society is self-evident. Their recreational use, particularly of the ecstasy group, is expanding among younger sections of the population. Patterns of use, and even the drugs themselves, are quite different from the "classical" drugs, and their image is simultaneously benign and modern in comparison.

Secondly, the information age exacerbates the problem. Modern information technology has expanded public access to information on recipes and techniques for clandestine manufacture: what precursor chemicals to use; where they are available; what techniques can be used to evade control; and how one might set up a simple "kitchen lab" in one's backyard.

Thirdly; ATS have a double supply system: diversions from licit pharmaceutical trade or licit trade in chemicals, as well as illicit manufacture. Controlling the supply of synthetic drugs is difficult, because there are neither any easily identifiable botanical raw materials to target nor any long trafficking mutes linking production and consumption areas to interdict. Clandestine ATS are usually made from precursor chemicals, in or close to the area of final consumption. The precursor control regime is still young, since it only began with the 1988 Convention against Illicit Traffic in Narcotic Drugs and Psychotropic Substances. In any case, it is not feasible to put all possible precursors for ATS under international control because they have a vast amount of licit industrial uses.

Finally, the present control system - the 1971 Convention on Psychotropic Substances - is simply inadequate for controlling illicit markets. It was developed to resolve the dilemma of duality discussed above: to distinguish between the therapeutic potential and public health risk of particular drugs, which were put into a sliding scale of four schedules, with those in Schedule I having the highest public health risk, and those in Schedule IV having the greatest therapeutic potential. But the scheduling process is slow and cumbersome; individual substances, rather than chemically or pharmacologically-related classes of drugs, are put under control. New individual substances with no therapeutic potential, structurally different though pharmacologically similar (the ATS "analogues"), perpetually appear on illicit markets. They cannot be scheduled fast enough. The control regime is thus bound to lag behind illicit innovation.

These four challenges - demand, information, supply and control system - are now at the heart of an international Action Plan against the Manufacture, Trafficking and Abuse of ATS. Representing the culmination of an applied research process which began at the United Nations International Drug Control Programme (UNDCP) in 1996 and went through scientific study and investigation, expert consultations and political negotiation in the Commission on Narcotic Drugs, the Action Plan will go before the Special Session of the General Assembly in June 1998. If adopted, it will provide the nuts and bolts of a strategy to tackle the most serious drug problem of the next century.

Fact: In recent years, the amount of stimulants, sedatives and hypnotics diverted into illicit channels has totalled several tonnes, representing hundreds of millions of tablets - or street doses.

COPYRIGHT 1998 United Nations Publications
COPYRIGHT 2004 Gale Group

Return to Methcathinone
Home Contact Resources Exchange Links ebay