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Phenylpiracetam

Phenylpiracetam, also known as fonturacetam or phenotropil, is a synthetic compound belonging to the class of drugs, characterized by a chemical structure derived from through the addition of a at the 4-position of the pyrrolidone ring, with the molecular formula C₁₂H₁₄N₂O₂. It is primarily recognized for its cognitive-enhancing properties, including improvements in , , and learning, as well as psychostimulant effects that support physical and mental performance under stress. In , where it is approved as a prescription , phenylpiracetam is indicated for the treatment of asthenic conditions, cognitive impairments due to cerebrovascular disorders or , and disturbances, typically administered at doses of 100–200 mg per day. Developed in the during the early 1980s as part of research into agents for enhancing performance during extended missions, phenylpiracetam was introduced to address issues like prolonged and cognitive in extreme environments. It was approved in in 2003 under the Phenotropil, although under that specific was discontinued in 2018 due to licensing issues; the substance remains available as a prescription medication under other formulations and has since been used clinically for following or , with evidence suggesting benefits in reducing neurological deficits. Outside , it lacks regulatory approval from major agencies like the FDA and is often available as a or , though its sale for human consumption is restricted in many countries due to unverified safety and efficacy data in those contexts. Pharmacologically, phenylpiracetam demonstrates a broader spectrum of activity compared to , including , antiasthenic, , , and effects, potentially mediated by modulation of neurotransmitter systems such as (via inhibition of the ) and glutamate receptors, without significant involvement. It exhibits high (nearly 100%) and rapid (20–40 minutes), with neuroprotective properties observed in experimental models of and ischemia, where it attenuates pro-inflammatory cytokines like TNF-α and IL-1β. Additionally, it shows adaptogenic and mitochondrial-protective actions, supporting its potential in neurodegenerative conditions, , and metabolic disorders like syndrome-related , though long-term clinical data remains limited outside studies. Safety profiles indicate mild side effects such as or at higher doses, with contraindications for those with or severe renal impairment.

Medical Uses

Indications

Phenylpiracetam, known commercially as Phenotropil in , is approved by the State Pharmacological Committee of for treating cerebrovascular insufficiency, cognitive deficits resulting from organic brain lesions such as and , , , attention and memory disorders, asthenic states, post-traumatic syndromes, adaptation issues, obesity, convulsive disorders, , and chronic alcoholism in various neurological conditions. These indications stem from its classification as a agent that supports integrative brain activity and . Beyond approved uses, phenylpiracetam is employed off-label or in investigational contexts for enhancing physical and mental performance in healthy individuals, aiding recovery from brain injuries like , and managing associated with neurological disorders. For instance, its properties have been utilized to counteract mental in neuropsychiatric conditions. This application underscores its role in performance enhancement, where it demonstrates 30-60 times greater potency than in improving cognitive functions, due to the structural addition of a that enhances and efficacy.

Dosage and Administration

Phenylpiracetam is available primarily in the form of 100 mg oral tablets, with powder forms sometimes used for reconstitution in non-official contexts; no injectable formulations are approved for clinical use. The standard dosing regimen for cognitive enhancement and related indications consists of 100-250 mg per dose, typically administered twice daily (morning and early afternoon), yielding a total daily intake of 200-300 mg. Higher doses up to 750 mg per day, divided into two administrations, may be employed for acute conditions such as severe asthenia or post-traumatic recovery. Treatment courses are generally limited to 2-4 weeks or up to 1 month to minimize the risk of , with repetition possible after a 1-month interval; longer regimens, such as 2-3 months at 100 mg/day for chronic asthenia or multiple 400 mg/day courses over 1 year for rehabilitation, have been reported in clinical settings. Administration is oral, with doses exceeding 100 mg per day split to avoid evening intake and potential sleep disruption; it may be taken with or without food, though combining with meals can help reduce gastrointestinal discomfort in sensitive individuals. Dosing varies by condition—for instance, 100 mg/day for adjunct therapy or 200 mg/day for recovery—necessitating physician oversight for tailored regimens. In elderly patients or those with hepatic impairment, lower starting doses (e.g., 100 /day) are advisable due to potential reduced clearance, though specific adjustment guidelines mirror those for related racetams like , with no routine modification solely for hepatic issues unless combined with renal compromise. For stimulant-like effects, daily intake should not exceed 400 to balance efficacy and safety.

Adverse Effects

Contraindications

Phenylpiracetam is absolutely contraindicated in cases of to the active ingredient, pyrrolidone derivatives, or any excipients in the formulation, as this may lead to allergic reactions. It is also contraindicated during and , owing to a lack of adequate clinical data establishing safety for the , , or mother, despite no observed teratogenic or embryotoxic effects in experimental animal studies. Use in children under 18 years of age is contraindicated due to insufficient evidence from clinical trials regarding and efficacy in pediatric populations. Absolute contraindications further extend to acute psychotic states, particularly those involving , where administration is not advised to avoid potential worsening of symptoms. Relative contraindications include severe , as phenylpiracetam may elevate and exacerbate cardiovascular strain. Similarly, patients with a history of , such as severe , require careful monitoring or avoidance, given the drug's potential to influence hemodynamic parameters. Individuals with a history of panic attacks should use it with caution, as it may intensify anxiety or related symptoms. In special populations, caution is advised for elderly patients with renal impairment, due to the risk of altered from reduced clearance, and for those with severe hepatic dysfunction, where dosing adjustments or avoidance may be necessary. These contraindications stem primarily from phenylpiracetam's stimulant-like effects, which can provoke , , or elevations in , potentially leading to adverse outcomes in at-risk groups.

Side Effects

Phenylpiracetam is generally well-tolerated in clinical use, with most adverse reactions being mild and limited to the initial period of treatment. Common side effects, reported in some patients, include , (such as ), increased , and sensations of heat or flushing. These effects typically occur during the first 1-3 days of and tend to diminish as tolerance develops rapidly. is particularly associated with dosing within 8 hours of bedtime and can be mitigated by administering the drug earlier in the day. Rare side effects may encompass , , , and allergic reactions manifesting as , though these are infrequently documented in clinical observations. Management of side effects generally involves dose reduction or temporary discontinuation to allow resolution. For instances of , supportive measures such as sedatives may be employed if symptoms persist. In patients prone to , caution is advised due to potential elevation, aligning with contraindications for those with cardiovascular risks. Long-term use at therapeutic doses (up to 3 months, with breaks of at least 30 days) carries a low risk of dependence, as no addictive potential has been reported in available . To minimize and recurrence, cycling the medication—such as using it intermittently—is recommended.

Toxicity and Overdose

Phenylpiracetam demonstrates low in animal models, with an oral LD50 exceeding 5,000 mg/kg in , such as 6,800 mg/kg in mice. This indicates a wide relative to typical human doses of 100-200 mg, contributing to its generally safe profile at recommended levels. No human fatalities from phenylpiracetam overdose have been reported in the scientific literature, and documented cases of intoxication are absent, underscoring its low risk of lethality. Overdose symptoms, when they occur from excessive intake, may manifest as amplified versions of common adverse effects, including severe psychomotor agitation, hypertension, and tachycardia, with onset typically within 1-2 hours of ingestion. Treatment for overdose is primarily supportive, focusing on symptom management such as benzodiazepines to control and antihypertensives to address elevated ; no specific exists. may be considered if ingestion was recent and the patient presents promptly, alongside monitoring for cardiovascular and neurological effects. Regarding , prolonged use can lead to , requiring higher doses for equivalent effects, though data remain limited due to the compound's restricted clinical use.

Pharmacology

Pharmacodynamics

Phenylpiracetam exerts its primary pharmacological effects through selective inhibition of the (), thereby increasing synaptic levels. The (R)- demonstrates higher potency in this regard, with a Ki value of 16 μM for DAT binding in rat brain membranes, compared to 56 μM for the (S)-. This mechanism underlies its stimulant-like properties without significant affinity for norepinephrine or serotonin transporters. The compound also exhibits neuroprotective and actions, modulating production in response to inflammatory stimuli. In (LPS)-induced models in male mice, (R)-phenylpiracetam attenuates overexpression of pro-inflammatory s such as TNF-α and IL-1β, as well as inducible (iNOS). Under conditions of cyclophosphamide-induced , phenylpiracetam normalizes levels of IL-1, IL-4, and IL-6, supporting its role in immune modulation. Enantioselective differences are prominent in behavioral effects. The (R)-enantiomer is more potent in enhancing locomotor activity and memory retention, increasing horizontal activity at doses of 10 and 50 mg/kg in and improving performance in passive avoidance tests at 1 mg/kg, whereas the (S)-enantiomer shows weaker or absent effects in these paradigms. In contrast, the (S)-enantiomer reduces body weight gain and fat mass in obese models without stimulating locomotion. In studies, phenylpiracetam promotes increased alertness and anti-asthenic effects, evidenced by enhanced operant behavior and reversal of scopolamine-induced , without inducing amphetamine-like dependence or significant locomotor overstimulation at therapeutic doses. These actions contribute to its cognitive-enhancing profile through and improved synaptic signaling.

Pharmacokinetics

Phenylpiracetam exhibits rapid absorption from the after , with complete of approximately 100% in humans. Peak plasma concentrations are reached within 1 hour post-ingestion. The compound is widely distributed to various tissues and efficiently penetrates the blood-brain barrier, facilitating its effects. Phenylpiracetam undergoes minimal hepatic and is predominantly excreted unchanged, with roughly 40% eliminated via the and 60% through the and sweat. There are no known active metabolites. Its elimination ranges from 3 to 5 hours, allowing for complete clearance from the body within about 24 hours. This pharmacokinetic profile aligns with typical twice-daily dosing recommendations.

Chemistry

Chemical Structure

Phenylpiracetam, systematically named 2-(2-oxo-4-phenylpyrrolidin-1-yl)acetamide, consists of a pyrrolidinone ring substituted with a phenyl group at the 4-position and an acetamide side chain at the nitrogen. This structural modification distinguishes it from its parent compound, piracetam, by incorporating the phenyl ring, which enhances lipophilicity for improved blood-brain barrier penetration and confers greater potency in nootropic effects. The molecular formula is C_{12}H_{14}N_{2}O_{2}, with a molecular weight of 218.25 g/mol. Phenylpiracetam exists as a of (R)- and (S)-, where the (R)- exhibits the primary , including enhanced memory improvement and locomotor stimulation compared to the (S)-form. As a white to off-white crystalline powder, phenylpiracetam has a of 132–134 °C and demonstrates in of approximately 10–18.5 mg/mL, particularly with gentle warming. Its calculated octanol-water partition coefficient () is 0.1, reflecting moderate lipophilicity relative to ( ≈ -1.1). Under standard storage conditions, such as at -20 °C in a , phenylpiracetam remains stable for at least one year, though it may undergo in strong acidic or basic media, consistent with its functionality.

Synthesis and Derivatives

Phenylpiracetam is synthesized through a multi-step process that typically begins with the formation of the core 4-phenyl-2-pyrrolidone structure, followed by N- to introduce the side chain. A representative method for the step involves treating 4-phenyl-2-pyrrolidone with in to form the of the , which is then reacted with chloro at controlled temperatures (10°C , followed by stirring at 15°C for 16 hours). The reaction mixture is quenched with cold water, and the product is isolated by and , affording phenylpiracetam in 53% yield (73% based on converted starting material) with 96% purity. Alternative routes to the 4-phenyl-2-pyrrolidone have been developed, including a novel cascade approach starting from N-Boc-protected N-propargyl . This involves a aryl migration to generate an α,β-unsaturated-β-aryl-γ-lactam derivative, followed by and deprotection to yield the racemic pyrrolidone, which can then be converted to phenylpiracetam via amidation. This method provides efficient access to the core structure and has been extended to prepare in racemic or chiral forms using simple aryl precursors. Direct derivatives of phenylpiracetam are limited, with phenylpiracetam hydrazide representing an experimental analog where the terminal is replaced by a group; it has been synthesized via aminolysis of the intermediate ester in the radical route and is noted for potential properties. No major commercial derivatives exist, though structurally related racetams such as and share the pyrrolidone core but differ in substitution patterns and are not derived from phenylpiracetam itself. Enantioselective preparation of phenylpiracetam focuses on isolating the (R)-enantiomer (MRZ-9547), which exhibits enhanced pharmacological activity compared to the racemate. Chiral resolution of the racemic mixture is achieved through normal-phase chromatography on a chiral stationary phase, enabling separation of the enantiomers for further study. The original synthesis of phenylpiracetam was developed and patented in 1983 by researchers at the Russian Academy of Sciences.

History

Development

Phenylpiracetam, a phenylated derivative of , was first synthesized in 1983 at the Institute of Biomedical Problems of the by a team of researchers including Iu. G. Bobkov, I. S. Morozov, O. M. Glozman, L. N. Nerobkova, and L. A. Zhmurenko. This structural modification involved adding a to the piracetam molecule to potentially enhance its and . The compound was initially assigned the code name Carphedon during its development phase. The primary purpose of phenylpiracetam's development was to address cognitive and physical impairments associated with prolonged , particularly the effects of on cosmonauts in the . Researchers aimed to create a agent capable of improving mental performance, stress tolerance, and overall resilience under extreme conditions such as microgravity and isolation. This initiative reflected broader efforts in Soviet biomedical research to support human by mitigating the neurological and physiological toll of orbital missions. Early preclinical testing in the 1980s utilized animal models to evaluate phenylpiracetam's pharmacological profile, revealing superior effects compared to . In these studies, the compound demonstrated stronger activation of operant behavior, inhibition of post-rotational , and prevention of induced by electroshock or . It also exhibited enhanced resistance to stress factors, including improved physical performance and adaptation in models of and emotional strain, positioning it as a promising for high-stress environments. Initial evaluations within the further indicated benefits for cosmonauts, such as bolstered memory, focus, and endurance during simulated and actual space conditions. Over time, phenylpiracetam became known under additional names, including the brand Phenotropil in and the fonturacetam, reflecting its progression from experimental code name to recognized pharmaceutical entity.

Regulatory Approval

Phenylpiracetam was approved for medical use in in 2003 by the State Pharmacological Committee as a for indications including cerebrovascular deficiency, , , and disorders. Its development for Soviet cosmonauts to enhance cognitive and physical performance under extreme conditions influenced this early regulatory pathway. In 2017, production of the branded formulation Phenotropil was discontinued in due to licensing conflicts between manufacturer Valenta Pharm and the Ministry of Health, leading to a temporary withdrawal from the market. This issue was resolved, with reinstatement occurring in through alternative formulations such as Nanotropil, followed by the return of Phenotropil in 2022. Phenylpiracetam has not received approval from major international regulatory bodies, including the U.S. (FDA), the (EMA), or the (WHO). It remains classified as a prescription in and select Eastern European countries, such as and , for neurological conditions. The limited global adoption stems primarily from the absence of large-scale clinical trials conducted to Western regulatory standards, which has hindered submissions to agencies like the FDA and . Additionally, concerns over its stimulant-like properties, including increased and noradrenaline activity, have raised issues regarding potential for and doping in , where it has been prohibited by the since 1998. As of 2025, phenylpiracetam continues to be available by prescription in for cognitive and neurological support, with no new international approvals reported.

Society and Culture

Legal Status

Phenylpiracetam is classified as a prescription-only in , where it is authorized for medical use and available in pharmacies with a doctor's prescription. In other Eastern European countries such as and , it holds similar prescription status and is approved for therapeutic applications. In the United States, phenylpiracetam has not been approved by the (FDA) for any medical purpose and is considered an unapproved drug, rendering its marketing or sale as a , food, or unlawful. Although it is not scheduled as a by the (DEA), personal possession is generally legal, but importation is restricted due to its unapproved status, leading to a gray market where it is often sold online as a or supplement. As of 2025, there have been no changes to its DEA scheduling. Within the , phenylpiracetam is not authorized as a or by any regulatory authority and is therefore illegal to market or sell for human consumption. It has been detected in substandard or falsified products intercepted by official medicines control laboratories, highlighting ongoing enforcement against unauthorized imports. Specific member states, such as , align with this EU-wide prohibition on its sale. In , phenylpiracetam is not authorized for human use and is prohibited from import or distribution without approval from the (), classifying it as a Schedule 4 substance requiring a prescription, though no such approved products exist. As of 2025, regulatory scrutiny on imports has intensified globally, with increased customs seizures of unapproved substances like phenylpiracetam to prevent illicit market entry.

Use in Sports

Phenylpiracetam, also known as fonturacetam or carphedon, has been employed by athletes seeking to boost physical and cognitive performance. Studies indicate it enhances physical and to , increases to environments, and improves reaction times, making it particularly useful for involving prolonged exertion or extreme conditions. Athletes have reported benefits in and post-exercise , attributed to its stimulant-like effects on and . Due to these performance-enhancing properties, phenylpiracetam was the first banned in when the added it to its prohibited list in 1998; it remains classified under S6 (stimulants) on the (WADA) Prohibited List, where it is forbidden in-competition. The substance's history includes detections in athletes, notably during major events, contributing to doping scandals. Detection occurs primarily through urine testing via liquid chromatography-mass spectrometry (LC-MS), a standard method for identifying stimulants in anti-doping controls; WADA prohibits any detectable presence without a specified threshold. Prominent cases involve competitors, such as biathlete Olga Pyleva, who tested positive at the 2006 Winter Olympics, resulting in the loss of her and a two-year suspension. In 2012, gymnast Krylov was sanctioned by the after a positive test at the World Cup, leading to a two-year ban. These and similar incidents among athletes prompted broader sanctions under the 2016 McLaren report, which exposed state-sponsored doping schemes. The prohibition stems from phenylpiracetam's effects, which confer an unfair competitive edge by elevating levels to heighten alertness and physical output, comparable to banned agents like .

Manufacturing and Availability

Phenylpiracetam is primarily manufactured by the Russian pharmaceutical company Valenta Pharmaceuticals JSC under the brand name Phenotropil. The company, established in 1997, operates production facilities in and focuses on developing and producing prescription drugs in compliance with (GMP) standards. Raw materials for phenylpiracetam, including active pharmaceutical ingredients, are commonly sourced from suppliers in , where multiple manufacturers produce the compound for global export. Production of Phenotropil was temporarily suspended in 2018 due to expired licensing agreements but resumed in 2022, with Valenta announcing initial shipments exceeding 100,000 packages to distributors by the end of May that year. As one of Russia's top pharmaceutical producers, Valenta maintains annual output capabilities supporting widespread domestic supply, though specific volumes for phenylpiracetam are not publicly detailed beyond these resumption figures. In , phenylpiracetam is widely stocked in pharmacies as a prescription for conditions like and asthenia, available in 100 mg tablets. Internationally, it is not approved by regulatory bodies such as the FDA or , limiting official exports primarily to (CIS) countries where it holds similar prescription status. Outside these regions, availability occurs through gray-market online vendors, such as those shipping from or , often at prices around $1.00–$1.30 per 100 mg tablet for a pack of 30. This unofficial distribution meets demand in Western markets but raises concerns over and legal compliance.

Research

Preclinical Studies

Preclinical research on phenylpiracetam, primarily conducted in models during the , demonstrated enhancements in cognitive function, particularly retention and learning. In studies using rats and mice, of phenylpiracetam improved in passive avoidance tasks and spatial maze tests, where treated animals exhibited longer retention latencies and reduced errors compared to controls, indicating nootropic effects without significant side effects at therapeutic doses. These findings were supported by operant behavior assays, where phenylpiracetam activated exploratory and adaptive responses more potently than . Behavioral investigations in mice revealed that phenylpiracetam increased spontaneous locomotor activity in open-field tests without inducing or hyperactivity at low doses, while the (R)- specifically stimulated movement. Anxiolytic-like effects were observed in the elevated plus-maze , with treated mice spending more time in open arms, suggesting reduced anxiety-related avoidance. Binding assays confirmed its pharmacodynamic profile, including inhibition of dopamine , consistent with elevated striatal levels in rodents. A review by Gromova et al. reaffirmed phenylpiracetam's immunomodulatory potential in models, where it suppressed pro-inflammatory production, such as IL-6 and TNF-α, in activated macrophages, pointing to mechanisms relevant to . However, much of the foundational preclinical data originates from Soviet-era investigations, with limited independent replications in contemporary Western research, highlighting the need for further validation in diverse models.

Clinical Trials

Clinical trials of phenylpiracetam, primarily conducted in , have explored its efficacy in various neurological conditions, with a focus on cognitive and motor recovery. A controlled study involving 400 patients with ischemic stroke, published in 2010, examined the effects of three courses of phenotropil (phenylpiracetam) as part of comprehensive . In this trial, 200 patients received the drug alongside standard therapy, while the control group of 200 underwent alone; results showed significantly better restoration of neurological status and daily activities in the treatment group (p < 0.0001), indicating faster compared to controls. In trials addressing cognitive disorders, particularly among the elderly with mild impairment, phenylpiracetam at 200 mg/day has demonstrated enhancements in recall. Small-scale studies in patients with organic brain lesions, including age-related cognitive decline, reported improved cognitive function and reduced symptoms of asthenia, supporting its properties in this population (p < 0.05 for improvements in select assessments). Limited investigations have also evaluated phenylpiracetam in , typically involving fewer than 100 participants per study. In patients, adjunctive use showed stabilization of defects and improved visual function in approximately 80% of cases over six months, alongside reduced . For Parkinson's-related , development efforts for the (R)- have indicated potential reductions in symptoms based on preclinical data and descriptions, though larger confirmatory clinical trials are lacking. Recent analyses in 2024 highlight phenylpiracetam's potential through monoaminergic enhancement for cognitive benefits. A review by Gromova et al. prospects its applications in neurological disorders, suggesting neuroprotective roles via inhibition and reduced in experimental models, which may inform future clinical uses. As of November 2025, no major new large-scale clinical trials have been reported, and most existing trials are small, non-randomized, or conducted solely in , with limited double-blind, placebo-controlled studies outside this region; no large-scale Phase III trials support Western regulatory approval. Results in healthy volunteers have been inconsistent, often showing minimal cognitive enhancement. Adverse event rates remain low across reported trials, ranging from 5-10%, primarily involving mild , , or , with no serious events requiring discontinuation. There is a need for independent international validation of studies.