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Methasterone

Methasterone, chemically known as (2α,5α,17β)-17-hydroxy-2,17-dimethylandrostan-3-one with the molecular formula C₂₁H₃₄O₂, is a synthetic anabolic-androgenic steroid (AAS) first synthesized in 1956 and demonstrated to possess potent anabolic activity in animal models by 1959.^[1]^[2] Originally developed as a potential therapeutic agent for muscle wasting, it features structural modifications including methylation at the 2α and 17α positions, enhancing its oral bioavailability and androgenic potency relative to testosterone.^[3]^[4] Marketed illicitly in the early 2000s as the prohormone "Superdrol" in dietary supplements targeted at bodybuilders for its rapid promotion of lean muscle mass and strength gains without significant water retention, methasterone gained notoriety for its extreme anabolic-to-androgenic ratio, reportedly exceeding 20:1 in preclinical assays.^[5] However, its unapproved status led to regulatory bans by the U.S. Food and Drug Administration in 2012 and inclusion on the World Anti-Doping Agency's prohibited list due to misuse in sports.^[1] Despite its efficacy in augmenting skeletal muscle hypertrophy, methasterone is associated with severe adverse effects, particularly profound hepatotoxicity stemming from its 17α-alkylation, which resists first-pass metabolism and induces cholestatic liver injury, as evidenced by case reports of acute renal failure and jaundice requiring hospitalization.^[6]^[7] Peer-reviewed analyses confirm its potential for idiosyncratic drug-induced liver injury, underscoring the causal link between short-term use and elevated liver enzymes, peliosis hepatis, and metabolic disruptions in users.^[2]^[4]

Chemistry

Chemical Structure and Properties

Methasterone, also known as methyldrostanolone, is a synthetic derivative of dihydrotestosterone characterized by a 5α-androstane core with a ketone group at position 3, a hydroxy group at position 17β, and methyl substituents at positions 2α and 17α.^[3] These structural modifications, particularly the 17α-methylation, enhance its oral bioavailability by reducing first-pass hepatic metabolism, while the 2α-methyl group contributes to its potent anabolic activity.^[8] The IUPAC name is (2α,5α,17β)-17-hydroxy-2,17-dimethylandrostan-3-one, with a molecular formula of C₂₁H₃₄O₂ and a molecular weight of 318.5 g/mol.^[3]^[8] Physicochemical properties include a calculated logP (XLogP3) of 4.5, indicating high lipophilicity and low water solubility, consistent with its classification as a non-polar steroid.^[3] It appears as a white to off-white crystalline solid, though specific melting point data is limited due to its status as a research chemical rather than a widely studied pharmaceutical.^[9] Methasterone exhibits one hydrogen bond donor and two acceptors, supporting its interactions in biological systems but limiting aqueous solubility.^[3] These properties underpin its rapid absorption and tissue distribution following oral administration.^[8] Methasterone, chemically 2α,17α-dimethyl-5α-androstan-17β-ol-3-one, is synthesized via catalytic hydrogenation of oxymetholone (17β-hydroxy-2-(hydroxymethylene)-17α-methyl-5α-androstan-3-one) in ethanol using palladium on charcoal as the catalyst, which selectively reduces the exocyclic 2-hydroxymethylene group to the 2α-methyl substituent while preserving the 3-keto functionality and 5α stereochemistry.^[8] This method yields methasterone as a white crystalline solid suitable for pharmaceutical or research applications.^[8] An alternative route involves treating drostanolone (17β-hydroxy-2α-methyl-5α-androstan-3-one) with formaldehyde in the presence of hydrochloric acid to introduce the 17α-methyl group, though this approach is less commonly detailed in preparative scales.^[10] The compound was first reported in scientific literature during the 1950s amid research into potent anabolic-androgenic agents, predating its later emergence as a designer steroid.^[2] Structurally, methasterone derives from 5α-dihydrotestosterone (DHT) through α-methylation at the 2- and 17-positions, enhancing oral bioavailability and anabolic potency relative to the parent hormone.^[11] Closely related compounds include drostanolone, which lacks the 17α-methyl group and exhibits primarily androgenic effects, and oxymetholone, featuring a 2-hydroxymethylene instead of 2α-methyl, used clinically for anemia treatment but with higher hepatotoxicity.^[11] ^[2] Dimethazine, a synthetic dimer of two methasterone units linked via an azine bridge at the 3-keto positions, shares similar anabolic profiles but differs in metabolic stability.^[12] Other analogs, such as methylstenbolone (a 2,17-dimethyl derivative with a modified A-ring), have been developed as prohormone precursors, though they possess distinct receptor binding affinities. These structural modifications generally amplify resistance to hepatic metabolism compared to non-alkylated androgens like testosterone.^[2]

Pharmacology

Pharmacodynamics

Methasterone functions as a synthetic agonist of the androgen receptor (AR), a nuclear receptor that, upon ligand binding, translocates to the nucleus to regulate gene expression involved in protein synthesis, cellular growth, and differentiation.^[13] This mechanism mirrors that of endogenous androgens like testosterone and dihydrotestosterone, promoting anabolic effects such as increased nitrogen retention and muscle hypertrophy while also eliciting androgenic responses like stimulation of secondary sexual characteristics.^[13] In competitive binding assays, methasterone demonstrates affinity for the AR comparable to testosterone, with similar potency in AR transactivation assays that measure transcriptional activation.^[11] In vivo evaluations in castrated male rats reveal methasterone's capacity to maintain androgen-sensitive tissues, including the levator ani muscle (an anabolic endpoint), ventral prostate, and seminal vesicles (androgenic endpoints), upon subcutaneous or oral administration.^[13] Relative to methyltestosterone, methasterone exhibits approximately fourfold greater anabolic activity in preventing levator ani atrophy and only one-fifth the androgenic potency in prostate and seminal vesicle assays.^[13] This disparity contributes to an anabolic-to-androgenic activity ratio of 400:20, indicating a profile skewed toward tissue-building effects over virilizing ones, though human data remain limited and primarily inferred from animal models and structural analogies to other 17α-alkylated dihydrotestosterone derivatives.^[14] Methasterone's 2α,17α-dimethylation and 17β-hydroxy configuration enhance its oral bioavailability and AR selectivity, but these modifications do not alter the core receptor-mediated pathway.^[13]

Pharmacokinetics

Methasterone is administered orally and demonstrates rapid absorption from the gastrointestinal tract, as evidenced by the detection of the parent compound and its metabolites in urine within hours of ingestion in human excretion studies.^[15] The steroid undergoes primary hepatic metabolism via phase I biotransformations, including hydroxylations at carbon positions C2, C6, C12, and C16, as well as reductions at C3, mediated by cytochrome P450 enzymes.^[4] These phase I products are further processed through phase II conjugation, chiefly glucuronidation (yielding metabolites such as G2, G6, and G7) and sulfation (S1 and S2), which enhance water solubility for elimination.^[4] As a 17α-alkylated androgen, methasterone resists extensive first-pass inactivation, supporting its oral bioavailability, though precise quantitative measures remain undocumented in peer-reviewed human pharmacokinetic evaluations due to the lack of formal clinical trials. Elimination occurs predominantly via renal excretion of conjugated metabolites in urine, with free forms comprising a minor fraction.^[4] Detection windows for metabolites in anti-doping assays extend from 3 to 10 days post-administration, with certain glucuronides like G2 persisting up to 10 days, reflecting the compound's metabolic stability and accumulation of long-lived conjugates.^[4] ^[15] Comprehensive half-life data are unavailable from controlled human studies, limiting precise modeling of its elimination kinetics beyond observational excretion profiles.^[4]

Uses and Efficacy

Investigational and Potential Medical Applications

Methasterone has not been approved for any therapeutic use in humans and lacks clinical trials investigating medical applications. Early preclinical research in the 1950s identified it as a potent anabolic agent in animal models, exhibiting strong promotion of muscle growth in the castrated male rat assay while displaying relatively weak androgenic effects compared to testosterone.^[11] This profile suggested theoretical potential for treating conditions involving muscle wasting, such as cachexia or hypogonadism, akin to other anabolic-androgenic steroids (AAS). However, its 17α-alkylation enabling oral bioavailability also confers high hepatotoxicity, as evidenced by case reports of severe liver injury in users, which has deterred systematic medical exploration. No peer-reviewed studies support efficacy or safety for human medical indications, and sources claiming benefits like weight loss or improved sexual function cite insufficient evidence.^[16] Unlike approved AAS such as oxandrolone, methasterone's risk-benefit ratio—marked by elevated liver enzymes, cholestasis, and potential renal complications—renders it unsuitable for investigational advancement in conditions like sarcopenia or AIDS-related wasting, where less toxic options predominate. Current research focuses primarily on its metabolism for anti-doping detection rather than therapeutic development.^[4]^[15]

Non-Medical Applications in Bodybuilding and Athletics

Methasterone, commonly known by its trade name Superdrol, is utilized illicitly by bodybuilders and strength athletes to promote rapid lean muscle mass accrual and strength enhancements during short-term cycles.^[17] Its appeal stems from delivering "dry" gains with minimal estrogenic side effects or water retention, distinguishing it from other oral anabolic-androgenic steroids like Anadrol.^[18] Users typically administer 10–30 mg daily via oral tablets, often for 2–4 weeks to mitigate hepatotoxicity risks associated with its 17α-alkylation, which resists first-pass metabolism.^[19] Cycles are frequently stacked with injectable testosterone or other non-aromatizing agents to amplify anabolic effects while suppressing endogenous production.^[17] In athletic contexts, methasterone has been implicated in performance-enhancing doping, with detection methods developed for anti-doping agencies due to its metabolites' persistence in urine.^[15] For instance, mixed martial artist Cole Province tested positive for the compound following a 2009 World Extreme Cagefighting event, highlighting its misuse in combat sports for purported advantages in power output and recovery.^[20] Advanced urinary profiling via liquid chromatography-tandem mass spectrometry has enabled identification of methasterone and its phase I/II metabolites, facilitating enforcement under World Anti-Doping Agency prohibitions.^[4] Despite such controls, underground production persists, with the substance appearing in over-the-counter supplements mislabeled as prohormones prior to its 2011 U.S. scheduling as a controlled anabolic steroid.^[13] Empirical user outcomes in non-medical settings emphasize its potency, with anecdotal reports citing 15–25 pounds of mass gain in 4 weeks at moderate doses, though verifiable data remain limited to doping case studies and metabolic analyses rather than controlled trials.^[19] Its high anabolic rating—estimated over 400 relative to testosterone—underpins these applications, but efficacy claims derive primarily from community experiences rather than peer-reviewed performance metrics.^[17]

Reported Efficacy and User Outcomes

Methasterone demonstrates pronounced anabolic effects in preclinical assessments, with early studies reporting it to possess four times the anabolic activity of methyltestosterone alongside reduced androgenic potency, approximately one-fifth that of the reference compound.^[11] This profile contributes to its reputation for promoting lean tissue accrual without significant estrogenic conversion or water retention.^[17] Anecdotal user reports from bodybuilding contexts consistently describe rapid enhancements in muscle fullness, vascularity, and strength during short cycles of 2-4 weeks at dosages ranging from 10-30 mg daily.^[21] Practitioners frequently claim 10-20 pounds of weight gain, predominantly lean mass, with noticeable physique changes emerging within days, including heightened glycogen retention and workout capacity under caloric surplus conditions.^[22] These outcomes align with its high anabolic-to-androgenic ratio, facilitating "dry" gains suitable for cutting or recomp phases, though empirical data from controlled trials remain unavailable due to its regulatory status.^[23] Post-cycle retention of gains varies among users, with some retaining 50-70% of acquired mass when followed by appropriate ancillary therapies, while others experience greater losses attributable to the compound's brief half-life and absence of sustained receptor mediation.^[21] Such reports, drawn from online forums, underscore methasterone's efficacy for acute performance elevation but highlight the need for caution in interpreting them as uncontrolled and potentially confounded by concurrent ergogenic aids or training variables.

Adverse Effects and Risks

Hepatotoxicity

Methasterone, a synthetic 17α-alkylated anabolic-androgenic steroid, demonstrates marked hepatotoxicity attributable to its chemical modification, which enhances oral bioavailability by impeding first-pass hepatic metabolism and prolonging exposure to hepatocytes.^[24] This structural feature, common to other C-17α alkylated steroids, elevates the risk of liver injury compared to non-alkylated analogs, primarily manifesting as cholestatic hepatitis rather than hepatocellular necrosis.^[24] Clinical evidence derives from case series and reports in otherwise healthy young males using methasterone for performance enhancement, with onset typically occurring 1–2 months after initiation of doses ranging from 10–30 mg daily.^[25]^[24] Characteristic presentations include jaundice, pruritus, dark urine, and fatigue, accompanied by laboratory abnormalities such as markedly elevated total bilirubin (often exceeding 20 mg/dL or 340 μmol/L), modestly raised aminotransferases (ALT 100–500 U/L, AST similar), and increased alkaline phosphatase (ALP 200–300 U/L).^[24]^[26] In a series of five cases reported by Shah et al. in 2008, patients aged 20–33 years developed jaundice with peak bilirubins of 7.6–41.8 mg/dL following 4–8 weeks of use; liver biopsies revealed bland intracanalicular cholestasis with minimal inflammation or fibrosis.^[25]^[24] Similar patterns appear in other reports, such as a 23-year-old with bilirubin peaking at 36.2 mg/dL and ALT at 93 U/L, or two cases with bilirubins up to 49.7 mg/dL resolving over 2–3 months post-discontinuation.^[24] Severity can escalate to acute liver injury with coagulopathy or renal dysfunction, as in two 2020 cases where peak bilirubins reached 37 mg/dL (633 μmol/L) and 45 mg/dL (768 μmol/L), with ALT peaks of 257 U/L and 460 U/L, respectively; both involved methasterone and required hospitalization.^[26] Histopathologic findings consistently show canalicular cholestasis without significant hepatocyte damage, suggesting a mechanism involving disruption of bile salt export transporters (e.g., BSEP inhibition) rather than direct cytotoxicity.^[24] Liver enzyme elevations may persist or worsen for 1–2 weeks after cessation, underscoring the need for monitoring beyond discontinuation.^[25] Management entails immediate cessation, supportive care including hydration and avoidance of hepatotoxins, and monitoring for complications; adjunctive therapies such as N-acetylcysteine, ursodeoxycholic acid, or corticosteroids (e.g., prednisolone 40–60 mg daily, tapered over weeks) have facilitated recovery in severe cholestatic cases, with resolution typically occurring within 2–12 weeks absent underlying liver disease.^[25]^[26] No fatalities directly attributed to methasterone hepatotoxicity have been documented in reviewed cases, though prolonged cholestasis risks secondary issues like malabsorption or xanthomas; full hepatic recovery without sequelae is the norm in reported instances.^[24]^[25] Pre-existing conditions, such as chronic hepatitis B, may exacerbate injury, as noted in isolated reports.^[27]

Androgenic, Cardiovascular, and Other Systemic Effects

Methasterone, a synthetic dihydrotestosterone derivative, possesses potent androgenic properties characteristic of anabolic-androgenic steroids (AAS), including promotion of secondary male sexual characteristics. In male users, reported androgenic effects encompass acne due to enhanced sebaceous gland activity, accelerated male-pattern baldness in genetically predisposed individuals, and potential increases in aggression or mood alterations linked to androgen receptor activation. Unlike aromatizable AAS, methasterone does not convert to estrogen, thereby minimizing estrogen-mediated effects such as gynecomastia, though progestogenic activity remains unclarified in available data.^[28] Female users face heightened risks of virilization, including hirsutism, voice deepening, and clitoral enlargement, with reversibility uncertain post-discontinuation. Empirical evidence is largely anecdotal or extrapolated from AAS class effects, as controlled studies on methasterone are absent due to its status as an unapproved designer steroid. Cardiovascular effects of methasterone align with those observed in AAS misuse, including elevations in systolic blood pressure from fluid retention and vasoconstriction, alongside dyslipidemia characterized by decreased high-density lipoprotein cholesterol and increased low-density lipoprotein levels.^[29] These alterations promote atherosclerosis and elevate thrombotic risk, compounded by potential erythrocytosis increasing hematocrit. Specific case data for methasterone are sparse, but general AAS literature implicates accelerated left ventricular hypertrophy and arrhythmogenic potential, contributing to sudden cardiac events in chronic users.^[30] Oral administration exacerbates lipid perturbations via hepatic first-pass metabolism, though direct methasterone-linked cardiac pathology remains undocumented in peer-reviewed reports. Other systemic effects include hypothalamic-pituitary-testicular axis suppression, resulting in reduced endogenous testosterone production, azoospermia, and temporary infertility persisting months post-cessation. Case reports document acute kidney injury, often alongside cholestatic jaundice, attributed to dehydration, rhabdomyolysis, or toxin-mediated nephrotoxicity rather than primary glomerular damage.^[6] Psychological sequelae, such as heightened irritability or dependency, mirror broader AAS profiles, with limited methasterone-specific longitudinal data available. Overall, systemic risks underscore the compound's profile as a high-potency AAS with minimal therapeutic margin, informed primarily by adverse event reports rather than prospective trials.

Long-Term Health Implications and Mitigation Strategies

Long-term use of methasterone, a 17α-alkylated anabolic-androgenic steroid (AAS), is associated with heightened risk of chronic liver pathology due to its propensity for inducing severe cholestatic injury, as evidenced by multiple case reports of acute hepatotoxicity progressing to liver failure in some instances.^[25] Repeated exposure exacerbates this, potentially leading to peliosis hepatis—characterized by blood-filled hepatic cysts—or hepatic adenomas and hepatocellular carcinoma, patterns observed in prolonged use of similar oral AAS.^[31] While acute cholestasis often resolves upon discontinuation, histological findings in affected cases reveal bile duct proliferation and portal edema, raising concerns for fibrosis or irreversible damage with cumulative dosing.^[25] Beyond hepatotoxicity, extended methasterone administration contributes to AAS-class endocrine disruptions, including persistent hypogonadotropic hypogonadism and infertility, with recovery of spermatogenesis potentially delayed beyond one year in heavy users.^[32] Cardiovascular implications include accelerated atherosclerosis, dyslipidemia, and cardiomyopathy, correlating with elevated mortality rates in long-term AAS abusers compared to non-users (12.9% vs. 3.1% in one cohort of powerlifters).^[32] Psychiatric sequelae, such as dependence and mood disturbances, may persist post-cessation, compounded by progression to polysubstance abuse in approximately 35% of chronic users.^[32] Limited prospective data exist specifically for methasterone owing to its illicit, non-medical context, but class-wide evidence underscores dose- and duration-dependent risks.^[24] Mitigation strategies emphasize immediate discontinuation at the onset of symptoms like jaundice or elevated liver enzymes, with supportive care including hospitalization for severe cases to manage complications such as coagulopathy or renal involvement.^[25] Serial monitoring of liver function tests (e.g., ALT, bilirubin) and avoidance of concurrent hepatotoxins are recommended for users, though prophylactic agents like N-acetylcysteine lack robust evidence in AAS-induced injury.^[24] For endocrine recovery, post-cycle therapy with selective estrogen receptor modulators may aid hypothalamic-pituitary axis reactivation, but efficacy varies and professional oversight is essential to avert prolonged hypogonadism.^[32] Ultimate risk reduction entails abstinence, as no regimen fully offsets the hepatotoxic profile of 17α-alkylated AAS like methasterone.^[31]

Legal Status and Regulation

United States Classification

Methasterone is classified as a Schedule III controlled substance under the Anabolic Steroids Control Act of 1990, as amended, which is part of the Controlled Substances Act (CSA).^[11] This placement recognizes its chemical and pharmacological similarity to testosterone (17β-hydroxyandrost-4-en-3-one), qualifying it as an anabolic steroid with high potential for abuse but accepted medical use in treatment in the United States under strict conditions, and abuse potentially leading to moderate or low physical dependence or high psychological dependence.^[11] ^[33] The Drug Enforcement Administration (DEA) finalized methasterone's scheduling as a Schedule III substance on July 30, 2012, through a rule published in the Federal Register, following a notice of proposed rulemaking in November 2011.^[11] ^[13] Prior to this, methasterone (marketed as Superdrol) evaded explicit controls by being sold as a purported dietary supplement or prohormone since around 2005, despite lacking FDA approval for any medical indication and exhibiting potent anabolic effects comparable to or exceeding those of traditional Schedule III steroids like oxymetholone.^[34] The DEA's action was prompted by evidence of widespread non-medical distribution and abuse, aligning with congressional intent under the Designer Anabolic Steroid Control Act of 2014 (which further refined definitions but did not alter methasterone's status).^[35] Under Schedule III, unauthorized possession, manufacture, distribution, importation, or exportation of methasterone or its salts, esters, and ethers carries civil and criminal penalties, including up to one year imprisonment and fines for first offenses, escalating for repeat violations or larger quantities.^[11] Exemptions apply only to DEA-registered handlers for legitimate research, teaching, or medical purposes, though no anabolic steroid products containing methasterone have been granted exemptions from CSA listing requirements.^[36] The substance is assigned DEA controlled substance code number 4000 in official listings.^[33]

International Controls and Sports Prohibitions

Methasterone is not scheduled under international treaties such as the United Nations Convention against Illicit Traffic in Narcotic Drugs and Psychotropic Substances, as anabolic-androgenic steroids are primarily regulated through national legislation rather than global conventions. In the United Kingdom, methasterone is classified as a Class C substance under the Misuse of Drugs Act 1971, alongside other anabolic steroids, prohibiting its possession, supply, and production without authorization; penalties include up to 2 years imprisonment for possession and 14 years for supply.^[37] In Canada, products containing methasterone, marketed as Superdrol, have been deemed to contain illegal anabolic steroids under the Controlled Drugs and Substances Act, with Health Canada issuing advisories against their use and seizure of unauthorized imports since at least 2006.^[38] Similar restrictions apply in Australia, where methasterone is treated as an unapproved Schedule 4 substance by the Therapeutic Goods Administration, banning its therapeutic goods status, importation, and sale without exemption.^[2] In professional and competitive sports, methasterone is explicitly prohibited by the World Anti-Doping Agency (WADA) under S1.1 Anabolic Androgenic Steroids (exogenous) of the Prohibited List, effective annually from January 1; it is banned at all times, both in- and out-of-competition, as a specified substance subject to potential reduced sanctions but still resulting in anti-doping rule violations upon detection.^[39]^[40] The WADA code, adopted by over 700 signatories including the International Olympic Committee and major federations like FIFA and UCI, mandates testing and sanctions such as suspensions for positive tests, with metabolites detectable in urine via advanced mass spectrometry methods developed since its emergence as a designer steroid.^[15] Anti-doping laboratories worldwide monitor for methasterone due to its history of illicit use in bodybuilding and athletics, contributing to cases of adverse analytical findings despite its oral administration and short detection window.^[41]

History

Early Development and Research (1950s–1970s)

Methasterone, chemically known as 17α-methyl-2α-dihydrotestosterone or methyldrostanolone, was first synthesized in 1956 by researchers at Syntex Corporation as part of systematic explorations into synthetic anabolic-androgenic steroids derived from dihydrotestosterone.^[42] This development aligned with the post-World War II surge in steroid chemistry, where pharmaceutical firms like Syntex pursued modifications to testosterone's structure—such as 17α-alkylation for oral bioavailability and 2α-methylation for enhanced anabolic potency—to treat conditions like muscle-wasting diseases and hypogonadism.^[2] The initial synthesis was documented in scientific literature that year, highlighting methasterone's structural novelty but noting no immediate therapeutic breakthroughs.^[43] Through the late 1950s and 1960s, limited pharmacological evaluations of methasterone occurred within broader structure-activity studies of C-17 alkylated androgens, which aimed to dissociate anabolic muscle-building effects from androgenic virilizing properties.^[44] Unlike more successful Syntex compounds such as norethandrolone (introduced in 1956), methasterone exhibited high anabolic ratios in preclinical assays but raised early concerns over hepatotoxicity, a common liability of 17α-methylated steroids that strained liver metabolism. No large-scale clinical trials advanced during this period, as regulatory scrutiny intensified following reports of adverse effects from similar agents, including jaundice and peliosis hepatis in users of oral androgens.^[45] By the 1970s, amid growing evidence of steroid-related health risks and shifting priorities toward less hepatotoxic alternatives like injectables, methasterone faded from active pharmaceutical pipelines.^[2] Patents from the era encompassed thousands of synthetic androgens, many unmarketed due to efficacy-safety imbalances, consigning methasterone to archival status without FDA approval or commercial release.^[46] This dormancy reflected causal realities of drug development: while structurally promising for anabolism, its profile did not outweigh risks in an era prioritizing verifiable clinical utility over speculative potency.

Re-Emergence as a Designer Steroid (2000s)

Methasterone re-emerged in the mid-2000s as a designer anabolic steroid amid a surge in underground supplement innovation following the Anabolic Steroid Control Act of 2004, which expanded bans on prohormones and prompted creators to develop novel, structurally modified compounds not yet explicitly scheduled. Marketed under the brand name Superdrol by Designer Supplements—a company associated with supplement formulator Matt Cahill—it was introduced in 2005 as an over-the-counter dietary supplement containing 10 mg of methasterone per capsule, exploiting regulatory gaps that classified it as a legal nutritional product rather than a controlled substance.^[47]^[48] Positioned as a "prohormone" alternative for bodybuilders seeking rapid, dry muscle gains without significant estrogenic side effects, Superdrol rapidly gained traction in fitness communities for its reported potency, with users documenting exceptional strength increases and lean mass accrual—often 15-25 pounds in 4-6 week cycles—at doses of 10-30 mg daily. This appeal stemmed from its chemical profile as a 17α-methylated dihydrotestosterone derivative, enabling oral bioavailability and high anabolic-to-androgenic ratios, which outperformed many contemporaneous oral steroids in anecdotal performance logs while evading initial detection in drug-tested environments. Cahill's formulation, drawing from earlier unpublished Syntex research, capitalized on the era's lax FDA oversight of supplement labeling, allowing widespread distribution through online vendors and gyms until adverse health reports mounted.^[48] By 2006, the compound's re-emergence faced scrutiny as clinical cases linked it to acute liver injury, including cholestatic jaundice and elevated transaminases exceeding 1,000 IU/L in users, prompting the FDA to issue warning letters to distributors and seize products for misbranding as unapproved drugs. Despite these interventions, underground production persisted into the late 2000s, with Superdrol exemplifying the designer steroid trend that prioritized short-term efficacy over long-term safety, influencing subsequent analogs until its explicit scheduling.^[49]^[13]

Banning, Detection Advances, and Ongoing Use (2010s–Present)

In July 2012, the United States Drug Enforcement Administration (DEA) finalized the classification of methasterone as a Schedule III controlled substance under the Controlled Substances Act, following a proposed rule in November 2011 that determined it met the criteria for an anabolic steroid due to its structural similarity to testosterone and potential for abuse.^[13]^[34] This action criminalized its manufacture, distribution, and possession without a prescription, responding to its prior sale as an unapproved dietary supplement under the guise of "Superdrol" since the mid-2000s. Internationally, the World Anti-Doping Agency (WADA) has prohibited methasterone at all times as an anabolic androgenic steroid under section S1.1 of its Prohibited List, with explicit inclusion confirmed in versions from 2019 onward, subjecting athletes to sanctions upon detection.^[40]^[50] Detection methodologies advanced significantly in the 2010s through enhanced mass spectrometry techniques, including gas chromatography-mass spectrometry (GC-MS) and liquid chromatography-tandem mass spectrometry (LC-MS/MS), enabling identification of methasterone metabolites such as reduced A-ring derivatives for retrospective doping analysis.^[10]^[51] These improvements addressed challenges in detecting low-abundance phase I and II metabolites, extending detection windows beyond the parent compound's short half-life and supporting WADA's emphasis on longitudinal urinary and blood profiling.^[52] By the late 2010s, methods like high-resolution mass spectrometry integrated suspect screening for undeclared anabolic agents in supplements, facilitating proactive identification in seized products.^[53] Despite regulatory measures, methasterone persists in illicit use among bodybuilders and athletes, often via black-market sources or contaminated supplements, as evidenced by its detection in over-the-counter products sold in the UK as late as 2014 and in doping cases into the 2020s.^[2]^[54] WADA-accredited labs continue to report adverse analytical findings, underscoring evasion tactics like microdosing or prohormone precursors, though enforcement has curbed overt supplement marketing.^[55] Ongoing misuse highlights gaps in supply chain oversight, with peer-reviewed analyses confirming its appeal for rapid muscle gains despite known hepatotoxicity risks.^[56]

References

[1]
https://public-inspection.federalregister.gov/2012-18495.pdf
[2]
Anabolic steroids detected in bodybuilding dietary supplements – a ...
Oct 6, 2014 · For example, methasterone was first synthesized in the 1950s15 and shown to be a potent anabolic agent in animal models14, 17, DMT was first ...
[3]
Methasterone | C21H34O2 | CID 237186 - PubChem - NIH
Methasterone | C21H34O2 | CID 237186 - structure, chemical names, physical and chemical properties, classification, patents, literature, ...
[4]
New Potential Biomarker for Methasterone Misuse in Human Urine ...
Sep 24, 2016 · As 17α-methylation makes a valuable contribution to the enhancement of anabolic effect and considerably increases the anabolic strength of the ...
[5]
Methasterone (Superdrol, methasteron, methyldrostanolone)
Sep 16, 2012 · Methasterone resurfaced in 2005 as a “designer steroid”.[5] It was brought to market by Anabolic Xtreme as the primary ingredient of a dietary ...
[6]
Severe Cholestasis and Renal Failure Associated with the Use of ...
Aug 6, 2025 · Consumption of methasteron as a dietary supplement for bodybuilding has been reported to cause severe hepatotoxicity, cholestasis, and acute renal failure.
[7]
Structural transformation of methasterone with Cunninghamella ...
... anabolic-androgenic steroid (AAS), used to increase skeletal muscles growth. Consequently, athletes may favour methasterone (1) for its fat-burning ability ...
[8]
Methasterone | 3381-88-2 - ChemicalBook
Methasterone (CAS 3381-88-2) information, including chemical properties ... Molecular Formula: C21H34O2. Molecular Weight: 318.5. MDL Number: MFCD01670015.<|separator|>
[9]
[PDF] Safety Data Sheet - Cayman Chemical
Jul 18, 2025 · · Trade name: Methasterone. · Synonym. (2α,5α,17β)-17-hydroxy-2,17 ... · Molecular Weight. 318.5 g/mol. · Storage Buffer. · Odor threshold ...
[10]
Identification of drostanolone and 17-methyldrostanolone ...
The list of anabolic agents including anabolic androgenic steroids, prohibited in sports is published by the World Anti-Doping Agency [1]. In order to detect ...
[11]
Classification of Two Steroids, Prostanozol and Methasterone, as ...
Jul 30, 2012 · Methasterone is known by the following chemical names: 2α,17α-dimethyl-5α-androstan-17β-ol-3-one; 2α,17α-dimethyl-17β-hydroxy-5α-androstan-3-one ...
[12]
Synthetic Androgens as Designer Supplements - PMC
Dimethazine (17β-hydroxy-2α,17β-dimethyl-5α-androstan-3-one-azine), a steroid dimer consisting of two methasterone (17β-hydroxy-2α,17α-dimethyl-5a-androstan-3- ...
[13]
Methylstenbolone - Wikipedia
Methylstenbolone, known by the nicknames M-Sten, Methyl-Sten, and Ultradrol, is a synthetic and orally active anabolic–androgenic steroid (AAS)<|control11|><|separator|>
[14]
Classification of Two Steroids, Prostanozol and Methasterone, as ...
Nov 23, 2011 · This Notice of Proposed Rulemaking (NPRM) proposes to classify the following two steroids as “anabolic steroids” under the Controlled Substances Act (CSA).
[15]
Polymorphism and β-cyclodextrin complexation of methyldrostanolone
Feb 15, 2022 · Introduction. Anabolic-androgenic steroids are synthetic compounds derived from testosterone with the purpose to provide an increased anabolic ...
[16]
Human Metabolism of the Anabolic Steroid Methasterone: Detection ...
These authors found two 2,3-diol metabolites and proposed, through chemical synthesis and nuclear magnetic resonance, that the major isomer would be a 2β,3α ...
[17]
Methasterone [Fast Facts] - Uses, Side Effects, and More - WebMD
Methasterone is used for weight loss, to improve athletic performance, to reduce sexual problems, and for many other uses, but there is no good scientific ...Missing: trials | Show results with:trials
[18]
https://teletest.ca/blog/anadrol-vs-superdrol-comparing-side-effects/
[19]
Anadrol vs. Superdrol: Comparing Side Effects - TeleTest.ca
Jul 5, 2024 · When exploring the realm of anabolic steroids, Anadrol (Oxymetholone) and Superdrol (Methasterone) often stand out due to their powerful effects ...
[20]
Superdrol: Cycle, Dosage, and Before and After Results
Feb 15, 2023 · Superdrol is the brand name for methasterone, an oral anabolic steroid that was first described in 1956 by Syntex.What Are the Benefits of... · What Are the Side Effects of... · Superdrol Cycle
[21]
WEC's Province tests positive for steroid - Mixed Martial Arts Blog
Aug 18, 2009 · Remember, kids: It's only cheating if you get caught. Following his win at WEC 42, Cole Province has tested positive for the oral steroid ...<|separator|>
[22]
[Compound Experience Thread] Superdrol (Methyldrostanolone) 09 ...
Sep 7, 2023 · Absolutely insane on just 10mg a day, strength up, vascularity up, FULLNESS is crazy, your body changes in just 2-3 days, you look 15 lbs ...
[23]
Superdrol- what to expect/transformations : r/PEDs - Reddit
Oct 22, 2021 · superdrol is good for short term, very acute outcomes in strength and/or glycogen retention. it does both of those very well under calorie ...
[24]
Methasterone: Functions and side effects - ChemicalBook
Jan 7, 2025 · Methasterone (superdrol and methyldrostanolone) is an orally active anabolic agent exhibiting androgenic activity.Missing: pharmacodynamics | Show results with:pharmacodynamics
[25]
Androgenic Steroids - LiverTox - NCBI Bookshelf - NIH
May 30, 2020 · Severe cholestasis and renal failure associated with the use of the designer steroid Superdrol (methasteron): a case report and literature ...
[26]
Methasteron-associated cholestatic liver injury - PubMed
The aim of this study was to describe 5 cases of hepatotoxicity in patients using methasteron seen at tertiary-care medical centers. Methods: A case report ...Missing: studies | Show results with:studies
[27]
Androgenic anabolic steroid-induced liver injury: two case reports ...
Nov 19, 2020 · Background Anabolic androgenic steroids (AAS) usage is widespread and increasing. AAS drug-induced liver injury (DILI) is recognised but its ...
[28]
Methasterone | Reactions Weekly
Jan 23, 2021 · His liver screen showed undiagnosed chronic hepatitis B (HBV) with a low viral load of 181 IU/mL and a low titre of antismooth muscle antibody ( ...Missing: hepatotoxicity studies
[29]
Designer steroids – over‐the‐counter supplements and their ...
Feb 13, 2015 · Designer anabolic steroids have been popular now for over a decade as a way to achieve classic anabolic steroid-like results from products sold in the legal ...<|control11|><|separator|>
[30]
Cardiovascular manifestations of anabolic steroids in association ...
The most common drug abuse among athletes is anabolic steroids which lead to the development of cardiovascular diseases and sudden death.
[31]
Sudden cardiac death in anabolic androgenic steroids abuse - NIH
Aug 19, 2019 · Anabolic androgenic steroids (AAS) have several adverse effects on the cardiovascular system that may lead to a sudden cardiac death (SCD).
[32]
Anabolic androgenic steroid-induced liver injury: An update - NIH
Jul 14, 2022 · Testosterone and its derivatives have been most often shown to induce a specific form of cholestasis, peliosis hepatis, and hepatic benign and malignant tumors.Missing: Methasterone | Show results with:Methasterone
[33]
Long-Term Psychiatric and Medical Consequences of Anabolic ...
The problem of anabolic-androgenic steroid (AAS) abuse has recently generated widespread public and media attention. Most AAS abusers, however, ...
[34]
[PDF] Controlled Substances - Alphabetical Order
Methasterone (2a, 17a-dimethyl-5a-androstan-17ẞ-ol-3- one). 4000. |||. N. Methcathinone. 1237. N. Methasterone; 2a,17a-dimethyl-17ẞ-hydroxy-5α- androstan-3-one.
[35]
DEA Controls Prostanozol and Methasterone As Schedule III ...
Jul 30, 2012 · Prostanozol and methasterone are Schedule III anabolic steroids because they are chemically and pharmacologically related to testosterone, not ...
[36]
Implementation of the Designer Anabolic Steroid Control Act of 2014
Aug 1, 2023 · The Act amended the Controlled Substances Act to revise and add specified substances to the definition of “anabolic steroid.” The Act provided a ...
[37]
Schedules of Controlled Substances: Exempt Anabolic Steroid ...
Jun 15, 2020 · The DEA is exempting two anabolic steroid products, Esterified Estrogens and Methyltestosterone tablets, from the Controlled Substances Act due ...
[38]
[PDF] ACMD - Consideration of the Anabolic Steroids - GOV.UK
Sep 21, 2010 · EU Member states control measures for anabolic steroids. Legal for a person to: Possess without prescription. Sell without govt. authorization.Missing: Methasterone | Show results with:Methasterone
[39]
Health Canada advises consumers not to use unauthorized ...
Apr 21, 2006 · Health Canada is advising consumers not to use seven products containing illegal anabolic steroids, as they can potentially cause serious ...Missing: banned | Show results with:banned
[40]
The Prohibited List | World Anti Doping Agency - WADA
Jun 1, 2019 · Methasterone (17β-hydroxy-2α,17α- dimethyl-5α-androstan-3 ... However, some sports authorities may prohibit its use in their regulations.Athletes & Support Personnel · Liste des interdictions · Footer
[41]
[PDF] international standard - prohibited list - WADA
*Also prohibited Out-of-Competition. PROHIBITED IN PARTICULAR SPORTS. All prohibited substances in this class are Specified Substances. BETA-BLOCKERS. Page 20 ...
[42]
World Anti-Doping Agency (WADA) Prohibited List - Usada
The World Anti-Doping Agency (WADA) Prohibited List outlines the banned substances and methods that are prohibited in sport.
[43]
Superdrol Cycle - Best Practices and Protocol - MuscleChemistry
Sep 23, 2019 · Superdrol Cycle Guide to adding lean quality muscle mass. Gain Strength Lose Fat With Our Methasterone Tips.<|separator|>
[44]
Thread: Extensive Info on Superdrol/M-Drol
Sep 4, 2011 · The synthesis of methasterone is first mentioned in the literature in 1956 in connection with research conducted by Syntex Corporation in ...
[45]
(PDF) Human Enhancement Drugs - The Emerging Challenges to ...
anabolic methasterone. This was first synthesised in the late 1950s. but ... Most accounts suggest that by the early 1950s the drugs started to be. used ...
[46]
History and epidemiology of anabolic androgens in athletes and non ...
Testosterone was isolated in the 1930s, and numerous synthetic androgens were quickly developed thereafter. Athletes soon discovered the dramatic anabolic ...Missing: Methasterone | Show results with:Methasterone
[47]
https://www.wada-ama.org/sites/default/files/resources/files/wada_-eichner-investigation-istanbul.pdf
[48]
[PDF] DIETARY SUPPLEMENTS AS A SOURCE OF ILLEGAL/DESIGNER ...
• Methasterone (Superdrol). • 1956- Syntex Corporation, anti-tumor. • 2005- marketed as Superdrol (Matt Cahill). Steroids Hit “Supplements”. Page 11. • Powerful ...Missing: date | Show results with:date
[49]
Sports supplement designer has history of risky products - USA Today
Jul 25, 2013 · Matt Cahill designed supplements that have been linked to liver damage, other health problems.Missing: date | Show results with:date
[50]
Cholestatic jaundice, acute kidney injury and acute pancreatitis ...
Over the last few years the use of anabolic steroids has become increasingly common amongst amateur athletes and for aesthetic purposes.
[51]
[PDF] PROHIBITED LIST - WADA
Jan 1, 2020 · NON-APPROVED SUBSTANCES. Any pharmacological substance which is not addressed by any of the subsequent sections of the.Missing: worldwide | Show results with:worldwide
[52]
New Insights into the Metabolism of Methyltestosterone and ... - NIH
Due to the low abundance of some of the target analytes, GC-QQQ-MS in MRM mode is considered as a better-suited technique for metabolite detection after ...
[53]
Recent advances in identifying and utilizing metabolites of selected ...
Oct 25, 2021 · In this review, approaches supporting the identification, characterization, and implementation of metabolites exemplified by means of selected doping agents ...
[54]
A review of the analytical techniques for the detection of anabolic ...
Oct 3, 2023 · This review collates information regarding the extraction and analysis of AASs from various biological matrices
[55]
Detection of multiple prohibited ingredients in nutritional ...
Aug 6, 2025 · Conclusion: methasterone, ligandrol and cardarine were complessively detected in 2 samples. Since no labelling declared the retrieved substances ...
[56]
The ITA reports that three Turkish weightlifters have committed anti ...
May 31, 2024 · Three athletes from the Turkish Weightlifting Federation have committed anti-doping rule violations (ADRVs) within a 12-month period.<|control11|><|separator|>
[57]
Anabolic-Androgenic Steroid Misuse: Mechanisms, Patterns of ...
Dec 10, 2021 · AAS are associated with sudden cardiac death, neuropsychiatric manifestations, and infertility. The average AAS user is unlikely to voluntarily ...