Doramectin is a semisynthetic avermectin, a macrocyclic lactoneantiparasitic agent derived from the fermentation of the bacterium Streptomyces avermitilis, featuring a distinctive cyclohexyl group at the C-25 position that enhances its potency against certain parasites.[1][2] It functions by binding to glutamate-gated chloride ion channels in invertebrate nerve and muscle cells, leading to hyperpolarization, paralysis, and death of targeted parasites, while exhibiting low toxicity in mammals due to poor penetration of the blood-brain barrier.[1][3]Primarily used in veterinary medicine, doramectin treats and controls a broad spectrum of internal parasites such as gastrointestinal roundworms (e.g., Ostertagia ostertagi, Haemonchus contortus), lungworms (Dictyocaulus viviparus), kidney worms (Stephanurus dentatus), and eyeworms (Thelazia spp.), as well as external parasites including grubs (Hypoderma spp.), sucking lice (Haematopinus spp., Linognathus spp.), biting lice, horn flies (Haematobia irritans), and mange mites (Sarcoptes scabiei, Psoroptes ovis).[4][5][2] It is approved for use in cattle and swine, with formulations including a 1% sterile injectable solution (10 mg/mL) administered subcutaneously or intramuscularly at doses of 200 mcg/kg for cattle and 300 mcg/kg for swine, and a topical solution (5 mg/mL) applied at 500 mcg/kg for cattle.[4][5]First approved by the U.S. Food and Drug Administration (FDA) in 1996 under the brand name Dectomax for injectable use in cattle (NADA 141-061), with the topical formulation approved in 1997 (NADA 141-095), doramectin has since gained generic approvals, including the first topical generic (DectoGard) in 2023. On September 30, 2025, the FDA conditionally approved Dectomax-CA1, an injectable doramectin formulation, for the prevention and treatment of New World screwworm myiasis in cattle.[6] It is also authorized in the European Union with established maximum residue limits to ensure food safety (e.g., 15 μg/kg in liver, 25 μg/kg in fat for cattle).[1][5][2] Pharmacokinetically, it is rapidly absorbed after administration, with a plasmahalf-life of approximately 6 days in cattle, primarily excreted via feces (87% within 14 days), and its major metabolite is 3"-O-desmethyldoramectin.[2] Safety profiles indicate it is well-tolerated at up to 25 times the recommended dose in cattle and 10 times in swine, though it is contraindicated in dairy cattle over 20 months of age or veal calves due to residue concerns, and it poses risks to aquatic organisms.[4][1]
Veterinary uses
Indications
Doramectin is approved for the treatment and control of a broad spectrum of internal and external parasites in livestock, primarily through injectable formulations. In cattle, it targets gastrointestinal roundworms such as Haemonchus placei, Ostertagia ostertagi (including inhibited larvae), and Cooperia spp., as well as lungworms (Dictyocaulus viviparus), eyeworms (Thelazia spp.), cattle grubs (Hypoderma bovis and H. lineatum), sucking lice (Haematopinus eurysternus, Linognathus vituli, Solenopotes capillatus), and mange mites (Psoroptes bovis, Sarcoptes scabiei).[7] It also provides control against horn flies (Haematobia irritans) via topical formulations.In swine, doramectin is indicated for gastrointestinal roundworms including Ascaris suum, Hyostrongylus rubidus, and Oesophagostomum spp., kidney worms (Stephanurus dentatus), lungworms (Metastrongylus spp.), sucking lice (Haematopinus suis), and mange mites (Sarcoptes scabiei var. suis).[7]For sheep and reindeer, doramectin is approved for similar nematodes and ectoparasites, including gastrointestinal roundworms (e.g., Haemonchus, Ostertagia, Trichostrongylus, Cooperia, Nematodirus spp.), lungworms, nasal bots (Oestrus ovis), and mites such as Psoroptes ovis.[8] These approvals exclude lactating animals producing milk for human consumption.[8]In September 2025, the FDA granted conditional approval for doramectin injection (Dectomax-CA1) for the prevention and treatment of New World screwworm (Cochliomyia hominivorax) myiasis in cattle, providing up to 21 days of protection against reinfestation.[6]Clinical trials have demonstrated doramectin's high efficacy, achieving 95-100% reduction in parasite burdens post-treatment across targeted species, such as gastrointestinal nematodes in cattle.[9]
Administration and dosage
Doramectin is primarily administered via injection in veterinary practice, with the standard formulation being a 1% (10 mg/mL) solution in an oily vehicle consisting of sesame oil and ethyl oleate, which facilitates prolonged absorption and efficacy from a single dose.[10] A topical pour-on formulation at 5 mg/mL is also available for cattle.[5]In cattle, the recommended dosage is 200 μg/kg body weight, given as a single subcutaneous injection in the anterior half of the neck behind the shoulder or intramuscularly in the posterior half of the neck.[10] For swine, the dosage is 300 μg/kg body weight, administered as a single intramuscular injection in the neck behind the ear.[10] In sheep, dosages of 200–300 μg/kg body weight are used via subcutaneous or intramuscular injection.[8] For reindeer, the dosage is 200 μg/kg body weight by subcutaneous injection.[8]Withdrawal periods vary by region and animal species but are established to ensure residue levels below maximum limits. In the United States, the meat withdrawal period is 35 days for cattle and 24 days for swine, with the product not approved for female dairy cattle 20 months of age or older or for veal calves due to residue concerns.[10] In the European Union (as of 2020), meat withdrawal periods are 70 days for cattle, reindeer, and sheep, and 77 days for swine, and the product is not authorized for lactating animals producing milk for human consumption.[11] Residues persist longer in fat tissues, sometimes requiring extended periods up to 77 days in certain formulations or regions.[12]Special considerations include strict adherence to aseptic injection techniques to prevent site reactions, accurate body weight determination to avoid underdosing—which can foster parasite resistance—and administration at the specified sites to minimize tissue damage.[10]Intramuscular injection is generally avoided in cattle where possible, favoring subcutaneous routes for reduced irritation.[8]
Pharmacology
Pharmacodynamics
Doramectin, a macrocyclic lactoneantiparasitic agent, exerts its effects by selectively binding to glutamate-gated chloride ion channels in the nerve and muscle cells of invertebrates. This binding increases the permeability of the cell membrane to chloride ions, leading to an influx that hyperpolarizes the cell membrane and disrupts normal neurotransmission.[13][3][14]The resulting physiological effects include flaccid paralysis of the parasite's body wall muscles, inhibition of pharyngeal pumping in nematodes that prevents feeding, and eventual death of the organism. In arthropods, the mechanism similarly targets muscle cells, causing paralysis and immobilization. These actions are highly potent, with in vitro studies demonstrating IC50 values for nematodeparalysis in the range of 0.1–1 nM, comparable to or slightly higher than those for related avermectins in larval development assays.[13][15]Doramectin's selectivity for invertebrates stems from the absence of glutamate-gated chloride channels in vertebrates; mammalian GABA-gated chloride channels, which share structural similarities, exhibit minimal binding affinity at therapeutic doses, limiting toxicity to the host. Compared to ivermectin, doramectin's cyclohexyl substitution enhances potency against certain ectoparasites, such as ticks and mites, contributing to a broader effective spectrum while maintaining similar endoparasitic efficacy.[3][14][15]
Pharmacokinetics
Doramectin is rapidly absorbed following subcutaneous injection in cattle, achieving peak plasma concentrations (Cmax) of approximately 28 ng/mL within 1-2 days post-administration at a dose of 200 μg/kg.[16] This absorption profile is influenced by the oily formulation (sesame oil and ethyl oleate), which promotes a depot effect at the injection site, though less than 1% of the dose remains there by day 21.[2]Due to its high lipophilicity, doramectin exhibits a large volume of distribution exceeding 10 L/kg, facilitating extensive accumulation in lipid-rich tissues such as fat and liver, where concentrations are notably higher than in plasma.[17] In cattle tissues, doramectin persists for up to 18 days, contributing to its prolonged therapeutic efficacy against parasites.[2]Elimination is slow, with a plasma elimination half-life of 4-6 days in cattle, reflecting its extensive tissue binding and gradual release.[18] Metabolism is minimal, primarily involving cytochrome P450-mediated O-demethylation to form 3"-O-desmethyldoramectin (8-19% of residues), with doramectin excreted largely unchanged. Excretion occurs predominantly via feces (80-90% of the dose within 14 days), with urinary elimination below 1%.[2]In swine, doramectin shows similar rapid absorption after subcutaneous or intramuscular injection, but with a shorter plasmahalf-life of approximately 3 days compared to cattle, leading to reduced tissue persistence.[3] The oily formulation extends the depot effect in both species, supporting single-dose regimens for sustained antiparasitic activity.[19]
Chemistry
Chemical structure
Doramectin has the molecular formula C50H74O14 and a molecular weight of 899.1 g/mol.[1]It is a semi-synthetic derivative of avermectin B1a, featuring a cyclohexyl group at the C-25 position that replaces the sec-butyl group found in ivermectin, which increases its lipophilicity.[1][20]The core structure consists of a 16-membered macrocyclic lactone ring fused to a hexahydrobenzofuran unit, a spiroketal ring system, and a disaccharide moiety composed of two oleandrose units.[21][22]Compared to abamectin, doramectin includes hydrogenation of the 22,23 double bond and the C-25 cyclohexyl substitution, contributing to enhanced chemical stability.[1][23]Doramectin exhibits lipophilic properties with a calculated logP value of approximately 4.5, is poorly soluble in water, and remains stable under neutral pH conditions.[1][24]
Synthesis
Doramectin is produced through a microbial fermentation process utilizing mutant strains of Streptomyces avermitilis engineered for enhanced yield of the avermectin B1 precursor, with directed biosynthesis incorporating a cyclohexyl group at the C-25 position.[25] These mutants, such as those with disruptions in the bkd gene cluster to prevent natural starter unit formation, are cultivated in nutrient-rich media containing carbon sources like corn starch and soybean flour, under aerobic conditions at approximately 28°C and 200 rpm agitation.[25] During fermentation, exogenous cyclohexanecarboxylic acid (CHC) is added as a precursor, which is activated to CHC-CoA and incorporated into the polyketide chain by the avermectin polyketide synthase, yielding doramectin as the primary product alongside minor avermectin analogs. This precursor-directed approach, a form of semi-synthetic modification, replaces the natural isobutyryl starter unit and enables selective substitution at C-25 without requiring post-fermentation chemical alkylation.[25]The fermentation process typically spans 7–10 days, with CHC feeding optimized in stages to maximize incorporation efficiency and minimize byproduct formation, achieving titers up to 700–800 mg/L in engineered industrial strains.[26]Pfizer developed the scalable industrial method, employing high-yield mutants like ATCC 31272 derivatives in large-scale bioreactors to produce batches suitable for veterinary formulations such as Dectomax®. No total chemical synthesis route exists for doramectin due to the complexity of its macrocyclic lactone structure; production relies entirely on this fermentation-based strategy.Following fermentation, the broth is processed through solvent extraction, typically with organic solvents like methanol or ethyl acetate, to isolate the crude product from mycelial biomass.[27] Further purification involves column chromatography on silica gel or reversed-phase resins to separate doramectin from impurities and analogs, followed by concentration, pulping with solvents such as methanol-water mixtures, and recrystallization to attain purity exceeding 95%, often >98% for pharmaceutical use.[27] This multi-step purification ensures the compound meets regulatory standards for veterinary applications, with overall yields from fermentation broth ranging from 70–90% depending on strain optimization.[26]
History
Discovery
Doramectin was discovered in the early 1990s by researchers at Pfizer Inc. as part of a broader avermectin development program building on the success of ivermectin, a leading antiparasitic introduced in the 1980s.[28][29]The compound emerged from directed screening of avermectin-producing Streptomyces avermitilis strains using mutational biosynthesis techniques. This process involved genetically modifying the microorganism and feeding it specific biosynthetic precursors, such as cyclohexanecarboxylic acid, to generate a series of novel avermectin analogs with varied C-25 substituents.[30][31] Doramectin, chemically identified as 25-cyclohexyl-5-O-demethyl-25-de(1-methylpropyl)avermectin A1a, was selected from this series for its enhanced antiparasitic potential.[29]The development aimed to surpass ivermectin's (dihydroavermectin B1a) spectrum of activity and persistence against parasites. Initial identification occurred through in vitro assays targeting nematodes, followed by in vivo evaluations that demonstrated superior efficacy.[29] The key publication detailing its synthesis and preliminary antiparasitic screening appeared in 1993.[29]Preclinical trials conducted in 1992–1993 further validated doramectin's broad efficacy, particularly against resistant parasites, using models such as the rat Trichostrongylus colubriformis infection and the rabbit Psoroptes cuniculi mite infestation, where it outperformed ivermectin at doses of 200 μg/kg subcutaneously.[29] These studies highlighted its prolonged plasma half-life of approximately 89 hours and persistent activity lasting up to 12 days in cattle against nematodes like Ostertagia ostertagi and Cooperia oncophora.[29]
Regulatory approvals
Doramectin received its initial regulatory approval from the U.S. Food and Drug Administration (FDA) on July 30, 1996, under New Animal Drug Application (NADA) 141-061, for use as the injectable solution Dectomax (1% doramectin) in cattle and swine to treat and control various internal and external parasites.[32]The European Medicines Agency (EMA), through its Committee for Veterinary Medicinal Products (CVMP), evaluated doramectin in a 1997 summary report, recommending maximum residue limits (MRLs) of 15 μg/kg in liver and 25 μg/kg in fat for cattle, and supported its authorization for use in cattle via subcutaneous injection at 0.2 mg/kg body weight, with formal EU-wide approval following in 1998; provisional MRLs based on these recommendations were established in 1999.[2][33][34]Generic versions of doramectin formulations began receiving approvals starting in 2005, enabling increased accessibility in various markets.[35]On September 30, 2025, the FDA granted conditional approval under NADA 141-616 for Dectomax-CA1 (doramectin injection) to prevent and treat screwworm myiasis (Cochliomyia hominivorax infestations) in cattle under emergency conditions, marking the first such approval for this indication amid threats near the U.S. border.[6]Doramectin is approved for veterinary use in over 50 countries globally and has been evaluated by the Joint FAO/WHO Expert Committee on Food Additives (JECFA) for residue limits, supporting its inclusion on lists of essential veterinary medicines for parasite control in livestock.[36]
Society and culture
Legal status
Doramectin is classified as an over-the-counter (OTC) veterinary drug in the United States for use in beef cattle and non-lactating dairy cattle, allowing purchase without a prescription for approved indications such as parasite control.[5] In contrast, it is designated as a prescription-only (Rx) veterinary medicine in countries like the Philippines, requiring veterinary oversight for dispensing.[37]Doramectin is approved exclusively for veterinary use and is not authorized for human consumption by regulatory bodies such as the U.S. Food and Drug Administration (FDA). Its veterinary-only status stems from documented risks of neurotoxicity in humans at elevated doses, including central nervous system effects observed in cases of intentional misuse, such as encephalopathy and altered mental status.[38]The FDA has established residue tolerances for doramectin in cattle tissues to ensure food safety, with a limit of 100 parts per billion (ppb) in liver (the target tissue) and 30 ppb in muscle; no tolerance is set for milk residues, as the drug is not approved for use in lactating dairy cattle.[39] Compliance is monitored through pre-slaughter withdrawal periods of 35 days for injectable formulations and 45 days for pour-on products to prevent violative residues in edible tissues.Doramectin is not classified as a controlled substance under U.S. regulations, such as the Controlled Substances Act, and faces no specific scheduling requirements. However, export of veterinary anthelmintics like doramectin may encounter restrictions in certain regions due to concerns over emerging anthelmintic resistance in livestock parasites, prompting guidelines for prudent use to mitigate global spread.[40][41]In the European Union, doramectin holds marketing authorization as a veterinary medicinal product with established maximum residue limits (MRLs) for food-producing animals, including 100 µg/kg in cattle liver and 15 µg/kg in milk.[42] Its use in organic farming is restricted under Regulation (EU) 2018/848, permitting application only as a last resort for therapeutic purposes after alternative methods fail, with extended withdrawal periods (up to twice those for conventional farming) to maintain organic integrity.[43]
Brand names
Doramectin is primarily marketed under the brand name Dectomax by Zoetis, which was originally developed by Pfizer Animal Health before the spin-off of Zoetis in 2013. The Dectomax injectable solution contains 1% w/v doramectin and is available in 100 mL, 250 mL, and 500 mL vials for subcutaneous administration in cattle and swine to treat internal and external parasites.[44]Zoetis also offers Dectomax Pour-On, a topical 0.5% doramectin solution formulated for weatherproof application on cattle, targeting gastrointestinal roundworms, lungworms, grubs, lice, and mites.[45]Generic equivalents of doramectin have entered the market following FDA approvals starting in 2023. The first generic topical solution, DectoGard by Aurora Pharmaceutical, was approved on January 11, 2023, as a bioequivalent to Dectomax Pour-On for parasite control in cattle. For the injectable form, Doraject (doramectin injection) by Cronus Pharma Specialities India Private Ltd. received approval on May 25, 2023, referencing Dectomax as the pioneer product. Additional generics include Doramectin Injection by Durvet and Doracide topical solution by Bimeda, approved in May 2025.[5][46][47][48]Combination products containing doramectin are limited but include formulations with clorsulon for enhanced control of liver flukes alongside nematodes. One example is Ectosulon by ATCO Pharma, which combines 10 mg/mL doramectin with 100 mg/mL clorsulon for subcutaneous injection in cattle.[49]Internationally, doramectin is sold under names such as Doramec L.A. by Agrovet Market in Latin America for long-acting treatment in cattle, sheep, and swine. In Australia, brands include D-MAX Injectable by Abbey Laboratories and Doramate Injectable Endectocide by Troy Laboratories, both providing broad-spectrum parasite control for cattle and pigs.[50][51][52]Dectomax has dominated the U.S. livestockantiparasitic market, contributing to global doramectin sales exceeding $100 million annually prior to the introduction of generics in 2023.[53]
Resistance concerns
Resistance to doramectin, a macrocyclic lactoneanthelmintic, has been documented in gastrointestinal nematodes of cattle, particularly Cooperia oncophora, in both the United States and Australia since the early 2000s. In the US, the first cases emerged around 2002, with studies reporting fecal egg count reduction (FECR) rates as low as 61% against C. oncophora 14 days post-treatment, indicating substantial efficacy loss compared to the expected >90% for susceptible populations.[54] In Australia, resistance was confirmed starting in 2005 through surveys in south-west Western Australia, where doramectin failed in 59% of tested beef cattle farms against C. oncophora, with some dairycalf studies showing resistance in up to 91% of properties and efficacy reductions of 20-50% in affected herds.[55][56]The primary mechanism of resistance involves target-site mutations in glutamate-gated chloride channels (GluCls), the molecular target of doramectin, which reduce the drug's ability to open these channels and cause parasite paralysis.[57][58] These mutations lead to cross-resistance with other avermectins, such as ivermectin, due to their shared action on GluCls, exacerbating the issue in regions with prior exposure to multiple macrocyclic lactones.[59] Prevalence is notably higher in intensive grazing systems, where frequent prophylactic treatments increase selective pressure; monitoring typically relies on the fecal egg count reduction test (FECRT), which detects resistance when FECR falls below 90%.[60][61]To mitigate resistance, management strategies emphasize rotating doramectin with anthelmintics from non-avermectin classes, such as benzimidazoles, to reduce repeated exposure to the same target site.[56] Incorporating refugia—leaving a portion of the parasite population untreated to preserve susceptible genotypes—has proven effective in delaying resistance onset by diluting resistant alleles in the population.[62] Additionally, the persistence of doramectin residues in soil, lasting weeks to months post-application, can impose selection pressure on free-living soil nematodes, potentially accelerating resistance in environmental stages of the parasite life cycle.[63]