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Placental expulsion
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Placental expulsion
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Human placenta after expulsion

Placental expulsion (also called afterbirth) occurs when the placenta comes out of the birth canal after childbirth. The time between the expulsion of the baby and the expulsion of the placenta is called the third stage of labor.

The third stage of labor can be managed actively with several standard procedures, or it can be managed expectantly, with physiological management or passive management. The latter allows for the placenta to be expelled without medical assistance.

Although uncommon in some countries, the placenta is kept and consumed by the mother over the weeks following the birth. This practice is termed human placentophagy and can be harmful.[1]

Physiology

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Hormone induction of placental separation

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As the fetal hypothalamus matures, the activation of the hypothalamic–pituitary–adrenal (HPA) axis initiates labor through two hormonal mechanisms. The end pathway of both mechanisms lead to contractions in the myometrium, a mechanical cause of placental separation, which is due to the sheer force and contractile and involutive changes that occur within the uterus, distorting the placentome.

Fetal adrenocorticotropic hormone (ACTH)

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ACTH increases fetal cortisol which acts by two mechanisms:

PTGS in turn produces prostaglandin E2 which is a catalyst for pregnenolone to C-19 steroids, such as estrogen. Estrogen increases:

  • Vaginal lubrication
  • Softening of collagen fibre structures in the cervix, vaginal, and associated tissues
  • Increases contraction associated proteins (i.e., connexins)
  • Placental shedding by physiological inflammation (note that pathological inflammation often leads to retention of membranes, i.e., placentitis)

Fetal oxytocin

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As the HPA axis activates, the posterior pituitary of the fetus begins to increase production of oxytocin, which stimulates the maternal myometrium to contract.

Cellular changes of placental separation

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In the seventh month of pregnancy, the MHC-I complexes increase in the interplacentomal arcade reduces the bi- and tri-nucleate cells, a source of immune suppression in pregnancy. By the ninth month, the endometrial lining has thinned (due to loss of trophoblast giant cells) which exposes the endometrium directly to the fetal trophoblast epithelium. With this exposure and the increase in maternal MHC-I, T-helper 1 (Th1) cells, and macrophages induce apoptosis of trophoblast cells and endometrial epithelial cells, facilitating placental release. Th1 cells attract an influx of phagocytic leukocytes into the placentome at separation, allowing further degradation of the extracellular matrix.

Vascular changes of placental separation

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After delivery, loss of fetal blood return to the placenta allows for shrinkage and collapse of the cotyledonary villi with subsequent fetal membrane separation.[2]

Active management

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Methods of active management include umbilical cord clamping, stimulation of uterine contraction and cord traction.

Umbilical cord clamping

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Main article: Umbilical cord clamping

Active management routinely involves clamping of the umbilical cord, often within seconds or minutes of birth.

Uterine contraction

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Uterine contraction assists in delivering the placenta. Uterine contraction reduces the placental surface area, often forming a temporary hematoma at their former interface. Myometrial contractions can be induced with medication, usually oxytocin via intramuscular injection. The use of ergometrine, on the other hand, is associated with nausea or vomiting and hypertension.[3][needs update]

Breastfeeding soon after birth stimulates oxytocin which increases uterine tone, and through physical mechanisms uterine massage (targeting the fundus) also causes uterine contractions.

Cord traction

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Controlled cord traction (CCT) consists of pulling on the umbilical cord while applying counter pressure to help deliver the placenta.[4] It may be uncomfortable for the mother. Its performance requires specific training. Premature cord traction can pull the placenta before it has naturally detached from the uterine wall, resulting in hemorrhage. Controlled cord traction requires the immediate clamping of the umbilical cord.

A Cochrane review came to the results that controlled cord traction does not clearly reduce severe postpartum hemorrhage (defined as blood loss >1000 mL) but overall resulted in a small reduction in postpartum hemorrhage (defined as blood loss >500 mL) and mean blood loss. It did reduce the risk of manual placenta removal. The review concluded that use of controlled cord traction should be recommended if the care provider has the skills to administer it safely.[4]

Manual placenta removal

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Manual placenta removal is the evacuation of the placenta from the uterus by hand.[5] It is usually carried out under anesthesia or more rarely, under sedation and analgesia. A hand is inserted through the vagina and cervix into the uterine cavity and the placenta is detached from the uterine wall and then removed manually. A placenta that does not separate easily from the uterine surface indicates the presence of placenta accreta.

Efficacy of active management

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A Cochrane database study[3][needs update] suggests that blood loss and the risk of postpartum bleeding will be reduced in women offered active management of the third stage of labour. A summary[6] of the Cochrane study came to the results that active management of the third stage of labour, consisting of controlled cord traction, early cord clamping plus drainage, and a prophylactic oxytocic agent, reduced postpartum haemorrhage by 500 or 1000 mL or greater. It also reduced later morbidities including profuse blood loss, incidences of postpartum haemoglobin becoming less than 9 g/dL, blood transfusion, need for supplemental iron postpartum and length of third stage of labour. Although active management increased adverse effects such as nausea, vomiting, and headache, women were less likely to be dissatisfied.[6]

Retained placenta

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A retained placenta is a placenta that does not undergo expulsion within a normal time limit. Risks of retained placenta include hemorrhage and infection. If the placenta fails to deliver in 30 minutes in a hospital environment, manual extraction may be required if heavy ongoing bleeding occurs. Very rarely, a curettage is necessary to ensure that no remnants of the placenta remain (in conditions with very adherent placenta, placenta accreta). However, in birth centers and attended home birth environments, it is common for licensed care providers to wait for the placenta's birth up to 2 hours in some instances.[7]

Non-humans

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In most mammalian species, the mother bites through the cord and consumes the placenta, primarily for the benefit of prostaglandin on the uterus after birth.[citation needed] This is known as placentophagy. However, it has been observed in zoology that chimpanzees apply themselves to nurturing their offspring, and keep the fetus, cord, and placenta intact until the cord dries and detaches the next day.

The placenta exists in most mammals and some reptiles. It is likely polyphyletic, having arisen separately in evolution rather than being inherited from one distant common ancestor.[8]

Studies on pigs indicate that the duration of placenta expulsion increases significantly with increased duration of farrowing.[9]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Placental expulsion

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from Grokipedia
Placental expulsion refers to the delivery of the and its attached from the following the birth of the newborn, concluding the third stage of labor. This process typically occurs within 5 to 30 minutes after delivery, with a duration of about 6 minutes in uncomplicated cases, and is driven by that cause the placenta to separate from the uterine wall. The physiology of placental expulsion involves two main phases: separation and expulsion. During separation, ongoing myometrial contractions reduce the surface area of the placental site, creating a shearing force that detaches the , often starting from one edge and accompanied by a small gush of as retroplacental clots form. Expulsion follows as the contracts further, pushing the through the and , usually requiring only 2-3 additional contractions. Signs of successful separation include lengthening of the , a sudden rush of , and a globular of the uterine fundus upon . Management of placental expulsion can follow either physiological (also called expectant) or active approaches, each with distinct benefits and risks. Physiological management relies on natural and maternal pushing, without routine use of medications or cord traction, and is suitable for low-risk pregnancies, though it may result in higher average blood loss (often exceeding 500 mL in about 16.5% of cases) and longer duration, up to 1 hour. In contrast, active management incorporates administration of a agent like oxytocin immediately after birth, delayed cord clamping (1-5 minutes), and controlled cord traction to expedite delivery, reducing the risk of postpartum hemorrhage by up to 50% and severe bleeding by 60%, as recommended by the for most settings with skilled attendants. However, active methods carry potential side effects such as maternal , , or reduced early initiation. Complications during placental expulsion, though uncommon, can be serious and include (failure to deliver within 30 minutes, affecting less than 3% of vaginal births), which elevates the odds of postpartum hemorrhage by over sixfold and may necessitate manual removal under anesthesia. Other risks involve or cord avulsion, particularly if traction is applied prematurely, underscoring the importance of monitoring for complete expulsion to ensure maternal recovery.

Overview

Definition and Timing

Placental expulsion is the process of delivering the and , collectively known as the afterbirth, immediately following the birth of the baby. This event marks the completion of the third stage of labor in human childbirth. Labor is traditionally divided into three stages: the first stage, which encompasses and the descent of the through the birth canal; the second stage, involving the active expulsion of the ; and the third stage, focused on placental expulsion. The third stage begins at the moment of fetal delivery and concludes with the complete separation and delivery of the and membranes. In uncomplicated vaginal deliveries, spontaneous placental expulsion typically occurs within 5 to 30 minutes after birth, with an average duration of 8 to 9 minutes. Delays exceeding 30 minutes are considered prolonged and are associated with increased risks, including postpartum hemorrhage. The recognition of this phase as a distinct stage of labor emerged in 18th-century texts, such as Thomas Denman's Introduction to the Practice of (1782), which outlined physiological expectations and management principles for the . Normal blood loss during placental expulsion ranges from 200 to 500 mL, primarily resulting from the shearing of placental attachments and . This volume establishes baseline physiological norms, beyond which excessive may signal complications.

Clinical Signs of Separation

The primary clinical signs of placental separation during the third stage of labor include a lengthening of the as the placenta detaches and descends into the lower uterine segment, a sudden gush of blood from the due to the release of the retroplacental , and an upward shift of the uterine fundus as the contracts and elevates in the . These observable indicators, typically appearing within 5 to 10 minutes after fetal delivery, signal that the has detached from the uterine wall and is ready for expulsion. Secondary signs encompass a change in the uterine shape from discoid (flat and broad) to globular (rounded and firm), along with a reduction in overall uterine size as myometrial contraction compresses the placental site. These changes reflect the uterus adapting post-separation, with the fundus becoming more prominent and ballotable upon abdominal . Healthcare providers rely on direct and gentle to identify these signs, avoiding excessive traction that could lead to complications. Once separation occurs, the placenta is expelled through one of two mechanisms observed during delivery. In the Schultze mechanism, the shiny fetal surface emerges first, with the membranes trailing behind, which is the more common presentation. The Duncan mechanism involves expulsion of the rough maternal surface first, often accompanied by more visible bleeding. The Schultze mechanism accounts for approximately 80% of cases. Recognizing these signs is essential for timing interventions, such as controlled cord traction, to facilitate safe expulsion and prevent delays that increase the risk of postpartum hemorrhage if delivery exceeds 30 minutes.

Physiology

Hormonal Mechanisms

The hormonal mechanisms underlying placental expulsion involve coordinated endocrine signals from both fetal and maternal sources, primarily driving myometrial contractions and facilitating tissue separation during the third stage of labor. Fetal (ACTH), secreted by the fetal , plays a key role in initiating these processes by stimulating the fetal adrenal glands to produce . This , in turn, upregulates prostaglandin synthesis in the placental and fetal , particularly by inducing expression, which promotes myometrial contractions essential for placental detachment. Fetal oxytocin is released from the fetal during labor, potentially triggered by stresses and stimulation, but its role in is not direct. Complementing these fetal signals, maternal hormones are critical: oxytocin is released from the maternal in response to birth stimuli, such as vaginal distension and fetal ejection, generating powerful that shear the from the . Additionally, maternal prostaglandins, notably PGF2α produced by the and placental membranes, amplify these contractions and support expulsion, with plasma levels peaking shortly postpartum to originate from placental sources. The sequence of events begins with fetal endocrine activation—such as rising ACTH and levels—triggering maternal responses via increased and oxytocin output, culminating in effective placental separation. Following expulsion, a rapid decline in progesterone occurs due to the loss of the primary placental source, which further sustains uterine tone and prevents hemorrhage by removing progesterone's inhibitory effects on contractions. Evidence from animal models, particularly in sheep, supports these mechanisms; fetal , which eliminates ACTH production, delays parturition and associated placental delivery, while ACTH or infusions accelerate the process, highlighting the fetal pituitary-adrenal axis's regulatory role.

Cellular and Vascular Changes

During the third stage of labor, cellular alterations at the maternal-fetal interface play a critical role in enabling placental detachment. Trophoblast cells exhibit increased expression of major histocompatibility complex (MHC) class I molecules, particularly non-classical variants like HLA-G, which rise toward term and facilitate immune recognition without triggering rejection. This upregulation promotes a controlled alloimmune response at the interface. Concurrently, labor involves a shift toward pro-inflammatory immune responses that contribute to tissue remodeling essential for separation. Vascular changes further drive the detachment process by altering at the uteroplacental site. Following fetal delivery, cessation of fetal blood flow through the umbilical vessels leads to rapid shrinkage of the cotyledons, reducing l volume and creating space for separation from the uterine wall. compress the spiral arteries, halting maternal blood supply to the and generating shear forces that mechanically disrupt the decidual-l attachment. These forces, combined with myometrial retraction, shear the along its basal plate. A key feature of these vascular dynamics is the formation of a retroplacental , where maternal blood accumulates behind the due to ruptured decidual vessels. This expands to create a hydraulic plane of cleavage, further loosening the and accelerating its expulsion. Histological evidence from studies of term demonstrates that decidual breakdown facilitating this process is mediated by matrix metalloproteinases (MMPs), enzymes that degrade the at the interface, with increased MMP activity and reduced tissue inhibitors observed during labor. The plane of separation typically occurs within the basalis, specifically between its basal and spongy layers, where the spongy zone's dilated glands and looser structure provide a natural cleavage line. This distinction ensures efficient detachment without excessive invasion into deeper myometrial tissues, distinguishing normal expulsion from pathological conditions. These cellular and vascular changes are initiated by hormonal mechanisms that prime the interface for labor.

Management

Active Management

Active management of the third stage of labor involves a bundle of interventions designed to expedite placental expulsion and reduce the risk of postpartum hemorrhage. This approach, recommended by the (WHO) for use by skilled birth attendants, includes the administration of uterotonics, delayed umbilical cord clamping, and controlled cord traction. The primary component is the prophylactic administration of a agent, with oxytocin (10 IU intramuscularly) as the first-line choice, given immediately after the birth of the baby or delivery of the anterior shoulder. This mimics and enhances the natural release of endogenous oxytocin that promotes and placental separation. Alternatives such as ergometrine (0.2 mg intramuscularly) or syntometrine may be used if oxytocin is unavailable, particularly in women without , though oxytocin is preferred due to its and safety profile. Delayed cord clamping, typically for 1 to 3 minutes after birth or until the cord ceases pulsating, is incorporated to allow placental transfusion to the newborn, balancing maternal and neonatal benefits. Following administration and signs of placental separation (such as cord lengthening), controlled cord traction (CCT) is performed with simultaneous counter-pressure on the via to prevent . This technique, also known as the Brandt-Andrews maneuver, requires precise execution by trained providers, as improper application can lead to rare but serious complications like (incidence <0.01%).02204-9/fulltext) In low-resource settings, the WHO endorses this bundled protocol as a standard for preventing excessive blood loss, emphasizing implementation by skilled attendants who have received specific training in normal delivery and complication management. Prophylactic manual removal of the is not routine but may be considered rarely if immediate separation fails despite these interventions, typically after 30 minutes of observation. Historically, evolved in the , building on 19th-century techniques like the Credé maneuver (manual uterine expression) introduced in 1853, with key advancements including the isolation of ergometrine in 1932 and synthetic oxytocin in 1953. The modern bundle, formalized through international collaborations like those of the International Confederation of Midwives and FIGO in the late , gained WHO endorsement in the 1970s and was refined based on evidence from randomized trials in the and .

Expectant Management

Expectant management, also referred to as physiological or spontaneous management, of the third stage of labor entails a non-interventionist strategy that relies on the body's natural processes to achieve placental separation and expulsion without the routine administration of uterotonics, early clamping, or controlled cord traction. This approach prioritizes observation and support for maternal and neonatal , typically reserved for low-risk births where immediate access to emergency care is available. The protocol for expectant management involves close monitoring of the mother and newborn for up to 60 minutes following fetal delivery, though guidelines from organizations such as the International Confederation of Midwives (ICM) and the International Federation of Gynecology and Obstetrics (FIGO) suggest intervening if expulsion does not occur within 30 to 45 minutes in low-resource settings. Care providers encourage upright positioning, bladder emptying, and maternal efforts such as bearing down to facilitate delivery, while maintaining skin-to-skin contact between mother and infant to promote bonding and breastfeeding initiation. The umbilical cord is clamped only after it stops pulsating or after placental expulsion, allowing for delayed cord clamping; this practice increases neonatal hemoglobin levels at birth and enhances iron stores for up to several months, reducing the risk of iron deficiency anemia. Placental expulsion under this method typically occurs spontaneously through gravity and uterine contractions, with a mean duration of approximately 10 to 15 minutes, longer than in active management approaches. This management strategy aligns with guidelines from the ICM and FIGO, which endorse it as a core competency for uncomplicated vaginal births in low-risk women, emphasizing informed choice and the avoidance of unnecessary interventions. The National Institute for Health and Care Excellence (NICE) in the UK also recommends discussing expectant management as an option, allowing women to select based on their preferences. In contexts where uterotonics are unavailable or contraindicated, the (WHO) views expectant management as an acceptable alternative to active methods. Historically, expectant represents the traditional cornerstone of practice, predating the widespread adoption of active interventions in the mid-20th century, and embodies a "hands-off" that trusts physiological processes while awaiting natural signs of separation such as cord lengthening or uterine gush. By facilitating uninterrupted skin-to-skin contact and delayed cord clamping, it supports optimal neonatal transition and maternal-infant attachment without compromising safety in appropriately selected cases.

Complications

Retained Placenta

Retained placenta refers to the incomplete or absent expulsion of the following delivery, typically diagnosed when the has not separated and been delivered within 30 minutes of birth in settings using of the third stage of labor, or within 60 minutes in community or physiological management scenarios. This condition can be classified as partial, where fragments of the remain in the , total, involving the entire , or adherent, such as in cases of where abnormal attachment prevents separation. Adherent forms arise from defective , often in the context of prior , leading to invasion into the . The incidence of retained placenta is approximately 2-3% among vaginal deliveries, with higher rates observed in preterm births and physiological management approaches. It serves as a significant contributor to early postpartum hemorrhage, accounting for about 20% of severe cases, primarily due to disrupted uterine contraction and potential infection risks if untreated. Key risk factors include a history of previous retained placenta, which increases recurrence odds, as well as uterine abnormalities such as fibroids or Asherman syndrome that impair myometrial function. Intrauterine infection, like chorioamnionitis, can exacerbate retention by promoting inflammation and atony, while placenta accreta spectrum elevates risk dramatically, particularly with prior cesarean deliveries and placenta previa, where risks can exceed 60% with multiple priors. Preterm delivery and labor induction are also associated, reflecting underlying placental or uterine dynamics. Diagnosis begins with clinical assessment during the third , noting failure of expulsion and signs like a firm, non-rising fundus or continued ; is employed to confirm retained fragments or adherence, visualizing echogenic material in the . In adherent cases, imaging may reveal loss of the hypoechoic retroplacental zone. Management involves an initial period of 10-15 minutes after the 30-minute threshold in settings to allow potential spontaneous separation, followed by manual removal under regional or general if unsuccessful. Pharmacological support, such as (a analog) at 250 mcg intramuscularly, aids in addressing associated to facilitate expulsion or control bleeding during intervention. For adherent , conservative approaches like leaving the placenta with uterotonics may be considered in stable patients to avoid , though surgical removal remains standard.

Postpartum Hemorrhage

Postpartum hemorrhage (PPH) is defined as a cumulative blood loss of ≥1000 mL or blood loss accompanied by signs of such as or within 24 hours of birth (primary PPH), applicable to both vaginal and cesarean deliveries. Abnormal or delayed placental expulsion contributes to PPH through resulting from incomplete placental separation, which impairs myometrial contraction and at the placental site. Retained placental fragments can further exacerbate bleeding by acting as a persistent trigger for ongoing hemorrhage, preventing the from contracting effectively. The overall incidence of PPH is estimated at 3-5% in high-resource settings, representing a leading cause of maternal morbidity worldwide. However, this risk escalates significantly in cases of abnormal placental expulsion, with associated with PPH in up to 20% of severe cases and conferring a markedly higher likelihood of excessive blood loss compared to uncomplicated deliveries. , often linked to incomplete separation, accounts for the majority of PPH episodes in this context, underscoring the need for prompt recognition of expulsion delays. Initial management of PPH related to placental expulsion abnormalities focuses on stabilizing the patient through administration of uterotonic agents such as oxytocin or to promote and reduce bleeding. Bimanual uterine compression is employed as a non-invasive technique to mechanically counteract atony by applying pressure to the , often in conjunction with uterotonics. If these measures fail, surgical interventions may be required, including compression sutures (e.g., B-Lynch technique), arterial ligation, or, in extreme refractory cases, to achieve . Evidence from systematic reviews, including the Cochrane analysis, demonstrates that of the third stage of labor—incorporating prophylactic uterotonics and controlled cord traction—reduces the incidence of severe PPH by approximately 60% compared to expectant approaches, particularly in mitigating risks tied to expulsion delays. This reduction highlights the preventive value of such strategies in addressing atony and incomplete separation as precursors to hemorrhage.

Other Complications

Uterine inversion and cord avulsion are rare but serious complications associated with placental expulsion, often linked to improper cord traction. occurs when the uterus turns inside out, with an incidence of about 1 in 20,000 deliveries, and can lead to profound hemorrhage and shock if not promptly corrected manually or surgically. Cord avulsion, where the tears from the during traction, affects less than 1% of cases but may result in retained fragments and increased bleeding risk. Monitoring and adherence to guidelines for traction timing are essential to prevent these events.

In Non-Human Species

Physiological Processes

In mammals, the physiological processes of placental expulsion exhibit notable similarities to those observed in humans, particularly among eutherian species, where uterine contractions driven by hormonal surges play a central role. Oxytocin release stimulates uterine myometrial contractions that shear the placenta from the uterine wall, while prostaglandins, often triggered by oxytocin, enhance these contractions and facilitate separation by promoting cervical ripening and myometrial activity. This hormonal interplay is conserved across species, including equids and ruminants, where oxytocin induces prostaglandin release from placental tissues to coordinate expulsion. Additionally, vascular changes such as the formation of a retroplacental hematoma contribute to separation in hemochorial placentas, where maternal blood accumulation behind the placenta aids in detaching the fetal membranes, a mechanism evident in primates and rodents. Despite these conserved elements, significant variations exist in the duration and regulation of placental expulsion among species, often influenced by reproductive strategies and litter characteristics. In canines, expulsion typically occurs rapidly, within 5-15 minutes following each pup's delivery, reflecting the multiparous nature of the species and efficient uterine dynamics. In contrast, suids like pigs experience longer expulsion phases, often lasting 20 minutes to 4 hours after the last piglet, with duration positively correlated to litter size due to extended farrowing times that strain uterine contractility. demonstrate even more accelerated processes, with placental expulsion immediately post-parturition triggering rapid uterine remodeling via degradation, while primates such as baboons closely mirror timelines, with expulsion occurring up to two hours after birth aided by similar oxytocin-driven contractions. Evolutionary conservation underscores retroplacental separation as a hallmark of eutherian mammals, stemming from an ancestral hemochorial that enabled intimate maternal-fetal exchange and facilitated post-parturient detachment through hematoma formation and contraction. Placental structures, while diverse, trace to a monophyletic origin in early eutherians, with polyphyletic-like variations in interhemal barriers (e.g., epitheliochorial in ungulates versus hemochorial in and ) arising from adaptive radiations that preserved core expulsion mechanisms. These parallels to , particularly in hormonal regulation, are explored using animal models like sheep, where fetal ACTH surges initiate release to prime uterine sensitivity for oxytocin-mediated expulsion, informing studies on preterm labor and placental retention.

Behavioral Aspects

Placentophagy, the consumption of the following expulsion, is a widespread behavior observed in nearly all female terrestrial eutherian mammals, encompassing over 4,000 species, with notable exceptions among aquatic mammals like cetaceans and semi-aquatic pinnipeds, as well as camelids. This practice is particularly prevalent in such as rats and , where both mothers and occasionally males or weanlings ingest the to facilitate cleanup and . In herbivores like and , which typically avoid animal tissues, the behavior persists post-parturition, aiding in the removal of birth remnants from the environment. The primary functions of placentophagy in species include recovery, modulation, and ecological adaptations for offspring protection. The provides essential proteins, calories, vitamins, and trace elements, such as iron, helping to replenish maternal reserves depleted during and labor. It also contains hormones that may support postpartum recovery. Additionally, the of placental and material releases placental opioid-enhancing factor (POEF), which amplifies endogenous activity, providing analgesia that can increase thresholds by 100–500% in rats and enhance opioid-mediated analgesia in cows, thereby easing discomfort during and after expulsion. Furthermore, by consuming the , mothers reduce olfactory cues from blood and tissues that could attract predators, minimizing risks to newborns in vulnerable wild settings. In contrast to its ubiquity in non-human mammals, placentophagy is traditionally absent in humans and has only recently emerged in some Western cultures since the , often through encapsulation of dehydrated placental tissue for consumption. Proponents claim benefits like hormonal balance and pain relief, but comprehensive reviews indicate no verifiable postpartum advantages, with nutrients and hormones largely degraded during . Risks include bacterial infections from improper handling, as evidenced by cases of linked to contaminated capsules. This human aversion may stem from evolutionary adaptations in ; while all non-human routinely practice placentophagy, humans appear to have lost the , potentially due to ancestral use introducing toxins like into the via smoke exposure, rendering consumption deleterious to fitness. Beyond , other post-expulsion behaviors in focus on and predator deterrence, such as maternal grooming or licking of to remove amniotic fluids and establish bonding, observed in and carnivores . In some that do not consume the placenta, such as certain or ungulates, mothers may bury or disperse the remains to mask odors and avoid drawing predators to the birth site. These actions typically occur shortly after expulsion, aligning with the rapid physiological processes that facilitate separation in animals.

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