γ-Hydroxybutyric acid Systematic (IUPAC) name 4-Hydroxybutanoic acid Clinical data Pregnancy cat. B Legal status Prohibited (S9) (AU) Schedule III (CA) ? (UK) Class B ( NZ), Schedule I and III (US) Routes Usually oral; intravenous Pharmacokinetic data Bioavailability 25% (oral) Metabolism 95%, mainly Hepatic, also in blood and tissues Half-life 30–60 minutes Excretion 5%, renal Identifiers CAS number ATC code N01 N07 PubChem DrugBank ChemSpider UNII KEGG ChEBI ChEMBL Synonyms γ-Hydroxybutyric acid
Chemical data Formula C4H8O3 Mol. mass 104.10 g/mol (GHB)
126.09 g/mol (sodium salt)
142.19 g/mol (potassium salt)
SMILES & (what is this?)
γ-Hydroxybutyric acid (GHB), also known as 4-hydroxybutanoic acid and sodium oxybate (INN) when used for medicinal purposes, is a naturally occurring substance found in the central nervous system, wine, beef, small citrus fruits, and almost all animals in small amounts. It is also categorized as an illegal drug in many countries. It is currently regulated in Australia and New Zealand, Canada, most of Europe and in the US. GHB as the sodium salt, known as sodium oxybate, is sold by Jazz Pharmaceuticals under the name Xyrem to treat cataplexy and excessive daytime sleepiness in patients with narcolepsy.
GHB has been used in a medical setting as a general anesthetic, to treat conditions such as insomnia, clinical depression, narcolepsy, and alcoholism, and to improve athletic performance. It is also used as an intoxicant (illegally in many jurisdictions) or as a date rape drug. GHB is naturally produced in the human body's cells and is structurally related to the ketone body beta-hydroxybutyrate. As a supplement/drug, it is used most commonly in the form of a salt, for example sodium gamma-hydroxybutyrate (Na.GHB, sodium oxybate) or potassium gamma-hydroxybutyrate (K.GHB, potassium oxybate). GHB is also produced as a result of fermentation, and so is found in small quantities in some beers and wines. Succinic semialdehyde dehydrogenase deficiency is a disease that causes GHB to accumulate in the blood.
- 1 Medical use
- 2 Recreational use
- 3 Adverse effects
- 4 Endogenous production
- 5 Natural fermentation by-product
- 6 Pharmacology
- 7 History
- 8 Legal status
- 9 See also
- 10 References
- 11 External links
GHB is the active ingredient in a prescription medication called Xyrem (sodium oxybate). Xyrem is approved by the U.S. Food and Drug Administration (FDA) for the treatment of cataplexy associated with narcolepsy  and Excessive Daytime Sleepiness (EDS) associated with narcolepsy .
GHB is a CNS depressant used as an intoxicant. It has many street names, including "Georgia Home Boy", "Liquid Ecstasy", "Mils", "G", "Liquid X", and "Liquid G", as well as "Fantasy" and the reordered initialism GBH. Its effects have been described anecdotally as comparable to alcohol and ecstasy use, such as euphoria, disinhibition, enhanced sensuality and empathogenesis. At higher doses, GHB may induce nausea, dizziness, drowsiness, agitation, visual disturbances, depressed breathing, amnesia, unconsciousness, and death. The effects of GHB can last from 1.5 to 3 hours, or even longer if large doses have been consumed or if it is mixed with alcohol.
In general, the doses used recreationally are between 500 mg and 3,000 mg. When used as a recreational drug, GHB may be found as the sodium or potassium salt, which is a white crystalline powder, or as GHB salt dissolved in water to form a clear solution. The sodium salt of GHB has a salty taste. Other salt forms such as calcium GHB and magnesium GHB have also been reported, but the sodium salt is by far the most common.
Some chemicals convert to GHB in the stomach and blood stream. GBL, or gamma-butyrolactone, is one such prodrug. Other prodrugs include 1,4-butanediol. There may be additional toxicity concerns with these precursors. 1,4-B and GBL are normally found as pure liquids, although they may be mixed with other more harmful solvents when intended for industrial use, e.g., as paint stripper or varnish thinner.
GHB can be produced in clandestine labs, and it is claimed that most of the GHB used in the U.S. is illegally manufactured within its borders. While available as a prescription for sleep disorders in some other countries, GHB was banned (in the U.S.) by the FDA in 1990. However, on 17 July 2002, GHB was approved for treatment of cataplexy, often associated with narcolepsy. GHB is "colourless and odorless".
Club scene or "rave"
GHB is taken because users feel that it enhances the experience of being in a club or at a party; small doses of GHB are thought to act as a stimulant and aphrodisiac. GHB is sometimes referred to as G, liquid ecstasy, liquid X, or liquid E due to its tendency to produce euphoria and sociability and its use in the dance party scene. Despite this nickname, GHB has entirely separate chemical and pharmacological modes of action compared to ecstasy.
The drug has been identified as a date rape drug, much the same way as alcohol and potent benzodiazepines such as Rohypnol, the trade name of a potent hypnotic benzodiazepine, flunitrazepam. It has a salty taste but, as it is colourless and odorless, it has been described as "very easy to add to drinks" that mask the flavor. GHB has been used in cases of drug-related sexual assault, usually when the victim is vulnerable due to intoxication with a sedative, generally alcohol. However it is difficult to establish how often GHB is used to facilitate rape as it is difficult to detect in a urine sample after a day, and many victims may not recall the rape until some time after this.
GHB, produced as a sodium salt (sodium oxybate), may provide a noticeable salty character to the drink, although individual sensitivity to the taste of salt varies. GHB can also be produced as different salts, some of which may not have a taste as distinctive as the sodium salt (e.g., magnesium oxybate), or much less commonly in the unstable free-acid form.
Sports and athletics
Some athletes also use GHB, as GHB has been shown to elevate human growth hormone in vivo. The growth hormone elevating effects of GHB are mediated through muscarinic acetylcholine receptors and can be prevented by prior administration of pirenzepine, a muscarinic acetylcholine receptor blocking agent.
As certain succinate salts have been shown to elevate growth hormone in vitro, and because GHB is metabolized into succinate some people have suggested this may play a role in the growth hormone elevations from GHB. There is however currently no evidence to show that succinate plays any role in the growth hormone elevations from GHB.
GHB has been common in the professional wrestling industry as well, with several deaths of former wrestlers informally linked to the drug.
Combination with alcohol
In humans, GHB has been shown to inhibit the elimination rate of alcohol. This may explain the respiratory arrest that has been reported after ingestion of both drugs. A review of the details of 194 deaths attributed to or related to GHB over a ten-year period found that most were from respiratory depression caused by interaction with alcohol or other drugs.
One report has suggested that Xyrem (pharmaceutical GHB, or "Sodium Oxybate") overdose may be fatal, based on deaths of three patients who had been prescribed the drug. However, for two of the three cases, post-mortem GHB concentrations were 141 and 110 mg/L, which is within the expected range of concentrations for GHB after death, and the third case was a patient with a history of intentional drug overdose.
One publication has investigated 226 deaths attributed to GHB. Of 226 deaths included, 213 suffered cardiorespiratory arrest and 13 suffered fatal accidents. Seventy-one deaths (34%) had no co-intoxicants. Postmortem blood GHB was 18–4400 mg/L (median=347) in deaths negative for co-intoxicants.
GHB is produced in the body in very small amounts, and blood levels may climb after death to levels in the range of 30–50 mg/L. Levels higher than this are found in GHB deaths. Levels lower than this may be due to GHB or to postmortem endogenous elevations.
A UK parliamentary committee commissioned report found the use of GHB to be less dangerous than tobacco and alcohol in social harms, physical harm and addiction.
Treatment of overdose
Overdose of GHB can be difficult to treat because of its multiple effects on the body. GHB tends to cause rapid unconsciousness at doses above 3500 mg, with single doses over 7000 mg often causing life-threatening respiratory depression, and higher doses still inducing bradycardia and cardiac arrest. Other side-effects include convulsions (especially when combined with stimulants), and nausea/vomiting (especially when combined with alcohol).
The greatest life threat due to GHB overdose (with or without other substances) is respiratory arrest. Other relatively common causes of death due to GHB ingestion include aspiration of vomitus, positional asphyxia, and trauma sustained while intoxicated (e.g., motor vehicle accidents while driving under the influence of GHB). The risk of aspiration pneumonia and positional asphyxia risk can be reduced by laying the patient down in the recovery position. People are most likely to vomit as they become unconscious, and as they wake up. It is important to keep the patient/friend awake and moving, plus do not allow them to be alone as death through vomiting can easily happen. Frequently they will be in a good mood but this does not mean they are not in danger. GHB overdose is a medical emergency and immediate assessment in an emergency department is needed.
Convulsions from GHB can be treated with diazepam or lorazepam, even though these are also CNS depressants they are GABAA agonists, whereas GHB is primarily a GABAB agonist, so the benzodiazepines do not worsen CNS depression as much as might be expected.
Most stimulants are not effective at counteracting the unconsciousness from GHB.
Because of the faster and more complete absorption of GBL relative to GHB, its dose-response curve is steeper, and overdoses of GBL tend to be more dangerous and problematic than overdoses involving only GHB or 1,4-B. Any GHB/GBL overdose is a medical emergency and should be cared for by appropriately trained personnel.
A newer synthetic drug SCH-50911, which acts as a selective GABAB antagonist, quickly reverses GHB overdose in mice. However this treatment has yet to be tried in humans, and it is unlikely that it will be researched for this purpose in humans due to the illegal nature of clinical trials of GHB, and the lack of medical indemnity coverage inherent in using an untested treatment for a life-threatening overdose.[original research?]
Detection of use
GHB may be quantitated in blood or plasma to confirm a diagnosis of poisoning in hospitalized patients, provide evidence in an impaired driving arrest or to assist in a medicolegal death investigation. Blood or plasma GHB concentrations are usually in a range of 50–250 mg/L in persons receiving the drug therapeutically (during general anesthesia), 30–100 mg/L in those arrested for impaired driving, 50–500 mg/L in acutely intoxicated patients and 100–1000 mg/L in victims of fatal overdosage. Urine is often the preferred specimen for routine drug abuse monitoring purposes. Both gamma-butyrolactone (GBL) and 1,4-butanediol are converted to GHB in the body.
In multiple studies, GHB has been found to impair spatial and working learning and memory in rats with chronic administration. These effects are associated with decreased NMDA receptor expression in the cerebral cortex and possibly other areas as well.
Pedraza et al. (2009) found that repeated administration of GHB to rats for 15 days drastically reduced the number of neurons and non-neuronal cells in the CA1 region of the hippocampus and in the prefrontal cortex. With doses of 10 mg/kg of GHB, they were decreased by 61% in the CA1 region and 32% in the prefrontal cortex, and with 100 mg/kg, they were decreased by 38% and 9%, respectively. It is interesting to note that GHB has biphasic effects on neuronal loss, with lower doses (10 mg/kg) producing the most neurotoxicity, and higher doses (100 mg/kg) producing less.
Pretreatment with NCS-382, a GHB receptor antagonist, prevents both learning/memory deficits and neuronal loss in GHB-treated animals, suggesting that GHB's neurotoxic actions are mediated via activation of the GHB receptor. In addition, the neurotoxicity appears to be caused by oxidative stress.
Although there have been reported fatalities due to GHB withdrawal, reports are inconclusive and further research is needed. Addiction occurs when repeated drug use disrupts the normal balance of brain circuits that control rewards, memory and cognition, ultimately leading to compulsive drug taking.
Colombo reports that rats forced to consume massive doses of GHB will intermittently prefer GHB solution to water, but notes that "no rat showed any sign of withdrawal when GHB was finally removed at the end of the 20-week period" or during periods of voluntary abstinence.
GHB has also been associated with a withdrawal syndrome of insomnia, anxiety, and tremor that usually resolves within three to twelve days. Treatment with benzodiazepines can be used, although extremely high doses may be required (e.g. > 100 mg/d of diazepam). With the exception of baclofen, other treatments are often ineffective. Evidence shows that baclofen is the most effective drug for GHB withdrawal. GHB and baclofen are agonists for the GABAb receptor. Benzodiazepines do not affect GABAB receptors and thus have no cross-tolerance with GHB; baclofen which works via GABAB receptors is cross-tolerant with GHB and is effective in alleviating withdrawal effects of GHB. Thus baclofen can be used to substitute for GHB and gradually titrated to reduce withdrawal severity.
GHB withdrawal is not widely discussed in text books and as a result most psychiatrists, general practitioners, and even hospital emergency physicians are not familiar with this withdrawal syndrome.
Cells produce GHB by reduction of succinic semialdehyde via the enzyme succinic semialdehyde dehydrogenase. This enzyme appears to be induced by cAMP levels, meaning substances that elevate cAMP, such as forskolin and vinpocetine, may increase GHB synthesis and release. People with the disorder known as succinic semialdehyde dehydrogenase deficiency, also known as gamma-hydroxybutyric aciduria, have elevated levels of GHB in their urine, blood plasma and cerebrospinal fluid.
The precise function of GHB in the body is not clear. It is known, however, that the brain expresses a large amount of receptors that are activated by GHB. These receptors are excitatory and not responsible for the sedative effects of GHB - they have been shown to elevate the principle excitatory neurotransmitter—glutamate. The benzamide antipsychotics—amisulpride, sulpiride—have been shown to bind to this receptor in vivo. Other antipsychotics were tested and were not found to have an affinity for this receptor.
Natural fermentation by-product
GHB is also produced as a result of fermentation and so is found in small quantities in some beers and wines, in particular fruit wines. However, the amount of GHB found in wine is insignificant and not sufficient to produce any effects.
GHB has at least two distinct binding sites in the central nervous system. GHB is an agonist at the newly characterized GHB receptor, which is excitatory, and it is a weak agonist at the GABAB receptor, which is inhibitory. GHB is a naturally occurring substance that acts in a similar fashion to some neurotransmitters in the mammalian brain. GHB is probably synthesized from GABA in GABAergic neurons, and released when the neurons fire.
If taken orally, GABA itself does not effectively cross the blood-brain-barrier.
GHB induces the accumulation of either a derivative of tryptophan or tryptophan itself in the extracellular space, possibly by increasing tryptophan transport across the blood-brain barrier. The blood content of certain neutral amino-acids, including tryptophan, is also increased by peripheral GHB administration. GHB-induced stimulation of tissue serotonin turnover may be due to an increase in tryptophan transport to the brain and in its uptake by serotonergic cells. As the serotonergic system may be involved in the regulation of sleep, mood, and anxiety, the stimulation of this system by high doses of GHB may be involved in certain neuropharmacological events induced by GHB administration.
However, at therapeutic doses, GHB reaches much higher concentrations in the brain and activates GABAB receptors, which are primarily responsible for its sedative effects. GHB's sedative effects are blocked by GABAB antagonists.
The role of the GHB receptor in the behavioural effects induced by GHB is more complex. GHB receptors are densely expressed in many areas of the brain, including the cortex and hippocampus, and these are the receptors that GHB displays the highest affinity for. There has been somewhat limited research into the GHB receptor; however, there is evidence that activation of the GHB receptor in some brain areas results in the release of glutamate, the principal excitatory neurotransmitter. Drugs that selectively activate the GHB receptor cause absence seizures in high doses, as do GHB and GABA(B) agonists.
Activation of both the GHB receptor and GABA(B) is responsible for the addictive profile of GHB. GHB's effect on dopamine release is biphasic. Low concentrations stimulate dopamine release via the GHB receptor. Higher concentrations inhibit dopamine release via GABA(B) receptors as do other GABA(B) agonists such as baclofen and phenibut. After an initial phase of inhibition, dopamine release is then increased via the GHB receptor. Both the inhibition and increase of dopamine release by GHB are inhibited by opioid antagonists such as naloxone and naltrexone. Dynorphin may play a role in the inhibition of dopamine release via kappa opioid receptors.
This explains the paradoxical mix of sedative and stimulatory properties of GHB, as well as the so-called "rebound" effect, experienced by individuals using GHB as a sleeping agent, wherein they awake suddenly after several hours of GHB-induced deep sleep. That is to say that, over time, the concentration of GHB in the system decreases below the threshold for significant GABAB receptor activation and activates predominantly the GHB receptor, leading to wakefulness.
Recently, analogs of GHB, such as 4-hydroxy-4-methylpentanoic acid have been synthesised and tested on animals, in order to gain a better understanding of GHB's mode of action. Analogues of GHB such as 3-methyl-GHB, 4-methyl-GHB and 4-phenyl-GHB have been shown to produce similar effects to GHB in some animal studies, but these compounds are even less well researched than GHB itself. Of these analogues, only 4-methyl-GHB (γ-hydroxyvaleric acid, GHV) and its prodrug form gamma-valerolactone (GVL) have been reported as drugs of abuse in humans, and on the available evidence seem to be less potent but more toxic than GHB, with a particular tendency to cause nausea and vomiting.
Other prodrug ester forms of GHB have also rarely been encountered by law enforcement, including 1,4-diacetoxybutane, methyl-4-acetoxybutanoate, and ethyl-4-acetoxybutanoate, but these are, in general, covered by analogue laws in jurisdictions where GHB is illegal, and little is known about them beyond their delayed onset and longer duration of action. The intermediate compound 4-hydroxybutaldehyde is also a prodrug for GHB; however, as with all aldehydes this compound is caustic and is strong-smelling and foul-tasting; actual use of this compound as an intoxicant is likely to be unpleasant and result in severe nausea and vomiting.
Also note that both of the metabolic breakdown pathways shown for GHB can run in either direction, depending on the concentrations of the substances involved, so the body can make its own GHB either from GABA or from succinic semialdehyde. Under normal physiological conditions, the concentration of GHB in the body is rather low, and the pathways would run in the reverse direction to what is shown here to produce endogenous GHB. However, when GHB is consumed for recreational or health promotion purposes, its concentration in the body is much higher than normal, which changes the enzyme kinetics so that these pathways operate to metabolise GHB rather than producing it.
Synthesis of the chemical GHB was first reported in 1874 by Alexander Zaytsev, but the first major research into its use in humans was conducted in the early 1960s by Dr. Henri Laborit to use in studying the neurotransmitter GABA. It quickly found a wide range of uses due to its minimal side-effects and short duration of action, the only difficulties being the narrow therapeutic dosage range and the dangers presented by its combination with alcohol and other nervous system depressants.
GHB was widely used in France, Italy, and other European countries for several decades as a sleeping agent and an anesthetic in childbirth but problems with its abuse potential and development of newer drugs have led to a decrease in legitimate medical use of GHB in recent times. In the Netherlands, GHB could be bought as aphrodisiac and euphoriant in a smartshop for several years, until several incidents caused it to become regulated. The only common medical applications for GHB today are in the treatment of narcolepsy and more rarely alcoholism. In the typical scenario, GHB has been synthesized from γ-butyrolactone (GBL) by adding sodium hydroxide (lye) in ethanol or water.
A popular children's toy, Bindeez (also known as Aqua Dots, in the United States), produced by Melbourne company Moose, was banned in Australia in early November 2007 when it was discovered that 1,4-butanediol (1,4-B), which is metabolized into GHB, had been substituted for the non-toxic plasticiser 1,5-pentanediol in the bead manufacturing process. Three young children were hospitalized as a result of ingesting a large number of the beads, and the toy was recalled.
In the United States, it was placed on Schedule I of the Controlled Substances Act in March 2000. However, when sold as Xyrem, it is considered a Schedule III substance but with Schedule I trafficking penalties, one of several drugs that are listed in multiple schedules.  On 20 March 2001, the Commission on Narcotic Drugs placed GHB in Schedule IV of the 1971 Convention on Psychotropic Substances. In the UK it was made a class C drug in June 2003.
In Hong Kong, GHB is regulated under Schedule 1 of Hong Kong's Chapter 134 Dangerous Drugs Ordinance. It can only be used legally by health professionals and for university research purposes. The substance can be given by pharmacists under a prescription. Anyone who supplies the substance without prescription can be fined HK$10000. The penalty for trafficking or manufacturing the substance is a HK$5,000,000 fine and life imprisonment. Possession of the substance for consumption without license from the Department of Health is illegal with a HK$1,000,000 fine and/or 7 years of jail time.
In New Zealand and Australia, GHB, 1,4-B and GBL are all Class B illegal drugs, along with any possible esters, ethers and aldehydes. GABA itself is also listed as an illegal drug in these jurisdictions, which seems unusual given its failure to cross the blood-brain barrier, but there was a perception among legislators that all known analogues should be covered as far as this was possible. Attempts to circumvent the illegal status of GHB have led to the sale of derivatives such as 4-methyl-GHB (gamma-hydroxyvaleric acid, GHV) and its prodrug form gamma-valerolactone (GVL), but these are also covered under the law by virtue of their being "substantially similar" to GHB or GBL and; so importation, sale, possession and use of these compounds is also considered to be illegal.
- 1,4-Butanediol (1,4-BD)
- gamma-Butyrolactone (GBL)
- gamma-Hydroxyvaleric acid (GHV)
- gamma-Valerolactone (GVL)
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- The Cognitive Enhancement Research Institute - Research findings on GHB and other substances
- EMCDDA Report on the risk assessment of GHB in the framework of the joint action on new synthetic drugs
- Erowid GHB Vault (also contains information about addiction and dangers)
- InfoFacts - Rohypnol and GHB (National Institute on Drug Abuse)
- Pubmed/Medline search on sodium oxybate and alcohol-related disorders
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Agonists: Main site: Bamaluzole • Gaboxadol • Ibotenic acid • Isoguvacine • Isonipecotic acid • Muscimol (Amanita Muscaria) • Progabide • SL 75102 • Thiomuscimol • Tolgabide; Positive allosteric modulators: Barbiturates • Benzodiazepines • Carbamates • Chlormezanone • Clomethiazole • Ethanol (Alcohol) • Etomidate • Kavalactones (Kava) • Loreclezole • Metomidate • Neuroactive steroids • Nonbenzodiazepines (β-Carbolines, Cyclopyrrolones, Imidazopyridines, Pyrazolopyrimidines, etc.) • Phenols • Piperidinediones • Propanidid • Pyrazolopyridines • Quinazolinones • ROD-188 • Skullcap • Stiripentol • Valerenic acid (Valerian)Antagonists: Main site: Bicuculline • Gabazine • Pitrazepin; Negative allosteric modulators: α5IA • Bilobalide • Cicutoxin • Cyclothiazide • DMCM • Flumazenil • Flurothyl • Furosemide • L-655,708 • Oenanthotoxin • Penicillin • Pentylenetetrazol • Picrotoxin • PWZ-029 • Ro15-4513 • Sarmazenil • Suritozole • Thujone (Absinthe) • Thiocolchicoside • ZK-93426
* See Template:GABAAergics for a full list of GABAA positive allosteric modulators.
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Animal Poisons & Venoms: Batrachotoxin • Bestoxin • Birtoxin • Bungarotoxin • Charybdotoxin • Conotoxin • Saxitoxin • TetrodotoxinNeurotoxic drugs: Amphetamine • Lisdexamfetamine • Methamphetamine • αET • αMT • MBDB • MDA • MDEA • MDMA (Ecstasy) • PBA • PCA • PIA • 1,4-BD • GBL • GHB • Ibotenic Acid • Dizocilpine (MK-801) • Ketamine • Phencyclidine (PCP) • 5,7-DHT • 6-OHDA • MPTP/MPP+ • Norsalsolinol • Ethanol (Alcohol)
Bacterial toxins: Botulinum toxin • Tetanospasmin
Fungal toxins: Bicuculline
Plant toxins: Penitrem A • Picrotoxin
Nerve agents: Cyclosarin EA-3148 • GV (nerve agent) • Novichok agent • Sarin • Soman • Tabun (nerve agent) • VE (nerve agent) • VG (nerve agent) • VM (nerve agent) • VR (nerve agent) • VX (nerve agent)
Neurotransmitters and precursors: Dopamine • Glutamate • L-Tyrosine • L-Phenylalanine • L-DOPA (Levodopa) • L-Glutamine
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