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Erythromycin

Erythromycin is a that functions as a by inhibiting bacterial protein through to the 50S ribosomal subunit, primarily effective against and certain gram-negative organisms. It is included in the World Health Organization's List of Essential Medicines. Originally isolated in 1952 from the soil bacterium Saccharopolyspora erythraea (formerly Streptomyces erythreus) found in the , it was introduced for clinical use in 1952. Erythromycin is indicated for treating mild-to-moderate bacterial infections, including respiratory tract conditions such as , , and ; skin and soft tissue infections; sexually transmitted infections like and ; and gastrointestinal infections such as . It also serves as a second-line for patients with penicillin allergies and is employed prophylactically to prevent recurrent in those unable to take penicillin. Available in oral, intravenous, and topical formulations, erythromycin has a molecular formula of C₃₇H₆₇NO₁₃ and exhibits variable oral of 18–45%, with primary excretion via the biliary route.

Medical uses

Indications

Erythromycin is indicated for the treatment of mild to moderate respiratory tract infections, including caused by Streptococcus pneumoniae, , and atypical pathogens such as and (). It is also used for acute exacerbations of chronic bronchitis due to susceptible strains of (in combination with sulfonamides), S. pneumoniae, or M. pneumoniae. For adults with these respiratory infections, the typical oral dose is 250 mg four times daily or 500 mg every 12 hours, adjusted up to 4 g daily for severe cases. In skin and soft tissue infections, erythromycin treats mild to moderate cases such as impetigo caused by S. pyogenes or Staphylococcus aureus. The topical formulation is specifically indicated for acne vulgaris, applied to affected areas to reduce Propionibacterium acnes proliferation and inflammation. Erythromycin serves as a primary treatment for sexually transmitted infections, including uncomplicated urogenital, endocervical, or rectal infections due to Chlamydia trachomatis (when tetracyclines are contraindicated) and non-gonococcal urethritis caused by Ureaplasma urealyticum. The recommended adult dose for chlamydial infections is 500 mg orally four times daily for at least 7 days. It is indicated for the treatment and postexposure prophylaxis of pertussis (whooping cough) caused by Bordetella pertussis, as well as diphtheria due to Corynebacterium diphtheriae as an adjunct to antitoxin therapy. Additional indications include prophylaxis to prevent initial attacks or recurrences of rheumatic fever in patients allergic to penicillin (250 mg orally twice daily continuously), alternative therapy for primary syphilis in penicillin-allergic patients (30–40 g over 10–15 days), acute pelvic inflammatory disease due to Neisseria gonorrhoeae (500 mg IV every 6 hours for 3 days followed by oral therapy), and intestinal amebiasis (250 mg four times daily for 10–14 days). Prophylactically, erythromycin ophthalmic ointment (0.5%) is applied to newborns' eyes shortly after birth to prevent neonatorum caused by or .

Available forms

Erythromycin is available in multiple pharmaceutical formulations tailored to different routes of administration, enhancing its suitability for various clinical needs. Oral preparations include the base form, typically supplied as enteric-coated tablets of 250 mg or 500 mg to reduce gastrointestinal irritation by delaying release until reaching the intestine. Additional oral variants encompass erythromycin stearate in tablet form and erythromycin ethylsuccinate, which is offered as both tablets and oral suspensions, particularly convenient for pediatric dosing due to its liquid availability. The of orally administered erythromycin varies by : the achieves approximately 30% , whereas the derivatives like stearate and ethylsuccinate exhibit higher rates of 50-55%. For parenteral use in severe infections, intravenous formulations such as erythromycin lactobionate are employed, with standard dosing ranging from 250 mg to 1000 mg every 6 hours. Topical applications consist of 2% erythromycin in gels, ointments, or solutions, designed for direct application. Ophthalmic preparations include a 0.5% ointment for prophylactic use in neonates. Stability considerations necessitate specific storage conditions across forms; for instance, solutions require protection from light to prevent , while reconstituted oral suspensions should be kept at controlled (20-25°C).

Adverse effects

Common adverse effects

The most common adverse effects of erythromycin are gastrointestinal disturbances, which include , , , and . These effects occur in up to 25% of patients, particularly with certain formulations like erythromycin ethylsuccinate, and are primarily attributed to the drug's stimulation of gastrointestinal through its as a motilin receptor agonist. Mild allergic reactions, such as or pruritus, are less frequent, affecting less than 1% of patients. The incidence of gastrointestinal effects increases with higher doses, such as 2 g/day compared to lower doses, and varies by formulation, with the base form often associated with more pronounced symptoms than ester derivatives like stearate or ethylsuccinate. To mitigate these effects, patients may take non-enteric-coated forms with or to reduce upset, although this can slightly decrease absorption. In cases of poor tolerance, switching to , which exhibits better gastrointestinal tolerability with adverse events in about 19% of patients versus 41% for erythromycin estolate, can be considered as an alternative .

Serious adverse effects

Erythromycin can cause cholestatic hepatitis and acute , which are rare but potentially severe complications, occurring in approximately 1-4 per 100,000 users, particularly with the estolate formulation. These reactions typically present with symptoms such as , pruritus, , and significantly elevated liver enzymes, often developing within days to weeks of initiation. The estolate form is associated with a higher risk due to its propensity to induce hypersensitivity-mediated , which may resolve upon discontinuation but can lead to prolonged recovery or, in rare cases, hepatic failure. In neonates, erythromycin exposure, particularly in the first two weeks of life, is associated with an increased risk of infantile hypertrophic (IHPS), with odds ratios up to 8-fold in some studies. Cardiovascular adverse effects from erythromycin include prolongation, which increases the risk of , a potentially life-threatening ventricular . This prolongation is dose-dependent and more common with intravenous administration, elevating the risk of sudden cardiac death, especially in patients with predisposing factors such as , preexisting heart disease, advanced age, or concomitant use of other QT-prolonging drugs. sex further heightens susceptibility to these arrhythmias. Pseudomembranous , resulting from overgrowth of , is a serious gastrointestinal complication linked to erythromycin use, though less frequent than with other antibiotics like clindamycin. This condition arises from disruption of normal gut flora, leading to toxin production that causes severe , abdominal cramping, and potentially or perforation if untreated. Rare hypersensitivity reactions to erythromycin encompass severe cutaneous disorders such as Stevens-Johnson syndrome, characterized by widespread mucocutaneous erosions, blistering, and systemic involvement that can be fatal. These IgE-mediated or T-cell responses typically occur within 1-3 weeks of exposure and require immediate discontinuation to prevent progression. For at-risk patients, baseline electrocardiogram (ECG) monitoring is recommended before starting erythromycin, with follow-up assessments during therapy to detect prolongation exceeding 500 ms or an increase greater than 60 ms from baseline. Discontinuation is advised if significant prolongation or arrhythmias occur, alongside correction of imbalances like , and avoidance in those with known . Common gastrointestinal effects, such as , may occasionally escalate to these severe outcomes in vulnerable individuals.

Drug interactions

Interactions with medications

Erythromycin, a , is a potent inhibitor of the 3A4 () enzyme, which can lead to elevated plasma concentrations of various CYP3A4 substrates and increase the risk of toxicity. This pharmacokinetic interaction is particularly significant with s such as and simvastatin, where concurrent use has been associated with due to markedly increased statin levels; as a result, concomitant administration with simvastatin is contraindicated, and close monitoring of and levels is recommended for . Similarly, erythromycin can elevate levels of , potentially causing toxicity, necessitating dose reduction of theophylline and therapeutic monitoring of its serum concentrations. Interactions with carbamazepine involve altered metabolism, leading to increased concentrations and possible , for which level is advised during co-administration. Erythromycin also enhances the anticoagulant effects of through inhibition of its metabolism via and possibly reduced absorption due to disruption of vitamin K-producing gut bacteria, which can result in elevated international normalized ratio (INR) values, particularly in elderly patients; frequent INR and potential dose adjustments are essential. Concomitant use of erythromycin with ergot alkaloids, such as or , is contraindicated due to potentiated , which may precipitate acute ergot toxicity characterized by severe peripheral vasospasm and dysesthesia. With , an antiarrhythmic, erythromycin can increase digoxin absorption and serum levels, raising the risk of toxicity, thus requiring monitoring of digoxin concentrations. Additionally, erythromycin's potential to prolong the can lead to additive cardiotoxicity when combined with other QT-prolonging drugs, such as certain antiarrhythmics; it is contraindicated with agents like , , , and due to the risk of ventricular arrhythmias. Erythromycin increases plasma concentrations of , potentially causing serious toxicity including and neuropathy; concomitant use is contraindicated in patients with renal or hepatic , and dose reduction is recommended otherwise. For immunosuppressants like cyclosporine, erythromycin inhibits via , potentially increasing cyclosporine levels and toxicity risk, so close therapeutic monitoring and possible dose adjustments are recommended. These interactions underscore the need for careful review of concurrent medications before initiating erythromycin therapy.

Interactions with food and other factors

The absorption of erythromycin base and stearate formulations is significantly reduced when administered with fatty foods, as high-fat meals can delay gastric emptying and impair dissolution, leading to lower bioavailability. In contrast, ester forms such as erythromycin estolate exhibit improved bioavailability when taken with food, particularly after the first dose, due to enhanced stability in the gastrointestinal tract. Acidic beverages like can increase erythromycin by inhibiting intestinal , which reduces first-pass and elevates concentrations by up to 84%. Antacids containing aluminum, magnesium, or calcium, as well as dairy products, can decrease erythromycin absorption through chelate formation or altered , which retards drug dissolution and reduces peak levels, particularly for stearate and propionate salts. Acute alcohol intake primarily exacerbates gastrointestinal side effects rather than altering pharmacokinetics. Patients should be counseled to take erythromycin on an empty stomach, at least one hour before or two hours after meals, to optimize absorption while minimizing interactions with dietary factors.

Pharmacology

Mechanism of action

Erythromycin exerts its antibacterial effect by binding to the 50S subunit of the bacterial ribosome, specifically to domain V of the 23S rRNA. This binding occurs within the nascent peptide exit tunnel near the peptidyl transferase center, where the antibiotic interacts with key nucleotides in the rRNA structure. By occupying this site, erythromycin inhibits the translocation step of protein synthesis, preventing the movement of peptidyl-tRNA from the A-site to the P-site and thereby blocking peptide chain elongation. This disruption halts bacterial protein production essential for growth and replication. The inhibition of protein synthesis by erythromycin is primarily bacteriostatic, meaning it suppresses bacterial proliferation without directly killing the organisms. However, under certain conditions, such as high drug concentrations in tissues relative to low minimal inhibitory concentrations, it can exhibit bactericidal activity against specific pathogens like . Erythromycin demonstrates activity against a range of , including Gram-positive cocci such as and species, some Gram-negative organisms like , and atypical pathogens including and . It shows limited or no efficacy against Enterobacteriaceae due to poor penetration or intrinsic resistance in these Gram-negative enteric . The lacks activity against fungi and viruses, as these lack prokaryotic ribosomes. Additionally, erythromycin does not affect mammalian ribosomes, owing to structural differences between bacterial 50S subunits and eukaryotic 60S subunits, which prevent effective binding.

Pharmacokinetics

Erythromycin demonstrates variable oral of 15-45%, attributed to instability in , with ester prodrugs such as erythromycin estolate and ethylsuccinate offering improved absorption compared to the base form. Peak plasma concentrations of 0.4-2 mcg/mL are generally reached 1-4 hours following a 250 mg oral dose, while intravenous administration achieves immediate peak levels. Food intake has minimal impact on serum concentrations for most formulations. The drug distributes widely throughout body tissues, including the lungs, prostate, and leukocytes, with accumulation in inflammatory fluids. It exhibits moderate protein binding of 70-80% primarily to alpha-1-acid glycoprotein, and a volume of distribution of approximately 0.8 L/kg. Erythromycin achieves good penetration into cerebrospinal fluid during meningeal inflammation but limited access under normal conditions. The elimination is 1.4-2 hours in adults with normal renal function but is prolonged in neonates, ranging from 2-9 hours depending on . occurs mainly via hepatic and biliary routes, with only 5-10% eliminated unchanged in ; dose adjustments are recommended in hepatic impairment due to reduced clearance. contributes to overall elimination, primarily through hepatic pathways.

Metabolism

Erythromycin undergoes primary metabolism via the 3A4 () enzyme in both the liver and intestines, primarily through N-demethylation, yielding major metabolites such as N-demethylerythromycin, anhydroerythromycin, and anhydro-N-demethylerythromycin. This process inactivates approximately 80% of the drug before excretion, with the metabolites exhibiting minimal antimicrobial activity compared to the parent compound. The extensive hepatic first-pass significantly reduces oral bioavailability to around 30-50%, contributing to variable absorption after . Overall, this influences the drug's elimination , which typically ranges from 1.5 to 2 hours in individuals with normal renal and hepatic function. The unchanged erythromycin and its metabolites are predominantly excreted via the biliary route, accounting for about 60% of elimination, with the remainder via renal . This biliary secretion facilitates enterohepatic recirculation, where reabsorption from the intestines can extend the drug's systemic exposure and contribute to its prolonged effects. In conditions like , impaired biliary excretion leads to drug accumulation, potentially elevating plasma concentrations and increasing the risk of . Metabolism of erythromycin is slower in elderly patients and those with due to reduced activity and hepatic function, resulting in higher drug levels and necessitating dose adjustments. Additionally, inducers such as rifampin can accelerate metabolism and increase clearance rates, while inhibitors like can slow it, decreasing clearance and prolonging exposure.

Resistance

Bacterial resistance to erythromycin primarily arises through two main mechanisms: ribosomal modification and active efflux. The most common form involves erm genes, which encode 23S rRNA methyltransferases that add a to at position 2058, sterically hindering erythromycin binding to the 50S ribosomal subunit. This results in the MLS_B phenotype, characterized by to , , and type B streptogramins, often with cross-resistance to clindamycin. Expression of erm genes can be inducible, triggered by subinhibitory concentrations of erythromycin, or constitutive, leading to high-level without . The second major mechanism is mediated by efflux pumps encoded by mef genes in streptococci (conferring the M phenotype with low-level resistance to 14- and 15-membered but not clindamycin) and msr genes in staphylococci, which actively expel the from the bacterial cell via ATP-binding cassette transporters. These efflux systems typically produce moderate resistance levels and do not confer broad cross-resistance. Resistance prevalence is notably high in key pathogens. For example, approximately 25% of invasive isolates were resistant in the United States as of 2023. In , resistance rates via erm or msr mechanisms have increased, reaching 31% in methicillin-susceptible strains from blood cultures in by 2020. Factors promoting this resistance include overuse of in human medicine and agriculture, which selects for resistant strains, as well as the distinction between inducible and constitutive erm expression that allows survival under varying pressures. Clinically, erythromycin contributes to treatment failures in infections, such as caused by S. pneumoniae, where monotherapy may fail due to inadequate bacterial clearance. Susceptibility testing follows Clinical and Laboratory Standards Institute (CLSI) breakpoints, with isolates considered susceptible at ≤0.5 mcg/mL for spp. and ≤0.25 mcg/mL for S. pneumoniae. To mitigate , strategies include with beta-lactams or other agents and switching to alternatives like fluoroquinolones for susceptible infections; as of 2025 includes adjuvants targeting mechanisms like ErmC and synergistic combinations to restore erythromycin .

Chemistry

Structure and properties

Erythromycin is classified as a 14-membered , consisting of a large ring known as the aglycone erythronolide, which is glycosidically linked to two moieties: desosamine at position 3 and cladinose at position 5. The desosamine is a dimethylamino (3,4,6-trideoxy-3-(dimethylamino)-β-D-xylo-hexopyranose), while cladinose is a methylated (2,6-dideoxy-3-C-methyl-3-O-methyl-α-L-ribo-hexopyranose). The molecular formula of erythromycin is C₃₇H₆₇NO₁₃, with a molecular weight of 733.93 g/mol. As a physical entity, erythromycin appears as a white to slightly yellow crystalline powder. It exhibits poor in water, approximately 2 mg/mL, which is pH-dependent and increases in acidic conditions due to salt formation, but it is freely soluble in organic solvents such as , , , and acetone. The compound is stable under neutral conditions but undergoes degradation in acidic environments, primarily through hydrolysis of the cladinose sugar, and is also sensitive to and . Erythromycin possesses pKa values of approximately 8.8 for the desosamine and around 7 for the aglycone moiety, conferring overall character that facilitates formation with acids. Its , indicated by a value of 2.6–3.06, supports effective penetration into tissues. Semi-synthetic derivatives, such as , which features a 6-O-methyl on the erythronolide , enhance acid stability while retaining the core structure.

Synthesis and production

Erythromycin is produced on an industrial scale through submerged fermentation using the actinomycete bacterium Saccharopolyspora erythraea (previously known as Streptomyces erythraeus), cultivated in aerated broths enriched with carbon sources such as glucose or starch and nitrogen sources like soybean flour or corn steep liquor. The fermentation process occurs under controlled conditions, typically lasting 5 to 7 days at temperatures of 30 to 35°C, with agitation and aeration to support aerobic growth, resulting in titers of 3 to 5 g/L of erythromycin A, the primary active component. After fermentation, the broth is filtered to remove , and erythromycin is extracted into an organic solvent phase, commonly or , followed by solvent evaporation and to isolate the crude . Purification involves or recrystallization to achieve pharmaceutical-grade material with purity exceeding 95%, accompanied by rigorous impurity profiling to control related substances like erythromycins B and C. Semi-synthetic derivatives such as erythromycin ethylsuccinate and erythromycin estolate are derived from the purified erythromycin base through targeted esterification reactions; for ethylsuccinate, the 2'-hydroxyl group on the desosamine sugar is esterified with ethylsuccinic acid, while estolate involves propionylation at the same position to enhance acid stability and oral bioavailability. These modifications are performed under mild conditions using activating agents to avoid degradation of the complex macrolide structure. Industrial production faces challenges due to the molecule's structural complexity, which makes total chemical synthesis impractical for industrial production, and relies instead on optimizing microbial strains through , , or medium supplementation to boost yields and minimize by-products. Recent advancements, such as addition during , have increased yields by up to 43.5% in engineered strains.

History

Discovery

Erythromycin was isolated in 1952 by James M. McGuire and colleagues at from a soil sample collected in , in the Philippine Islands, containing the actinomycete erythreus (now classified as Saccharopolyspora erythraea, strain NRRL 2338). The sample had been submitted by Filipino researcher , who identified promising antimicrobial activity during routine screening efforts for new antibiotics from microbes. Isolation involved suspending the in sterile water, diluting and plating on , incubating at 30°C for one week, and selecting colonies of the red-pigmented strain for further cultivation. The screening process entailed fermenting the isolated strain and testing its metabolic products for antibacterial activity using streak-dilution and broth-dilution assays against standard test organisms, including Bacillus subtilis, to detect zones of inhibition indicative of antibiotic production. Active fractions were purified, yielding a crystalline compound initially named Ilotycin (after Iloilo) and later erythromycin, reflecting the species name "erythreus" derived from the Greek word for red, due to the strain's characteristic red aerial mycelium and soluble pigments. The discovery was first reported in a 1952 publication detailing its isolation and preliminary properties. Early characterization, published in 1953, described erythromycin as a basic nitrogenous compound (pKa 8.7) belonging to the macrolide class, with a molecular formula approximating C₃₈H₆₇NO₁₃ and solubility in organic solvents like alcohol and chloroform, forming white crystalline needles with a melting point of 136–140°C. In vitro testing revealed potent activity against Gram-positive bacteria, such as staphylococci and streptococci (minimum inhibitory concentrations as low as 0.8 mcg/mL for Staphylococcus aureus), and moderate activity against some Gram-negative organisms, including Neisseria and Haemophilus species, positioning it as a broad-spectrum agent comparable to penicillin. Preclinical studies in mice confirmed erythromycin's efficacy against staphylococcal infections, demonstrating protection in systemic challenge models where oral or subcutaneous administration at doses of 10–50 mg/kg prevented mortality from Staphylococcus aureus, with survival rates exceeding 80% in treated groups versus near-total lethality in controls. These findings established its potential as a non-toxic therapeutic, paving the way for further development.

Development and approval

Following its discovery in 1952, erythromycin advanced through clinical development with phase I, II, and III trials conducted primarily between 1954 and 1956. These studies evaluated its efficacy against gram-positive bacterial infections, including pneumonia caused by Streptococcus pneumoniae and Staphylococcus aureus, syphilis due to Treponema pallidum, and acne vulgaris associated with Propionibacterium acnes. The trials also established a safety profile characterized by mild, transient gastrointestinal disturbances as the most common adverse effects, with rare hypersensitivity reactions. A pivotal 1955 multicenter trial involving 200 patients with acute infections demonstrated an 80% clinical cure rate with oral erythromycin at doses of 200-400 mg every 6 hours, comparable to penicillin in efficacy but with better tolerability in penicillin-allergic individuals. Additional trials confirmed its utility in , achieving serologic reversal in 85-90% of early cases after 10-15 days of , and in , reducing lesion counts by 50-70% after 4-6 weeks of topical or oral administration. These results supported erythromycin's role as a broad-spectrum alternative to existing antibiotics. The U.S. (FDA) granted approval for the oral erythromycin estolate , marketed as Ilosone by , in 1958 for systemic infections, addressing poor issues of the base form. An intravenous followed in 1962, enabling use in severe cases like hospitalized patients. In the 1960s, topical approvals expanded its applications, particularly for , with the 2% ointment form cleared in 1967; by then, erythromycin had gained recognition as a key penicillin substitute, filling a critical gap in allergy-prone populations. Post-approval in the late 1960s and 1970s identified cholestatic hepatitis as a rare but serious risk with the estolate , occurring in up to 1 in 10,000 courses and disproportionately affecting adults. This led to FDA-mandated warnings in , contraindicating its use in preexisting hepatic disease and cautioning against use in , and promoting alternative erythromycin salts like the stearate or ethylsuccinate for routine oral . Despite these precautions, the drug's overall and versatility drove its early adoption in clinical practice.

Society and culture

Brand names and availability

Erythromycin is available under several brand names globally, including Erythrocin for intravenous use, E-Mycin for the base formulation, and the historical PCE brand for delayed-release tablets, which was discontinued in 2010. The estolate salt, marketed as Ilosone, has limited availability due to its association with , including , and is no longer marketed . Following patent expiration in the early , generic erythromycin has been widely available in various forms, enhancing accessibility. Topical formulations for are prescription-only in most countries but available over-the-counter in select regions. Erythromycin has been included on the World Health Organization's Model List of since its inaugural publication in 1977, promoting broad availability in low- and middle-income countries. Regional variations affect formulations; the estolate form is restricted in the United States and owing to hepatotoxicity risks, whereas oral suspensions remain common in and for pediatric and general use. Combination products, such as Benzamycin pairing erythromycin with benzoyl peroxide, are approved for topical treatment in multiple markets.

Economics

Erythromycin is produced primarily through bacterial using Saccharopolyspora erythraea, resulting in low costs for the active pharmaceutical (API) of approximately $0.15 to $0.18 per gram as of 2025. formulations, such as 250 tablets, are priced at around $0.05 per unit based on reference prices, making it an affordable option in global markets. These low costs stem from established processes and widespread generic manufacturing, particularly in countries like and . Since the 1990s, erythromycin's market share has declined due to competition from better-tolerated like , which offer shorter dosing regimens and fewer gastrointestinal side effects. Despite this, global annual sales remain substantial, exceeding $300 million as of , driven by its continued use in treating respiratory and infections. held exclusive rights following its discovery in the early 1950s, with the original U.S. (US2653899) issued in 1953 and expiring around 1970, after which generic competition intensified. In resource-limited settings, erythromycin plays a key role as a cost-effective alternative for penicillin-allergic patients, particularly for conditions like in , and is included on the WHO Model List of Essential Medicines for such indications. The WHO facilitates bulk procurement to ensure availability at low prices, supporting its use in essential health programs in low-income countries. Additionally, its economic impact is evident in outbreaks like pertussis, where erythromycin prophylaxis and treatment help curb transmission, reducing overall healthcare costs estimated at millions annually in affected regions.

Veterinary uses

Indications in animals

Erythromycin is commonly used in to treat infections in young animals, particularly foals affected by Rhodococcus equi , where it is often combined with rifampin for enhanced efficacy against this Gram-positive bacterium. However, resistance to erythromycin and rifampin in R. equi has increased, with studies showing up to 10-20% resistant isolates in some regions as of 2024, necessitating susceptibility testing. In calves, it addresses complex caused by susceptible pathogens such as Pasteurella and Mannheimia species, helping to control and associated upper respiratory infections like and . In gastrointestinal contexts, erythromycin serves as a key treatment for proliferative enteropathy in pigs, an infectious condition driven by Lawsonia intracellularis, where it inhibits bacterial proliferation in the intestinal mucosa to alleviate symptoms like and . For Mycoplasma-associated diseases, it is indicated in for chronic respiratory disease and airsacculitis caused by , and in cats for ocular infections including linked to or species, often via topical application to reduce and bacterial load. Skin infections in dogs, particularly those involving Gram-positive organisms like Staphylococcus and Streptococcus, respond to erythromycin, which targets and wound infections by disrupting bacterial protein synthesis. In cattle, it is employed for reproductive tract issues such as subclinical , administered intramammarily to combat infections that can impact and . Typical oral dosages in small animals like dogs and cats range from 10-20 mg/kg every 12 hours, reflecting its species-specific activity against while minimizing gastrointestinal side effects.

Administration and considerations

In veterinary practice, erythromycin is primarily administered orally via tablets or suspensions, which is the preferred route for most species due to its efficacy and ease of use in outpatient settings. For severe infections in large animals such as foals or calves, intravenous or may be employed to achieve rapid therapeutic levels, though intravenous administration is contraindicated in adult due to the risk of fatal reactions, including from the IM formulation if injected IV. is also labeled for use in to target udder infections. Dosing regimens require species-specific adjustments to account for pharmacokinetic differences; for instance, ruminants often necessitate higher or alternative parenteral dosing because oral erythromycin undergoes significant degradation and inactivation in the , reducing to approximately 20%. Erythromycin should be strictly avoided in rabbits and guinea pigs, as oral administration can disrupt , leading to severe , enterotoxemia, and potentially fatal typhlocolitis. In cats and dogs, veterinarians must monitor for gastrointestinal side effects such as , , and anorexia, which occur in up to 20-30% of cases; treatment duration is typically 5-14 days to ensure resolution of while minimizing resistance development. Erythromycin holds off-label status for many veterinary applications across countries, but it is FDA-approved for specific uses, including in for respiratory infections. In food-producing animals, adherence to periods is critical to prevent residues; labeled guidelines specify 72 hours for milk and 14 days for meat in , with shorter intervals of 2-4 days for tissues, though extralabel use requires consultation with resources like for extended times based on dose and route.