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Equine chorionic gonadotropin

Equine chorionic gonadotropin (eCG), also known as pregnant serum (PMSG), is a secreted by trophoblastic cells that form endometrial cups in the of pregnant mares. These structures develop around day 40 post-conception, with hormone levels becoming measurable by day 45, peaking near day 60, and declining to undetectable by 100–150 days of . In equine physiology, eCG functions analogously to (LH), stimulating the luteinization or of secondary ovarian follicles to form accessory corpora lutea, thereby augmenting progesterone production critical for maintenance until the fetal-placental unit assumes endocrine support around day 70. Unlike pituitary-derived gonadotropins, eCG's placental origin and extended exceeding 24 hours enable prolonged gonadal stimulation, while its dual LH- and (FSH)-like bioactivities in non-equids distinguish it from homologs like . eCG's veterinary applications leverage this bifunctional potency for reproductive manipulation in diverse , including induction of , anestrus reversal, estrus , and superovulation to enhance ovulation rates in protocols for and in species such as , sheep, pigs, and goats. Commercial extraction from mare serum during early pregnancy has proven efficacious but controversial, as production on specialized farms often entails repeated , confined stabling, and selective abortions post-extraction to enable multiple annual cycles, practices documented to risk mare morbidity, injury, and ethical lapses in oversight.

Biological Foundations

Natural Production and Physiology

Equine chorionic gonadotropin (eCG), also known as pregnant gonadotropin (PMSG), is a synthesized and secreted by the endometrial cups within the of pregnant s. These cups originate from invasive fetal cells of the chorionic girdle, which differentiate into binucleate gonadotropin-producing cells and embed into the endometrial starting around days 25–35 of . of eCG begins approximately days 35–40 post-ovulation, coinciding with the maturation of these cup cells, and persists until roughly days 120–150, after which the cups undergo degeneration. Peak production occurs between days 55–70 of , when the cups achieve maximum size and eCG concentrations in maternal can exceed 50–100 international units per milliliter. Physiologically, eCG enters the maternal bloodstream and acts primarily on the ovaries, exerting both (FSH)-like and (LH)-like activities due to its receptor . It stimulates the and growth of secondary ovarian follicles, often leading to multiple ovulations or luteinization of unruptured follicles, which form accessory . These accessory structures produce additional progesterone, supplementing the primary and sustaining endometrial progesterone levels critical for early maintenance until the equine assumes steroidogenesis around day 120. eCG also promotes ovarian , including and potentially testosterone, which may contribute to or estrogen precursor pools, though its precise role in modulating maternal endocrine feedback remains under study. The hormone's production is unique to equine , reflecting an evolutionary for extended luteal support in a species with a non-invasive , and detectable levels serve as a diagnostic marker for viable beyond day 40. Concentrations typically decline after peak due to cup regression, independent of , though persistence beyond day 150 can indicate complications such as mummified fetuses. This temporal profile ensures transient ovarian stimulation without long-term disruption to maternal cyclicity post-parturition.

Molecular Structure and Mechanism of Action

Equine chorionic gonadotropin (eCG) is a heterodimeric hormone comprising a non-covalently associated α-subunit of 96 and a hormone-specific β-subunit of 149 . The α-subunit is identical to that of other equine hormones such as equine (eLH) and (eFSH), while the β-subunit shares sequence identity with eLHβ but features distinct patterns. The β-subunit core (residues 1–110) exhibits approximately 66% homology with the (hCG) β-subunit core and includes a carboxyl-terminal extension (residues 111–149) with multiple O-linked sites, contributing to extended circulatory compared to pituitary gonadotropins. eCG is the most heavily glycosylated member of the glycoprotein hormone family, with carbohydrates comprising over 40% of its molecular weight, primarily as N-linked and O-linked oligosaccharides terminating in sialic acids. The α-subunit bears two N-linked glycosylation sites at residues 56 and 82, while the β-subunit has one N-linked site at 13 and at least 11 O-linked sites (primarily on or ) within the C-terminal region ( 115–149). These structures, which include biantennary complex-type chains, confer sialylation and sulfation differences from eLH, influencing receptor binding affinity, , and persistence; for instance, mutations at key glycosylation sites (e.g., Asn56 or O-linked CTP sites) reduce biological potency by 2- to 5-fold in receptor assays. The mechanism of action involves binding to leucine-rich repeat-containing G protein-coupled receptors, primarily the (FSHR) and luteinizing hormone/chorionic gonadotropin receptor (LHCGR), with activity profiles varying by species. In equids, eCG predominantly elicits luteinizing hormone-like effects via LHCGR activation, promoting and formation; however, in non-equid species such as and , its β-subunit enables dual FSH-like (follicular recruitment and via FSHR) and LH-like (thecal production and via LHCGR) activities due to . Receptor engagement triggers dual signaling cascades: the primary cAMP-dependent pathway via Gs protein stimulation of adenylate cyclase and activation, which upregulates steroidogenesis and ; and a secondary pathway involving hydrolysis to , diacylglycerol, , and intracellular Ca²⁺ mobilization, enhancing responsiveness. modulates these effects, with sialylated O-linked chains in the β-CTP extending (up to several days versus hours for non-glycosylated analogs) and facilitating sustained receptor occupancy, while core fucosylation influences binding specificity.

Commercial Production

Extraction from Pregnant Mares

Equine chorionic gonadotropin (eCG) is commercially extracted from the or of pregnant mares, primarily during days 40 to 120 of when concentrations peak, with the highest levels between days 55 and 70. Blood samples are initially drawn and tested using enzyme-linked immunosorbent assay () to confirm eCG presence as mares approach day 40. Collection involves aseptic of the with large-bore needles, typically after restraining in chutes or halters to facilitate access. Volumes range from 5 to 10 liters per session, equivalent to up to 6.1 liters every two weeks for a 1000 kg , with collections occurring weekly or more frequently over 4 to 11 weeks to maximize yield without exceeding safe limits. Anticoagulants may be used to obtain , or blood is allowed to clot for separation via or siphoning. Purification from or follows classical protocols, beginning with precipitation steps such as using metaphosphoric acid, followed by graded (e.g., stepwise concentrations to isolate ), , and to remove impurities. Subsequent , including fixed-bed or hydroxylapatite columns, refines the product to high biological potency. Industrial-scale methods employ direct batch-wise adsorption of eCG onto anionic-exchange resins after conditioning to lower and , achieving approximately 90% and a 50-fold concentration factor, followed by cation-exchange for final purification with overall yields exceeding 70% and potencies around 4000 /mg. These processes preserve biological activity while enabling large-volume processing for veterinary applications.

Harvesting Protocols and Scale

Harvesting of equine chorionic gonadotropin (eCG), also known as pregnant serum gonadotropin (PMSG), entails of the in pregnant mares during the initial stages of . Blood collection is timed between days 40 and 120 of , coinciding with peak hormone concentrations around days 55 to 70, to maximize yield from the . Mares are typically restrained in or boxes to facilitate access, with 5 to 10 liters of drawn per session via large-bore or indwelling cannulas inserted by trained personnel. Sessions occur weekly or twice weekly over 4 to 11 weeks, though guidelines in some regions recommend limiting extraction to no more than 6.1 liters per 1000 kg of body weight every two weeks to reduce physiological stress. Commercial operations predominate in , , , , , and , where production relies on dedicated herds of broodmares impregnated seasonally. In , 5,383 mares across 119 farms contributed to output in 2021, while over 10,000 mares are engaged annually in and combined. Per mare, yields approximate 10 liters of weekly during the harvest window, supporting global demand for veterinary applications despite variability in farm practices and regulatory oversight.

Veterinary and Agricultural Applications

Primary Uses in Livestock Reproduction

Equine chorionic gonadotropin (eCG), also known as pregnant mare serum gonadotropin (PMSG), is primarily administered to to induce superovulation, thereby increasing the number of s and transferable embryos for assisted reproductive technologies such as multiple and (MOET) programs. In , eCG is injected intramuscularly or subcutaneously at doses typically ranging from 1,500 to 3,000 per animal, often in protocols combined with progesterone or progestins to synchronize estrus and promote follicular recruitment before induction with (hCG) or (LH). This application supports genetic improvement in and herds by enabling elite donors to produce multiple offspring annually, with superovulation yields averaging 5–10 viable embryos per flush in responsive cows. In small ruminants like sheep and , eCG serves a in out-of-season and superovulation, administered at 300–600 to stimulate ovarian follicular growth in anestrus animals or to amplify rates during natural cycles, facilitating production for accelerated flock multiplication. For , eCG is used at doses of 1,000–1,500 to enhance follicular development in gilts and sows, particularly in synchronization protocols for , resulting in increased litter sizes through higher numbers, though it may elevate abnormal rates if overdosed. These uses exploit eCG's prolonged and dual FSH- and LH-like activities, which mimic endogenous gonadotropins but persist longer in circulation compared to species-specific (FSH).

Efficacy Data and Economic Impacts

In , eCG administration in fixed-time protocols for anestrous cows has demonstrated improved reproductive outcomes, with rates increasing from 30.6% to 36.0% at 7 days post-insemination and in-calf rates rising from 52.3% to 58.6% at 28 days when 400–600 eCG is added to progesterone-based treatments. For superovulation in programs, eCG doses of 1200–2500 , often combined with anti-eCG antiserum to neutralize prolonged activity, yield higher corpora lutea counts and transferable compared to eCG alone, though excessive doses (e.g., 3600 ) reduce embryo quality due to increased unovulated follicles. In , eCG facilitates in weaned sows, achieving rates of 73–76.5% and average sizes of 10.5–10.9 pigs when used at 1000–1500 followed by hCG, outperforming unsynchronized controls in farrowing efficiency. Similar protocols in gilts enhance synchrony, supporting batch and reducing labor costs associated with variable estrus cycles. Economically, eCG supports technologies that accelerate genetic selection in by shortening generation intervals and amplifying superior traits, contributing to enhanced milk and yields in commercial herds. The global for injectable eCG products, reflecting its agricultural utility, was valued at USD 269 million in , with projections to reach USD 372 million by 2031 amid rising demand for reproductive enhancement in . These applications yield productivity gains, such as increased transferable embryos per donor cow (up to 10–20 in optimized protocols), which lower breeding costs and boost herd expansion rates for producers.

Risks, Side Effects, and Safety

Effects on Treated Animals

Equine chorionic gonadotropin (eCG) administration in such as , sheep, , and pigs induces superovulation by stimulating follicular growth and multiple , but it frequently results in ovarian hyperstimulation characterized by protracted follicular stimulation and the development of cystic or anovulatory follicles exceeding 20 in . In , the long of eCG (approximately 40 hours) contributes to asynchronous follicle waves, premature luteinization, failure, and abnormal corpora lutea formation, leading to early luteal regression and reduced progesterone support for embryos. Persistent large follicles post-treatment release excess , which correlates with fewer transferable embryos and potential nuclear abnormalities in developing oocytes. High dosages of eCG, such as 15 IU or more, impair quality through , elevating (ROS) levels, disrupting mitochondrial , and reducing ATP production, which in turn promotes via spindle assembly checkpoint activation. This manifests in lower fertilization rates (e.g., dropping to 59% from 80-84% at lower doses), decreased four-cell formation (64% vs. 76-79%), and yields (45% vs. 61-75%), alongside increased and fewer cells in and trophectoderm. quality exhibits high variability, with residual eCG exacerbating issues like reduced transferable numbers. Repeated eCG treatments provoke a humoral , generating neutralizing that diminish treatment efficacy and impair subsequent fertility; for instance, in Alpine goats, this leads to sustained fertility reductions. In donor animals across species, antibody formation from multiple exposures further compromises ovarian responsiveness and recovery rates. Overall, these effects contribute to inconsistent superovulatory outcomes, with documented risks of ovarian cysts and heightened embryonic mortality.

Human and Environmental Safety Considerations

Equine chorionic gonadotropin (eCG), also known as pregnant mare serum gonadotropin (PMSG), exhibits low to humans via typical exposure routes, with safety data sheets indicating potential for reactions such as abdominal discomfort upon or , though severe effects like ovarian rupture are associated primarily with therapeutic misuse rather than occupational handling. Prolonged or repeated exposure warrants precautions, including the use of chemical-resistant gloves, goggles, respirators, and fume hoods, as well as thorough washing post-handling; laboratories must be equipped with eye wash stations and showers to address irritant risks. Veterinary practitioners face reproductive hazards from hormones like eCG, including potential disruption or teratogenic effects, prompting recommendations to restrict handling by pregnant personnel or those planning , based on analogous risks from endocrine-active agents in . The assesses no consumer safety risk from eCG residues, as the is orally inactive and rapidly degraded in the human gastrointestinal tract, rendering it non-bioavailable through food chains from treated . No large-scale epidemiological data document adverse incidents directly attributable to eCG in or veterinary settings as of 2023, though its structural similarity to underscores the need for dermal and inhalation barriers to prevent unintended endocrine modulation. Environmental safety data for eCG remain limited, with no dedicated ecotoxicity studies identifying persistence, , or direct harm to or terrestrial organisms. As a naturally occurring , eCG is anticipated to undergo enzymatic degradation in and , similar to other proteinaceous biologics, minimizing long-term ecological risks; safety guidelines advise against release into drains or waterways to prevent localized during or disposal. Production via blood collection from pregnant mares occurs on equine farms, potentially contributing indirect impacts such as nutrient loading from runoff, but these effects are attributable to general intensive husbandry rather than eCG-specific residues, with no evidence of -mediated disruption in receiving ecosystems reported in peer-reviewed assessments.

Welfare Concerns and Ethical Debates

Documented Welfare Issues in Mare Production

The production of equine chorionic gonadotropin (eCG) involves repeated blood collection from pregnant mares between approximately days 40 and 120 of gestation, with volumes up to 6.1 liters per 1000 kg body weight every two weeks, which can lead to anemia, weakness, emaciation, and compromised immune function if not properly monitored. A 2024 study of two herds found that 14.3% of mares in one group developed moderate to marked anemia (hematocrit <24%) during harvesting, though levels recovered to normal within three weeks post-collection, with outcomes varying by nutritional factors such as pasture quality. Unhygienic or forceful bleeding practices exacerbate stress and infection risks, particularly when performed by unskilled handlers in large-scale operations. Mares are frequently managed in extensive systems with large sizes, minimal , and inadequate facilities, resulting in untreated injuries, poor , and annual mortality rates estimated at 25-30% from in some contexts. Overcrowded or poorly maintained pastures often lack sufficient , , and veterinary care, contributing to spontaneous abortions in underconditioned animals and overall deficits. Handling is compounded by responses to workers, with reports of abusive methods like beating or electric prods in facilities prioritizing output over animal well-being. Induced abortions, typically after day 90 of when eCG production from endometrial cups persists, are performed to facilitate rebreeding and maximize yield per rather than being essential for extraction, imposing physical distress and potential fatality risks at this gestational stage. Such procedures, while not universally routine, occur in systems aiming to shorten cycles, leading to concerns including maternal recovery challenges and ethical debates over non-therapeutic interventions. varies significantly by and facility, with poorer outcomes documented in less-regulated areas, underscoring the need for standardized health monitoring to mitigate these issues.

Responses, Regulations, and Empirical Mitigations

In response to documented welfare issues in eCG production, veterinary organizations including the (AVMA), Canadian Veterinary Medical Association (CVMA), Federation of Veterinarians of Europe (FVE), and Federation of European Equine Veterinary Associations (FEEVA) endorsed the World Veterinary Association's 2023 position statement prioritizing donor welfare, advocating for research into alternatives, and emphasizing adherence to established standards during extraction. These bodies acknowledged that while poor practices can compromise health, proper management mitigates risks without necessitating production cessation. Regulatory frameworks vary by region, with no global standards but increasing scrutiny in import markets. In the , eCG use and imports face calls for prohibition under forthcoming animal welfare legislation, driven by parliamentary inquiries citing excessive blood extraction and routine abortions as violations of Directive 98/58/EC on farm animal protection; however, as of 2023, no outright ban exists, though audits highlight traceability gaps in third-country supplies. Production in occurs under general equine welfare guidelines enforced by provincial authorities and the National Farm Animal Care Council, but lacks eCG-specific mandates, prompting CVMA involvement in welfare endorsements. In Argentina and , where over 10,000 mares are used annually, operations exist in a legal grey area without dedicated regulations, relying on broad animal cruelty laws that investigations show are inadequately enforced. Empirical mitigations focus on standardized collection protocols to minimize physiological , as outlined in veterinary reviews: collections should not exceed 10% of estimated (typically 2-4 liters for a 500 kg ) every 7-14 days between days 40-130, with pre- and post-extraction monitoring of , hydration, and behavior to prevent or exhaustion. Studies confirm that trained handlers using jugular with when needed reduce spikes and injury risks compared to restraint-only methods, while supplemental feeding and veterinary oversight during peak production (days 55-70) maintain body condition scores above 5/9 on the Henneke scale. Post-collection abortions, often induced to recycle mares, are mitigated by allowing natural foaling in select protocols, though data indicate higher complication rates (up to 20% dystocia) without intervention; ongoing trials in compliant facilities report welfare indices comparable to non-production broodmares when volumes are capped. Industry adoption of these guidelines, including third-party audits, has been proposed via multinational consensus to address variability across producers.

Alternatives and Future Developments

Recombinant and Synthetic Forms

Recombinant equine chorionic gonadotropin (reCG) has been developed as a biotechnology-derived alternative to native eCG extracted from pregnant serum, primarily using ovary (CHO) cell lines to express the hormone's alpha and beta subunits. Production processes involve transient or stable , often with third-generation lentiviral vectors for efficient into suspension-adapted CHO-K1 cells, yielding bioactive reCG with patterns comparable to the native form despite minor differences in sialylation and isoform distribution. Recent advancements include mass production in DG44 cells, achieving expression levels of 364–470 /mL for single-chain reCG (β/α construct), which demonstrates potent FSH-like activity in stimulating production in granulosa cells and LH-like activity via receptors in CHO-K1 cells expressing equine or gonadotropin receptors. In vivo applications, such as supplementation in fixed-time protocols for suckled beef cows, have shown reCG to enhance pregnancy rates per AI (P/AI) to levels equivalent or superior to native eCG, with no reported adverse effects on quality or viability. Fully synthetic chemical production of eCG, a complex , remains undeveloped due to challenges in replicating its intricate and post-translational modifications, though recombinant methods effectively mimic its FSH/LH bioactivity without reliance on animal-derived sources. Ongoing efforts prioritize scaling reCG manufacturing for commercial veterinary use, addressing welfare concerns associated with traditional eCG harvesting while maintaining efficacy in superovulation and estrus synchronization in ruminants.

Ongoing Research and Market Trends (2020–Present)

Recent studies have focused on developing recombinant equine chorionic gonadotropin (reCG) to mitigate variability and issues associated with natural extracts from pregnant mares. In 2025, researchers established a manufacturing process using DG44 cells to produce single-chain reCG β/α at yields of 364–470 /mL, demonstrating bioactivity equivalent to native eCG in stimulating FSH- and LH-like responses and in models. Comparative trials in 2025 evaluated conventional purified eCG against reCG, finding no significant differences in follicular , luteal , or outcomes in treated animals, supporting reCG as a viable substitute. Efforts to standardize commercial products have revealed inconsistencies, with 2025 analyses showing only 5.5% protein commonality across four pregnant serum (PMSG) brands, prompting quality control methods like MA-10 cell progesterone assays and HPLC to predict biological potency without . Dosage optimization research from 2020–2024 examined eCG splitting protocols and high-dose effects, identifying adverse impacts like ovarian overstimulation at elevated levels while improving synchronization efficacy in and ruminants when administered in divided doses during progesterone treatments. The global PMSG/eCG , valued at USD 253 million in , is projected to reach USD 263.8 million in 2025 and USD 369.5 million by 2033, reflecting a of 4.3% driven by expanded programs in pigs, , and sheep seeking higher rates through hormonal . Demand persists in veterinary reproductive technologies, though production remains concentrated in regions like , where mare welfare concerns have intensified regulatory scrutiny, including a 2023 EU violation citation against for PMSG blood farms. Advances in reCG and synthetic analogs, such as peforelin tested in 2025 trials, signal a market shift toward ethical, consistent alternatives to reduce reliance on mare-derived products.

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