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Dimercaprol

Dimercaprol, also known as British anti-Lewisite (BAL), is a synthetic dithiol chelating agent with the C₃H₈OS₂ and the systematic name 2,3-dimercapto-1-propanol. It appears as a clear, colorless with a pungent and is soluble in water, serving primarily as an for poisonings by forming stable ring complexes that facilitate the metals' urinary excretion. Developed during at Oxford University by biochemist Sir Rudolph Peters in 1940, it was originally designed to counteract the effects of , an arsenic-based agent. The compound's mechanism of action involves its two sulfhydryl (-SH) groups binding to toxic metals such as , mercury, , lead, and , thereby inactivating them and preventing interference with essential enzymes; its lipophilic nature allows it to cross the blood-brain barrier, making it effective against involvement in poisoning. Administered exclusively via deep due to its poor oral bioavailability, dimercaprol is FDA-approved for treating acute toxicities from , , mercury, and lead (concomitantly with edetate calcium disodium injection for lead), with dosing regimens typically involving 2.5–5 mg/kg every 4 hours for the first day(s), tapering over 3–10 days depending on the severity and metal involved—for instance, 4 mg/kg every 4 hours for lead levels exceeding 100 mcg/dL in adults or 70 mcg/dL in children. It has also been used historically in combination with edetate calcium disodium for lead encephalopathy and as a short-term therapy for , a accumulation disorder, though it has largely been supplanted by oral chelators like due to its parenteral route and side effects. While effective, dimercaprol carries notable adverse effects, including , , , , and injection-site , with fever occurring in up to 30% of pediatric cases; it is contraindicated in hepatic insufficiency (except post-arsenical ) and , with extreme caution advised or discontinuation if acute renal insufficiency develops during therapy, and in G6PD deficiency due to risk of . No clinically apparent has been reported, likely owing to its brief courses of use, and it may even stabilize liver enzymes in management. Despite the development of less toxic alternatives like succimer (DMSA), dimercaprol remains a critical agent for severe, life-threatening exposures where rapid intervention is required.

Chemistry

Chemical Structure and Properties

Dimercaprol, chemically known as 2,3-disulfanylpropan-1-ol, is an with the molecular formula C₃H₈OS₂ and a molecular weight of 124.23 g/. Its structure features a three-carbon chain bearing a hydroxyl group (-OH) at position 1 and groups (-SH) at positions 2 and 3, rendering it a dithiol capable of due to the nucleophilic sulfhydryl moieties. The IUPAC name is 2,3-disulfanylpropan-1-ol, with common synonyms including British anti-Lewisite (BAL), 2,3-dimercapto-1-propanol, and dithioglycerol; its is 59-52-9. Physically, dimercaprol appears as a clear, colorless to pale yellow viscous liquid at . It has a density of approximately 1.24 g/cm³ at 20°C and boils at 140°C under reduced pressure of 40 mmHg. The compound exhibits limited in (about 1 part in 11 to 20), is miscible with and , and shows moderate in vegetable oils such as (approximately 1 part in 10 to 18). Dimercaprol is chemically reactive and sensitive to oxidation, particularly in air or aqueous media, where the groups can form disulfides. To maintain stability, it should be stored in airtight containers under an inert atmosphere like , at temperatures between 2°C and 10°C, and protected from light.

Synthesis

Dimercaprol, also known as British anti-Lewisite (BAL), was originally synthesized during through a two-step process beginning with the bromination of to form 2,3-dibromopropan-1-ol (also known as 1,2-dibromohydrin), followed by its reaction with under pressure. This method, first detailed in scientific literature in 1945, yielded the compound as a clear, colorless to pale yellow liquid with a strong . The key reaction step is a double , in which the two atoms on 2,3-dibromopropan-1-ol are displaced by mercapto () groups from the hydrosulfide ions, forming the vicinal dithiol structure essential to dimercaprol's properties. To optimize yields, the reaction is typically conducted in a like or , with the prepared by saturating a solution with gas, followed by heating the mixture with the dibromohydrin at around 40°C under pressure; subsequent acidification isolates the product. Modern variations of the synthesis maintain the core approach but incorporate refinements for improved purity and safety. One such method uses gas directly with 2,3-dibromopropan-1-ol under controlled conditions to generate the hydrosulfide , enhancing reaction efficiency and reducing side products. An alternative industrial process involves the of hydroxypropylene trisulfide using a catalyst like at elevated temperature and pressure, followed by to obtain high-purity dimercaprol at 80–140°C under reduced pressure (less than 1 mmHg). Purification commonly entails to separate the product from impurities such as 1,2,3-trimercaptopropane, ensuring pharmaceutical-grade quality. Synthesis challenges include the handling of toxic intermediates like gas, which poses significant inhalation and exposure risks during preparation of . During production, scalability was limited by the need for pressurized reactors and careful control of exothermic substitutions to prevent side reactions, though wartime demands led to rapid process adaptations for bulk manufacturing.

Pharmacology

Mechanism of Action

Dimercaprol exerts its therapeutic effects primarily through of ions, facilitated by its two vicinal sulfhydryl (-SH) groups. These groups form stable, non-ionizable coordinate covalent bonds with metals such as , mercury, , and lead, creating five-membered chelate rings that neutralize the toxic ions. For instance, with trivalent (As(III)), dimercaprol forms As-S bonds in complexes like the 1:2 As-BAL species, with a stability constant of approximately log β = 11.6 at physiological , ensuring strong binding affinity. The resulting dimercaprol-metal complexes are lipophilic, enabling them to redistribute metals from intracellular sites and tissues into the bloodstream for subsequent . This allows rapid penetration into cells and concentration in organs like the liver, kidneys, and , where often accumulate. Primarily, these complexes are eliminated via the largely unchanged, while unbound dimercaprol is metabolized to conjugates for , promoting the removal of bound toxins and reducing systemic toxicity. At the molecular level, dimercaprol competes with endogenous biomolecules for metal binding, particularly displacing toxic ions from sulfhydryl-containing enzymes. like and mercury inhibit enzymes such as by binding to their critical -SH groups, disrupting metabolic pathways; dimercaprol reverses this by preferentially chelating the metals, thereby restoring enzymatic activity. This competitive mechanism is most effective when administered soon after exposure, as it prevents rather than reactivates inhibited enzymes. However, dimercaprol's mechanism contributes to a narrow , as its sulfhydryl groups can also bind essential metals like and , potentially leading to deficiencies or increased in vulnerable tissues. For example, it promotes urinary of these trace elements, which may require monitoring during therapy to avoid imbalances. This non-selectivity underscores the need for careful dosing to maximize benefits against toxic metals while minimizing interference with physiological metal .

Pharmacokinetics

Dimercaprol is administered exclusively via deep , as it is not absorbed orally owing to its lipophilic, oily formulation. Following intramuscular administration, it is rapidly absorbed into the bloodstream, achieving peak plasma concentrations within 30 to . The drug is highly lipophilic and distributes extensively into tissues, particularly the intracellular compartment, with the highest concentrations observed in the liver, kidneys, , and . It crosses the blood-brain barrier and forms protein-bound chelates with , aiding in their mobilization and excretion. Metabolism of dimercaprol is minimal, primarily occurring in the liver where the unbound drug undergoes and oxidation to inactive metabolites, including disulfide derivatives. The metal-chelating complexes, however, are largely excreted without significant , which facilitates the removal of toxic metals from the body. Excretion occurs primarily via the renal route through glomerular filtration of the dimercaprol-metal complexes, with some biliary and fecal elimination. The is short, ranging from 4 to 6 hours, with complete and typically occurring within 4 hours in healthy individuals. Impaired renal function prolongs elimination, thereby increasing the of from accumulated drug or redistributed metals.

Clinical Applications

Indications for Use

Note: As of , dimercaprol is no longer commercially available due to manufacturing discontinuation; its use is limited, and alternative chelators such as succimer (DMSA) or should be considered for poisonings. Dimercaprol is primarily indicated for the treatment of acute poisoning by , including exposure to , a vesicant agent. It is also approved for acute poisoning from gold salts, often associated with chrysotherapy overdoses in treatment, and from inorganic and elemental mercury. For , dimercaprol is indicated in severe cases, particularly when used concomitantly with edetate calcium disodium (EDTA) for acute lead or blood lead levels exceeding 100 mcg/dL in adults or 70 mcg/dL in children. As an adjunctive therapy, dimercaprol is combined with EDTA in the management of severe to enhance metal excretion. It is also used short-term for chelation in , particularly in cases with severe neurological symptoms, due to its ability to cross the blood-brain barrier, though it has largely been replaced by less toxic agents like . Emerging and off-label applications include potential treatment of acute poisoning by , , or , supported by its inclusion in guidelines for these toxicities despite limited clinical evidence. Investigational uses extend to neutralizing toxins, with in vitro studies demonstrating inhibition of zinc-dependent metalloproteinases in viper venoms, though human data remain absent. Dimercaprol is included on the World Health Organization's Model List of Essential Medicines as an for poisonings. Its is greatest when administered within hours of , such as 1-2 hours for acute inorganic , and it is not recommended for chronic or low-level exposures where it shows minimal benefit.

Administration and Dosage

Dimercaprol is administered exclusively via deep as an oil suspension, supplied in 3 mL ampules containing a 10% solution of dimercaprol in with 20% for stabilization. Intravenous administration is strictly contraindicated due to the risk of severe toxicity, including and renal failure. The formulation is stored at controlled room temperature (20–25°C) and remains stable for up to two years when protected from light and excessive heat. For adults, the standard dosage regimen varies by the severity of poisoning, such as or mercury intoxication. In mild cases of or poisoning, 2.5 mg/kg is given four times daily for the first two days, followed by twice daily on day 3, and once daily for the subsequent 10 days. For severe cases, the dose increases to 3 mg/kg every 4 hours for the first two days (up to 12 doses), then four times on day 3, and twice daily thereafter for 10 days. In , treatment begins with 5 mg/kg, followed by 2.5 mg/kg once or twice daily for 10 days. The total course typically lasts 3–5 days for acute lead encephalopathy when combined with edetate calcium disodium, starting at 4 mg/kg every 4 hours. Pediatric dosing mirrors adult regimens on a mg/kg basis, generally 3 mg/kg per dose adjusted for body weight, for conditions like , mercury, or . Special caution is advised in children under 2 years due to a higher incidence of adverse effects, such as fever occurring in up to 30% of pediatric patients, necessitating close observation during administration. Injections should alternate sites, preferably in the upper outer quadrant of the buttocks, to minimize local pain and tissue irritation. Treatment monitoring includes baseline assessments of renal and hepatic , with serial measurements of blood and levels to evaluate and guide dose adjustments. Supportive measures, such as intravenous to maintain alkaline (pH >7), are essential to enhance metal and protect renal . Therapy should be discontinued if signs of dimercaprol or worsening organ emerge.

Safety Profile

Adverse Effects

Dimercaprol therapy is associated with a range of adverse effects, occurring in up to 50-65% of patients receiving therapeutic doses of 4-5 mg/kg intramuscularly, though most are mild and self-limiting. Common effects include pain at the injection site, which may lead to hematomas or sterile abscesses due to the intramuscular administration; and , often the most frequent gastrointestinal symptoms; ; fever exceeding 38°C, reported in about 30% of pediatric patients; ; and accompanied by , one of the most consistent dose-proportional responses. Additional common manifestations encompass burning sensations in the , , eyes, or ; or tingling in the hands; excessive sweating, lacrimation, salivation, and ; weakness; restlessness; anxiety; chest tightness; and generalized . These symptoms typically arise 15 to 30 minutes post-injection and resolve within 1 to 4 hours without cumulative from repeated doses. Serious adverse effects are less common but can include , manifesting as elevated creatinine levels or , particularly if the dimercaprol-metal chelate dissociates in acidic urine; ; and, in rare cases at high doses, seizures, , or coma. Dimercaprol is potentially on its own and may exacerbate the renal effects of certain metals like iron. Allergic reactions can occur due to the vehicle, including rash, urticaria, or in sensitive individuals. Other serious risks involve in patients with (G6PD) deficiency and transient in children. The drug exhibits a narrow therapeutic window. At therapeutic doses above 3 mg/kg every 4 hours or less, up to two-thirds of patients may experience adverse effects. Doses exceeding 5 mg/kg can lead to severe such as , convulsions, or within 30 minutes, subsiding after about 6 hours. can induce metal redistribution, potentially causing transient worsening of symptoms, for example, by mobilizing lead to the and increasing . Management of adverse effects involves supportive measures, including antiemetics for and , antihistamines to alleviate symptoms like burning or anxiety, and monitoring of such as and . Renal function should be closely observed, with urine alkalinization to prevent chelate dissociation and worsening ; should be discontinued if renal impairment progresses. No specific exists for dimercaprol toxicity, so cessation of administration allows resolution of symptoms.

Contraindications and Precautions

Dimercaprol is contraindicated in patients with known to the drug or its components, including , as the formulation is suspended in , which can precipitate severe allergic reactions. It is also absolutely contraindicated in cases of hepatic insufficiency, except when associated with post-arsenical , due to the risk of exacerbating liver toxicity. Additionally, dimercaprol should not be used for poisoning involving iron, , , or similar metals, as it forms more toxic complexes that can worsen organ damage, particularly in the kidneys. Relative precautions are advised in several conditions to minimize risks. In patients with severe renal impairment or acute renal insufficiency, dimercaprol requires extreme caution or discontinuation if injury develops during , as the is potentially nephrotoxic and alkalinization of is recommended to protect renal . For individuals with (G6PD) deficiency, use is cautioned due to the potential for , and it should only be employed in life-threatening situations with close monitoring. During , dimercaprol is classified as Category C, indicating that animal studies are inadequate or absent, but potential fetal cannot be ruled out; it should only be used if the benefits clearly outweigh the risks, as safety data are limited. In , caution is warranted since it is unknown whether dimercaprol is excreted in human milk, potentially exposing nursing infants to harm. Hepatic disease beyond the specified exception also necessitates careful consideration to avoid toxicity. Drug interactions with dimercaprol primarily involve metals and require avoidance or timing adjustments. Concurrent administration with iron therapy is contraindicated, as dimercaprol forms nephrotoxic chelates with iron, increasing the of overload and renal damage; iron should be deferred for at least 24 hours after the last dimercaprol dose. Similarly, in exposure, while dimercaprol may increase excretion, it elevates concentrations, heightening toxicity. Combination with other chelators, such as EDTA, may be used for but requires monitoring to prevent additive toxicity. In special populations, dimercaprol demands vigilant use. Elderly patients face a higher of due to age-related declines in renal function, necessitating dose adjustments and monitoring. In , dosing must be precise, as children experience higher rates of adverse reactions like fever, and therapy should be limited to acute needs. There is limited data on long-term use, so dimercaprol is generally reserved for short-term in acute poisonings. For milder cases of metal poisoning, such as lead, succimer (DMSA) is often preferred as an oral alternative due to its better tolerability, water solubility, and lower toxicity profile compared to dimercaprol.

History and Development

Origins in

During , amid escalating fears of by German forces, British scientists at the initiated a urgent research program in 1940 to develop an antidote to potential arsenic-based agents. Led by biochemist Sir Rudolph Albert Peters, the effort was spurred by intelligence suggesting the deployment of vesicant gases like , and was supported by the British government's Chemical Defence Research Department. This work built on earlier biochemical insights into arsenic's interference with sulfhydryl (-SH) groups in enzymes, aiming to identify compounds that could competitively bind and neutralize such toxins. The primary trigger for the project was (2-chlorovinyldichloroarsine), an organoarsenic compound developed in the United States during but stockpiled for potential use in the war; it caused severe skin blistering, respiratory damage, and systemic toxicity by inhibiting essential like pyruvate oxidase. Peters' team screened dithiol compounds to restore function, focusing on those that could react with arsenic's trivalent form to form stable, excretable complexes. By 1945, they identified 2,3-dimercaptopropanol—later named dimercaprol or British anti-Lewisite (BAL)—as the lead candidate after extensive studies demonstrated its ability to protect sulfhydryl from arsenical inhibition. The key breakthrough came in through animal model testing, where dimercaprol proved highly effective in preventing lethality and tissue damage in mice exposed to vapor or injections; for instance, intramuscular administration shortly after exposure restored pyruvate oxidation in tissues and reduced mortality rates dramatically compared to controls. These findings, detailed in wartime reports and later published, confirmed BAL's rapid of . Safety was further evaluated in volunteers via simulated low-level exposures and applications, showing minimal adverse effects while effectively mitigating vesicant action without causing significant blistering. In response to the promising results, the and governments rapidly scaled production of dimercaprol, formulating it as a 10% oily for and an ointment for dermal use; code-named BAL, millions of doses were manufactured and distributed to Allied troops by 1945 for potential field deployment. Field trials involved simulated exposures on , validating its prophylactic and therapeutic efficacy in protecting against 's systemic effects. Although never used against lewisite in combat, dimercaprol's first clinical application occurred in 1946 for treating industrial , where it successfully enhanced excretion in affected workers.

Post-War Adoption and Evolution

Following the end of , dimercaprol, originally developed as British anti-Lewisite (BAL), rapidly transitioned from a wartime to a cornerstone therapy for poisonings. In the immediate post-war period, it demonstrated efficacy in treating industrial exposures and complications from arsenical treatments for , which were prevalent in both the and . Its chelating properties were soon applied to mercury, , and lead toxicities, revolutionizing management of accidental and iatrogenic poisonings, such as therapy for . A pivotal advancement occurred in 1951 when neurologist Derek Denny-Brown successfully employed dimercaprol to treat , a copper accumulation disorder, by promoting urinary excretion and halting disease progression in patients. This marked the first effective chelation-based intervention for the condition, previously fatal without treatment. However, dimercaprol's intramuscular administration, pungent odor, and side effects like and limited its long-term use. The 1950s saw further evolution with the introduction of oral alternatives. In 1956, John Walshe pioneered for , offering better tolerability and efficacy, which largely supplanted dimercaprol for chronic copper management. Concurrently, water-soluble analogs like (DMPS) and 2,3-dimercaptosuccinic acid (DMSA) were developed in the and in the late 1950s, providing safer, non-parenteral options for and . DMSA gained FDA approval in 1991 for pediatric , further reducing dimercaprol's role to severe cases, often combined with edetate calcium disodium for lead . Despite these shifts, dimercaprol remains a vital agent in emergency settings for acute , mercury, , and lead intoxications, particularly when blood lead exceeds 70 μg/dL in children or 100 μg/dL in adults. As of 2023, however, its production has ceased in the United States, resulting in limited availability, with alternative chelators such as succimer (DMSA) recommended for many cases. Its legacy endures in stockpiles for potential threats, underscoring over seven decades of adaptation from military origins to modern .