Meldonium

Meldonium (INN; trade name Mildronate, among others) is a limited-market pharmaceutical, developed in 1970 by Ivars Kalviņš at the USSR Latvia Institute of Organic Synthesis, and now manufactured by the Latvian pharmaceutical company Grindeks and several generic manufacturers. It is primarily distributed in Eastern European countries as an anti-ischemia medication.[1]

Not to be confused with medronate or minodronate.
Meldonium
Clinical data
Trade namesMildronate, Mildronāts
Other namesTHP, MET-8 Mildronāts or Quaterine
ATC code
Legal status
Legal status
  • US: Unscheduled
Identifiers
CAS Number
PubChem CID
ChemSpider
UNII
KEGG
ChEBI
CompTox Dashboard (EPA)
ECHA InfoCard100.110.108
Chemical and physical data
FormulaC6H14N2O2
Molar mass146.190 g·mol−1
3D model (JSmol)
Solubility in water>40 mg/mL mg/mL (20 °C)

Since 1 January 2016, it has been on the World Anti-Doping Agency (WADA) list of substances banned from use by athletes.[2] However, there are debates over its use as an athletic performance enhancer. Some athletes are known to have been using it before it was banned.[3] It is currently unscheduled in the United States.

Medical use

Meldonium may be used to treat coronary artery disease.[4][5] These heart problems may sometimes lead to ischemia, a condition where too little blood flows to the organs in the body, especially the heart. Because this drug is thought to expand the arteries, it helps to increase the blood flow as well as increase the flow of oxygen throughout the body.[6] Meldonium has also been found to induce anticonvulsant and antihypnotic effects involving alpha 2-adrenergic receptors as well as nitric oxide-dependent mechanisms. This, in summary, shows that meldonium given in acute doses could be beneficial for the treatment of seizures and alcohol intoxication.[7] It is also used in cases of cerebral ischemia, ocular ischemic syndrome and other ocular disease caused by disturbed arterial circulation and may also have some effect on decreasing the severity of withdrawal symptoms caused by the cessation of chronic alcohol use.

Physio-pharmacology
Carnitine synthesis

To ensure a continuous guarantee of energy supply, the body oxidises considerable amounts of fat along with glucose. Carnitine transports activate long-chain fatty acids (FA) from the cytosol of the cell into the mitochondrion and is therefore essential for fatty acid oxidation (known as beta oxidation). Carnitine is mainly absorbed from the diet, but can be formed through biosynthesis. To produce carnitine, lysine residues are methylated to trimethyllysine. Four enzymes are involved in the conversion of trimethyllysine and its intermediate forms into the final product of carnitine. The last of these 4 enzymes is gamma-butyrobetaine dioxygenase (GBB), which hydroxylates butyrobetaine into carnitine.

The main cardioprotective effects are mediated by the inhibition of the enzyme GBB. By subsequently inhibiting carnitine biosynthesis, fatty acid transport is reduced and the accumulation of cytotoxic intermediate products of fatty acid beta-oxidation in ischemic tissues to produce energy is prevented, therefore blocking this highly oxygen-consuming process.[4] Treatment with meldonium therefore shifts the myocardial energy metabolism from fatty acid oxidation to the more favorable oxidation of glucose, or glycolysis, under ischemic conditions. It also reduces the formation of trimethylamine N-oxide (TMAO), a product of carnitine breakdown and implicated in the pathogenesis of atherosclerosis and congestive heart failure.

The carnitine shuttle system. (Red: acyl-CoA, Green: carnitine, Red+green: acylcarnitine, CoASH: coenzyme A, CPTI: carnitine palmitoyltransferase I, CPTII: carnitine palmitoyltransferase II, 1: acyl-CoA sintetase, 2: translocase, A: outer mitochondrial membrane, B: Intermembrane space, C: inner mitochondrial membrane, D: mitochondrial matrix)

In fatty acid (FA) metabolism, long chain fatty acids in the cytosol cannot cross the mitochondrial membrane because they are negatively charged. The process in which they move into the mitochondria is called the carnitine shuttle. Long chain FA are first activated via esterification with coenzyme A to produce a fatty acid-coA complex which can then cross the external mitochondrial border. The co-A is then exchanged with carnitine (via the enzyme carnitine palmitoyltransferase I) to produce a fatty acid-carnitine complex. This complex is then transported through the inner mitochondrial membrane via a transporter protein called carnitine-acylcarnitine translocase. Once inside, carnitine is liberated (catalysed by the enzyme carnitine palmitoyltransferase II) and transported back outside so the process can occur again. Acylcarnitines like palmitoylcarnitine are produced as intermediate products of the carnitine shuttle.

In the mitochondria, the effects of the carnitine shuttle are reduced by meldonium, which competitively inhibits the SLC22A5 transporter. This results in reduced transportation and metabolism of long-chain fatty acids in the mitochondria (this burden is shifted more to peroxisomes). The final effect is a decreased risk of mitochondrial injury from fatty acid oxidation and a reduction of the production of acylcarnitines, which has been implicated in the development of insulin resistance.[8][9] Because of its inhibitory effects on L-carnitine biosynthesis and its subsequent glycolytic effects as well as reduced acylcarnitine production, meldonium has been indicated for use in diabetic patients. In animal models[10] and a very small clinical trial,[11] meldonium has been shown to reduce blood glucose concentrations, exhibit cardioprotective effects and prevent or reduce the severity of diabetic complications. Long term treatment has also been shown to attenuate the development of atherosclerosis in the heart.

Its vasodilatory effects are stipulated to be due to the stimulation of the production of nitric oxide in the vascular endothelium. It is hypothesized that meldonium may increase the formation of the gamma-butyrobetaine esters, potent parasympathomimetics and may activate the eNOS enzyme which causes nitric oxide production via stimulation of the M3 muscarinic acetylcholine receptor or specific gamma-butyrobetaine ester receptors.[4]

Meldonium is believed to continually train the heart pharmacologically, even without physical activity, inducing preparation of cellular metabolism and membrane structures (specifically in myocardial mitochondria[12]) to survive ischemic stress conditions. This is done by adapting myocardial cells to lower fatty acid inflow and by activating glycolysis; the heart eventually begins using glycolysis instead of beta oxidation during real life ischaemic conditions. This reduces oxidative stress on cells, formation of cytotoxic products of fatty acid oxidation and subsequent cellular damage. This has made meldonium a possible pharmacological agent for ischemic preconditioning.[13]

The mechanisms underlying the central nervous system effects of meldonium are unclear. In a study in a transgenic mouse model of Alzheimer's disease, meldonium increased cognition and mental performance by reducing amyloid beta deposition in the hippocampus.[14]

Pharmacology
Meldonium and its various forms of packaging showing 250 mg capsules and the injection 10% 5 ml

Although initial reports suggested meldonium is a non-competitive and non-hydroxylatable analogue of gamma-butyrobetaine;[15] further studies have identified that meldonium is a substrate for gamma-butyrobetaine dioxygenase.[16][17][18] X-ray crystallographic and in vitro biochemical studies suggest that meldonium binds to the substrate pocket of γ-butyrobetaine hydroxylase and acts as an alternative substrate, and therefore a competitive inhibitor.[19] Normally, this enzyme's action on its substrates γ-butyrobetaine and 2-oxoglutarate gives, in the presence of the further substrate oxygen, the products L-carnitine, succinate, and carbon dioxide; in the presence of this alternate substrate, the reaction yields malonic acid semialdehyde, formaldehyde (akin to the action of histone demethylases), dimethylamine, and (1-methylimidazolidin-4-yl)acetic acid, "an unexpected product with an additional carbon-carbon bond resulting from N-demethylation coupled to oxidative rearrangement, likely via an unusual radical mechanism."[19][18] The unusual mechanism is thought likely to involve a Steven's type rearrangement.[17]

Meldonium's inhibition of γ-butyrobetaine hydroxylase gives a half maximal inhibitory concentration (IC50) value of 62 micromolar, which other study authors have described as "potent."[20] Meldonium is an example of an inhibitor that acts as a non-peptidyl substrate mimic.[21]

Chemistry
Structure of meldonium

The chemical name of meldonium is 3-(2,2,2-trimethylhydraziniumyl) propionate.[22][23] It is a structural analogue of γ-butyrobetaine, with an amino group replacing the C-4 methylene of γ-butyrobetaine. γ-Butyrobetaine is a precursor in the biosynthesis of carnitine.[24][25]

Meldonium is a white crystalline powder, with a melting point of 87 °C (189 °F).[26]

Society and culture

Doping

Meldonium was added to the World Anti-Doping Agency (WADA) list of banned substances effective 1 January 2016 because of evidence of its use by athletes with the intention of enhancing performance.[2][27] It was on the 2015 WADA's list of drugs to be monitored.[28][29] A high prevalence of meldonium use by athletes in sport was demonstrated by the laboratory findings at the Baku 2015 European Games. 13 medallists or competition winners were taking meldonium at the time of the Baku Games. Meldonium use was detected in athletes competing in 15 of the 21 sports during the Games. Most of the athletes taking meldonium withheld the information of their use from anti-doping authorities by not declaring it on their doping control forms as they should have. Only 23 of the 662 (3.5%) athletes tested declared the personal use of meldonium. However, 66 of the total 762 (8.7%) of athlete urine samples analysed during the Games and during pre-competition tested positive for meldonium.[30]

WADA classes the drug as a metabolic modulator, just as it does insulin.[31] Metabolic modulators are classified as S4 substances according to the WADA banned substances list. These substances have the ability to modify how some hormones accelerate or slow down different enzymatic reactions in the body. In this way, these modulators can block the body's conversion of testosterone into oestrogen, which is necessary for females. Based on the overall effects these drugs have, they have been banned since 2001 from men's competitions and 2005 for women's.[32] On 13 April 2016 it was reported that WADA had issued updated guidelines allowing less than 1 microgram per milliliter of meldonium for tests done before 1 March 2016.[33] The agency cited that "preliminary tests showed that it could take weeks or months for the drug to leave the body".

Affected athletes

On 7 March 2016, former world number one tennis player Maria Sharapova announced that she had failed a drug test in Australia due to the detection of meldonium. She said that she had been taking the drug for ten years for various health issues, and had not noticed that it had been banned.[34][35] On 8 June 2016, she was suspended from playing tennis for two years by the International Tennis Federation (ITF).[36][37][38] Earlier the same year (March 7), Russian ice dancer Ekaterina Bobrova announced that she had also tested positive for meldonium at the 2016 European Figure Skating Championships. Bobrova said she was shocked about the test result, because she had been made aware of meldonium's addition to the banned list, and had been careful to avoid products containing banned substances.[39] In May 2016, Russian professional boxer Alexander Povetkin—a former two-time World Boxing Association (WBA) Heavyweight Champion—tested positive for meldonium. This was discovered just a week prior to his mandatory title match against World Boxing Council (WBC) Heavyweight Champion, Deontay Wilder. As a result, the match—scheduled to take place in Russia—was postponed indefinitely by the WBC.[40]

Other athletes who are provisionally banned for using meldonium include Ethiopian-Swedish middle-distance runner Abeba Aregawi,[41] Ethiopian long-distance runner Endeshaw Negesse,[42] Russian cyclist Eduard Vorganov,[43] and Ukrainian biathletes Olga Abramova[44] and Artem Tyshchenko.[45]

The Ice Hockey Federation of Russia replaced the Russia men's national under-18 ice hockey team with an under-17 team for the 2016 IIHF World U18 Championships after players on the original roster tested positive for meldonium.[46]

More than 170 failed tests by athletes were identified in a relatively brief period after the ban on meldonium was imposed on 1 January 2016, almost all of which were from Eastern European countries.[47] Many of the early cases were dropped when athletes claimed that they had ceased use in 2015.[47] Notable athletes with positive samples include:[48]

NameCountrySportWhereConsequencesRef.
Maria Sharapova RussiaTennis2016 Australian OpenBanned for 2 years, backdated to 26 January 2016. Reduced to 15 months.[34][35]
Semion Elistratov RussiaShort track speed skatingNo fault[49]
Pavel Kulizhnikov RussiaSpeed skating2016 World Sprint Speed Skating ChampionshipsNo fault[49]
Ekaterina Bobrova RussiaFigure skating2016 European Figure Skating ChampionshipsNo fault[49]
Olga Abramova UkraineBiathlonNo fault - but her results between 10 January 2016 and 3 February 2016 were voided[44]
Artem Tyshchenko UkraineBiathlon[45]
Abeba Aregawi SwedenAthletics[41]
Endeshaw Negesse EthiopiaAthletics[42]
Yuliya Yefimova RussiaSwimmingTwo out of competition tests – 15 & 24 FebruaryUnknown[50]
Nadezhda Kotlyarova RussiaAthleticsCleared by RUSADA[51]
Sergei Semenov RussiaWrestlingCleared by RUSADA[51]
Evgeny Saleev RussiaWrestling[52]
Anastasia Chulkova RussiaCyclingCleared by RUSADA[51]
Gabriela Petrova BulgariaAthletics6 February 2016Suspension temporarily lifted[53]
Pavel Kulikov RussiaSkeletonSuspension temporarily lifted[54]
Andrei Rybakou BelarusWeightlifting[55]
Nikolai Kuksenkov RussiaArtistic gymnastics[56]
Elena Mirela Lavric RomaniaAthletics2016 IAAF World Indoor Championships[57]
Denis Yartsev RussiaJudo[58]
Mikhail Pulyaev RussiaJudo[58]
Natalia Kondratieva RussiaJudo[58]
Igor Mikhalkin RussiaBoxing (professional)12 March 20162-year ban[59]
Ruth Kasirye NorwayWeightliftingOut of contest routine testing – 25 January 2016Suspended until 21 July 2018[60][60]
Éva Tófalvi RomaniaBiathlon[61]
Anastasiya Mokhnyuk UkraineAthletics[62]
Islam Makhachev RussiaMixed martial artsOut of contest routine testingProvisional suspension lifted after 75 days[63]
Davit Chakvetadze RussiaWrestlingCleared by RUSADA[64]
Armantas Vitkauskas LithuaniaFootball[65]
Martynas Dapkus LithuaniaFootball[65]
Andrii Kviatkovskyi UkraineWrestlingProvisionally suspended[66]
Alen Zasyeyev UkraineWrestlingProvisionally suspended[66]
Oksana Herhel UkraineWrestlingProvisionally suspended[66]
Varvara Lepchenko United StatesTennisNo fault[67]
Antonina Skorobogatchenko RussiaHandball[68]
Mariia Dudina RussiaHandball[68]
Maxwell Holt United StatesVolleyball[69]
Tamerlan Tagziev CanadaWrestling4-year ban[70]
Daniel Omielańczuk PolandMMANo fault[71]
Alexander Krushelnitsky RussiaCurling2018 Winter OlympicsUnknown; Mixed Doubles bronze medal stripped[47]

In addition it was reported that five Georgian wrestlers[72] and a German wrestler had tested positive for the drug although no further names were released.[73] On 25 March 2016 the Fédération Internationale de Sambo confirmed that four wrestlers under their governance (two from Russia and two from other countries) had recorded positive tests for the drug.[74]

Debates

A December 2015 study in the journal Drug Testing and Analysis argued that meldonium "demonstrates an increase in endurance performance of athletes, improved rehabilitation after exercise, protection against stress, and enhanced activations of central nervous system (CNS) functions".[75] However the study itself presents no evidence for this claim, and focuses instead on describing two approaches for the reliable identification of meldonium. It is also believed that meldonium is opposing to steroids in the sense that instead of making the athlete emotionally unstable and readily irritable, it keeps them in an elevated state of mind and keeps their emotions in a happier state. When referring to central nervous system enhancements, it better activates the neurons in the CNS. This improves the messaging system throughout the body and, therefore, can decrease (improve) reaction time for an athlete.

The manufacturer, Grindeks, said in a statement that it did not believe meldonium's use should be banned for athletes. It said the drug worked mainly by reducing damage to cells that can be caused by certain byproducts of carnitine. Meldonium "is used to prevent death of ischemic cells and not to increase performance of normal cells", the statement said. "Meldonium cannot improve athletic performance, but it can stop tissue damage in the case of ischemia", the lack of blood flow to an area of the body.[76]

The drug was invented in the mid-1970s at the Institute of Organic Synthesis of the Latvian SSR Academy of Sciences by Ivars Kalviņš.[77][78][79] Kalviņš criticized the ban, saying that WADA had not presented scientific proof that the drug can be used for doping. According to him, meldonium does not enhance athletic performance in any way, and was rather used by athletes to prevent damage to the heart and muscles caused by lack of oxygen during high-intensity exercise. He contended that not allowing athletes to take care of their health was a violation of their human rights, and that the decision aimed to remove Eastern European athletes from competitions and his drug from the pharmaceutical market.[80][81] Liene Kozlovska, the head of the anti-doping department of the Latvian sports medicine center, rejected claims that the ban is in violation of athletes' rights, saying that meldonium is dangerous in high doses, and should only be used under medical supervision to treat genuine health conditions. She also speculated that Russian athletes may not have received adequate warnings that the drug was banned – due to the suspension of the Russian Anti-Doping Agency in late 2015.[82]

Forbes reported that anesthesiology professor Michael Joyner, at the Mayo Clinic in Rochester, Minnesota, who studies how humans respond to physical and mental stress during exercise and other activities, told them that "Evidence is lacking for many compounds believed to enhance athletic performance. Its use has a sort of urban legend element and there is not much out there that is clearly that effective. I would be shocked if this stuff [meldonium] had an effect greater than caffeine or creatine (a natural substance that, when taken as a supplement, is thought to enhance muscle mass)."[83] Ford Vox, a U.S.-based physician specializing in rehabilitation medicine and a journalist reported "there's not much scientific support for its use as an athletic enhancer".[84]

Don Catlin, a long-time anti-doping expert and the scientific director of the Banned Substances Control Group (BSCG) said "There's really no evidence that there's any performance enhancement from meldonium – Zero percent".[85]

Approval status

Meldonium, which is not approved by the FDA in the United States, is registered and prescribed in Latvia, Russia, Ukraine, Georgia, Kazakhstan, Azerbaijan, Belarus, Uzbekistan, Moldova, Lithuania, Albania, and Kyrgyzstan.[75][86]

Economics

Meldonium is manufactured by Grindeks, a Latvian pharmaceutical company, with offices in thirteen Eastern European countries[87] as a treatment for heart conditions.[88][89] The company identifies it as one of their main products.[90] It had sales of 65 million euros in 2013.[79]

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