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Obstetrical bleeding
Obstetrical bleeding
Obstetrical bleeding
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Obstetrical bleeding
Other namesMaternal bleeding, obstetrical hemorrhage, obstetric haemorrhage,[1] maternal hemorrhage
SpecialtyObstetrics
Frequency8.7 million (2015)[2]
Deaths83,000 (2015)[3]

Obstetrical bleeding is bleeding in pregnancy that occurs before, during, or after childbirth.[4] Bleeding before childbirth is that which occurs after 24 weeks of pregnancy.[4] Bleeding may be vaginal or less commonly into the abdominal cavity. Bleeding which occurs before 24 weeks is known as early pregnancy bleeding.

Causes of bleeding before and during childbirth include cervicitis, placenta previa, placental abruption and uterine rupture.[4][5] Causes of bleeding after childbirth include poor contraction of the uterus, retained products of conception, and bleeding disorders.[4]

About 8.7 million cases of severe maternal bleeding occurred in 2015[2] resulting in 83,000 deaths.[3] Between 2003 and 2009, bleeding accounted for 27% of maternal deaths globally.[6]

Later pregnancy

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Main article: Antepartum bleeding

Antepartum bleeding (APH), also prepartum hemorrhage, is bleeding during pregnancy from the 24th week[7] (sometimes defined as from the 20th week[8][7]) gestational age up to the birth of the baby.[5] The primary consideration is the presence of a placenta previa which is a low lying placenta at or very near to the internal cervical os. This condition occurs in roughly 4 out of 1000 [9] pregnancies and usually needs to be resolved by delivering the baby via cesarean section. Also a placental abruption (in which there is premature separation of the placenta) can lead to obstetrical hemorrhage, sometimes concealed. This pathology is of important consideration after maternal trauma such as a motor vehicle accident or fall.

Other considerations to include when assessing antepartum bleeding are: sterile vaginal exams that are performed in order to assess dilation of the patient when the 40th week is approaching. As well as cervical insufficiency defined as a midtrimester (14th-26th week) dilation of the cervix which may need medical intervention to assist in keeping the pregnancy sustainable.[10]

During labor

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Besides placenta previa and placental abruption, uterine rupture can occur, which is a very serious condition leading to internal or external bleeding. Bleeding from the fetus is rare, but may occur with two conditions called vasa previa and velamentous umbilical cord insertion where the fetal blood vessels lie near the placental insertion site unprotected by Wharton's jelly of the cord.[11] Occasionally this condition can be diagnosed by ultrasound. There are also tests to differentiate maternal blood from fetal blood which can help in determining the source of the bleed.

After delivery

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Main article: Postpartum bleeding

Abnormal bleeding after delivery, or postpartum hemorrhage, is the loss of greater than 500 ml of blood following vaginal delivery, or 1000 ml of blood following cesarean section. Other definitions of excessive postpartum bleeding are hemodynamic instability, drop of hemoglobin of more than 10%,[12] or requiring blood transfusion. In the literature, primary postpartum hemorrhage is defined as uncontrolled bleeding that occurs in the first 24 hours after delivery while secondary hemorrhage occurs between 24 hours and six weeks.[13]

Risk factors

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In rare cases, inherited bleeding disorders, like hemophilia, von Willebrand disease (vWD), or factor IX or XI deficiency, may cause severe postpartum hemorrhage, with an increased risk of death particularly in the postpartum period.[13] The risk of postpartum hemorrhage in patients with vWD and carriers of hemophilia has been found to be 18.5% and 22% respectively. This pathology occurs due to the normal physiological drop in maternal clotting factors after delivery which greatly increases the risk of secondary postpartum hemorrhage.[14] Another bleeding risk factor is thrombocytopenia, or decreased platelet levels, which is the most common hematological change associated with pregnancy induced hypertension. If platelet counts drop less than 100,000 per microliter the patient will be at a severe risk for inability to clot during and after delivery.[15]

Medical tests

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If a small amount of bleeding is seen in early pregnancy a physician may request:

  • A quantitative human chorionic gonadotropin (hCG) blood test to confirm the pregnancy or assist in diagnosing a potential miscarriage [16]
  • Transvaginal pelvic ultrasonography to confirm that the pregnancy is not outside of the uterus[16]
  • Blood type and Rh test to rule out hemolytic disease of the newborn[16]

For bleeding seen in later pregnancy tests may include:

Unrelated bleeding

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Pregnant patients may have bleeding from the reproductive tract due to trauma, including sexual trauma, neoplasm, most commonly cervical cancer, and hematologic disorders. Molar pregnancy (also called hydatiform mole) is a type of pregnancy where the sperm and the egg have joined within the uterus, but the result is a cyst resembling a grape-like cluster rather than an embryo. Bleeding can be an early sign of this tumor developing.[17]

See also

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References

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Obstetrical bleeding

View on Grokipedia
from Grokipedia
Obstetrical bleeding, also referred to as obstetric hemorrhage, encompasses from the genital tract that occurs during (antepartum), labor and delivery (intrapartum), or the , posing significant risks to maternal and fetal health. It is a leading cause of maternal mortality worldwide, accounting for approximately 27% of all such deaths, with postpartum hemorrhage alone responsible for around 70,000 annual fatalities. The condition is broadly classified into three temporal categories based on timing relative to delivery. Antepartum hemorrhage (APH) is defined as bleeding after 20 weeks of until the onset of labor, affecting 3-5% of pregnancies and often resulting from placental abnormalities. Intrapartum hemorrhage occurs during active labor and may stem from complications like or cervical lacerations. Postpartum hemorrhage (PPH), the most prevalent and severe form, is characterized by blood loss exceeding 500 mL following or 1,000 mL after cesarean section within 24 hours, or any bleeding accompanied by signs of , occurring in 1-5% of all births. Key etiologies vary by type but share underlying mechanisms related to disrupted placental attachment, uterine tone, or coagulation. For APH, the primary causes are placental abruption (premature separation of the placenta, incidence 5-6 per 1,000 deliveries) and placenta previa (low-lying placenta covering the cervix, prevalence 4-5 per 1,000 term pregnancies), with unexplained bleeding accounting for about 50% of cases. In PPH, the "4 Ts" framework outlines the main contributors: Tone (uterine atony, responsible for ~70% of cases), Trauma (genital tract lacerations or uterine rupture), Tissue (retained placental fragments), and Thrombin (coagulopathies, such as disseminated intravascular coagulation). Risk factors across all types include advanced maternal age, multiple gestation, prior cesarean delivery, and conditions like preeclampsia or infection. Prevention and management emphasize multidisciplinary protocols to mitigate morbidity, including , preterm delivery, and the need for transfusion or . of the third stage of labor—using uterotonics like oxytocin—reduces PPH risk by up to 60%, while antenatal screening via helps identify APH risks like placenta previa. Initial treatment focuses on stabilization with intravenous fluids, blood products, and quantitative blood loss assessment, followed by targeted interventions such as uterine massage, , or surgical options for refractory cases. Despite advances, disparities persist, with higher burdens in low-resource settings where timely access to care is limited.

Overview

Definition and Epidemiology

Obstetrical bleeding, also known as obstetric hemorrhage, refers to excessive from or into the genital tract that is associated with and poses a risk to . It encompasses antepartum hemorrhage (APH), defined as bleeding after 20 weeks of and before the onset of labor; intrapartum hemorrhage, occurring during active labor; and postpartum hemorrhage (PPH), which involves loss within 24 hours of delivery (primary PPH) or up to 12 weeks postpartum (secondary PPH). Quantitative thresholds for include a cumulative loss of greater than 500 mL following or greater than 1,000 mL after cesarean section, often accompanied by signs of such as or . Globally, obstetrical bleeding affects millions of women annually, with APH occurring in approximately 3-5% of pregnancies and PPH in 1-5% of deliveries, impacting an estimated 14 million women each year. It remains a leading direct cause of maternal mortality, accounting for over 20% of such deaths worldwide and resulting in nearly 45,000 fatalities in 2023 alone. Incidence rates are markedly higher in low- and middle-income countries, where PPH prevalence can reach 5.1% in regions like compared to 1.5% in high-income settings, largely due to disparities in access to timely interventions and healthcare infrastructure. Recent trends indicate a rising incidence of PPH, from about 2.7% in 2000 to 4.3% in 2019 in the United States, attributed in part to increased cesarean delivery rates, which have climbed globally from around 12% in 2000 to over 21% by 2020. Historically, obstetrical bleeding contributed to extraordinarily high maternal mortality rates, with hemorrhage responsible for up to 50% of pregnancy-related deaths before , when overall rates exceeded 800 per 100,000 live births in many regions due to limited medical interventions and poor . Significant reductions occurred in the through advancements such as the introduction of of the third stage of labor (AMTSL), which includes uterotonic administration, delayed cord clamping, and controlled cord traction, decreasing PPH risk by up to 60% and contributing to a 40% global decline in maternal mortality ratios from 2000 to 2023.

Classification

Obstetrical bleeding is primarily classified by timing relative to delivery, which helps in anticipating clinical risks and management strategies. Antepartum hemorrhage refers to occurring from 20 weeks of until the onset of labor. Intrapartum hemorrhage involves bleeding during active labor and delivery. Postpartum hemorrhage is subdivided into early (or primary) occurring within the first 24 hours after delivery, and late (or secondary) from 24 hours up to 12 weeks postpartum. Classification by etiology distinguishes between primary causes, which are directly related to obstetric conditions such as placental abnormalities, and secondary causes stemming from non-obstetric factors like trauma or underlying medical disorders. This differentiation aids in identifying whether the bleeding arises from pregnancy-specific mechanisms or extraneous complications. Severity grading focuses on estimated blood loss volume combined with clinical signs of hypovolemia to assess urgency. Mild hemorrhage typically involves 500–1,000 mL of blood loss with minimal symptoms; moderate ranges from 1,000–2,000 mL with tachycardia and hypotension; and severe exceeds 2,000 mL or includes hypovolemic shock requiring immediate intervention. These categories overlap in clinical practice; for instance, antepartum hemorrhage may progress to intrapartum bleeding if labor ensues during an episode. Postpartum hemorrhage represents the primary focus, accounting for over 80% of all obstetrical bleeding cases globally. Recent epidemiology indicates rising rates of postpartum hemorrhage in high-resource settings, potentially linked to increasing cesarean deliveries.

Antepartum Hemorrhage

Causes

Antepartum hemorrhage (APH) refers to from the genital tract occurring after 20 weeks of and before the onset of labor. It complicates 3-5% of pregnancies and is a leading cause of and maternal morbidity. The primary causes include and placenta previa, with unexplained bleeding accounting for approximately 50% of cases. , the premature separation of the normally implanted , has an incidence of 5-6 per 1,000 deliveries and is associated with risks such as , , , multiple , and prior cesarean delivery. Placenta previa, characterized by a low-lying partially or completely covering the cervical os, occurs in 4-5 per 1,000 term pregnancies and is linked to multiparity, previous cesarean sections, and . Other less common causes encompass , vasa previa, cervical or vaginal lesions, and show (bloody discharge from cervical capillaries). Risk factors for APH overall include maternal conditions like , use, and trauma, as well as fetal factors such as .

Diagnosis

Diagnosis of antepartum hemorrhage involves a systematic approach to identify the cause, assess severity, and evaluate maternal and fetal well-being. Initial history-taking focuses on the onset, amount, and nature of bleeding (painless for placenta previa, painful for abruption), associated symptoms like or contractions, and risk factors. Fetal movements and are also noted. Physical examination begins with vital signs to detect hypovolemia (tachycardia, hypotension) and abdominal palpation for uterine tenderness, tone, or fetal presentation. Speculum examination is performed if stable to visualize the and rule out local causes like polyps or , but digital vaginal examination is avoided if placenta previa is suspected to prevent inducing severe bleeding. Continuous fetal heart rate monitoring via (CTG) assesses for distress. Ultrasound is the primary imaging modality, with transabdominal or transvaginal scans confirming placenta previa (sensitivity >95%) and estimating blood loss, though it has low sensitivity (25%) for detecting , relying instead on clinical signs like a tense, tender . Laboratory tests include for , coagulation profile to screen for (common in severe abruption), and /cross-match. For RhD-negative women, a Kleihauer-Betke test quantifies fetomaternal hemorrhage to guide anti-D immunoglobulin administration.

Management

Management of antepartum hemorrhage prioritizes maternal stabilization, fetal monitoring, and cause-specific interventions, with decisions guided by , bleeding severity, and fetal status. Upon , the ABCDE approach is used: secure airway/breathing, ensure circulation with two large-bore IV lines and crystalloids, and monitor disability/exposure. is grouped and cross-matched, and a multidisciplinary team (obstetrician, anesthetist, neonatologist) is activated for significant (>500 mL or shock). Expectant management is appropriate for stable cases with minor , involving , tocolysis if contractions occur, and serial ultrasounds/CTG. Corticosteroids (betamethasone) are administered between 24+0 and 34+6 weeks to promote fetal lung maturity if preterm delivery is likely. Anti-D immunoglobulin is given to RhD-negative women within 72 hours. For placenta previa, hospitalization is recommended from 32-36 weeks, with planned cesarean delivery at 36-37 weeks. In severe cases, such as major abruption with fetal compromise or maternal instability, immediate delivery is indicated—vaginal if feasible and stable, or cesarean section otherwise. requires emergency . Blood products (packed red cells, ) are transfused if loss exceeds 1,000 mL or develops. Post-management, monitoring for complications like preterm labor or is essential.

Intrapartum Hemorrhage

Causes

Intrapartum hemorrhage refers to significant occurring during the first or second stage of labor, before delivery of the , complicating approximately 2-5% of pregnancies and posing risks of maternal and fetal distress. Common causes include continuation of antepartum conditions, such as (prevalence 0.4-1% of pregnancies, often presenting with concealed bleeding and uterine hypertonus) and placenta previa (0.3-0.5% at term, triggered by ). , a rare but life-threatening event (incidence 0.5-1% in women with prior cesarean delivery, higher with labor augmentation), results from weakened uterine wall leading to extravasation of blood into the or broad ligament. Genital tract trauma, including cervical or vaginal lacerations, accounts for up to 20% of cases and is associated with operative vaginal deliveries or rapid labor. Vasa previa, where fetal vessels traverse the membranes over the cervical os (incidence 1 in 2500-5000 pregnancies), can cause rapid fetal exsanguination upon membrane rupture. disorders may also manifest with bleeding during labor attempts in undiagnosed cases. Unexplained hemorrhage occurs in about 50% of instances. Risk factors include , multiparity, prior uterine surgery, and conditions like .

Diagnosis

Diagnosis of intrapartum hemorrhage involves rapid assessment during labor to identify the source, quantify blood loss, and evaluate maternal stability and fetal well-being, as delays can lead to shock or fetal hypoxia. Initial evaluation includes a focused history of bleeding onset, volume, and associated symptoms (e.g., , contractions), followed by external inspection of the and for visible lacerations or pooling blood. If stable and delivery not imminent, sterile speculum examination visualizes the and vaginal walls to distinguish cervical/vaginal trauma from intrauterine sources. Abdominal palpation assesses for uterine tenderness (suggesting abruption) or abnormal contour (indicating rupture). Continuous monitors fetal heart rate for decelerations or signaling compromise. Bedside ultrasound, if feasible without delaying care, evaluates placental location (to confirm previa or accreta), estimates blood loss, and detects retroplacental clots in abruption, though sensitivity is limited in active labor. For suspected vasa previa, color Doppler may identify vessels over the os. Laboratory tests are ordered urgently: for /, coagulation profile (PT/PTT, fibrinogen) to screen for in abruption, and blood type/crossmatch for potential transfusion. Signs of severity include maternal (>100 bpm), , or estimated loss >500 mL, prompting immediate intervention. Differential includes distinguishing from show or minor bleeding.

Management

Management prioritizes maternal , fetal monitoring, cause identification, and prompt delivery to and prevent complications like or emergency . Upon recognition of significant hemorrhage (>250-500 mL or with instability), activate the multidisciplinary obstetric emergency team including senior obstetrician, anesthetist, neonatologist, and hematologist. Establish two large-bore IV lines for crystalloid infusion (initial 1-2 L balanced solution) and prepare blood products; transfuse if loss exceeds 1000 mL or hemodynamic instability occurs (e.g., systolic BP <90 mmHg), following massive transfusion protocols with plasma and platelets in 1:1:1 ratio if needed. Administer oxygen to maintain SpO2 >94% and position in left lateral decubitus to optimize uteroplacental . Cause-specific treatment is initiated concurrently: for suspected rupture, proceed to emergent for repair or ; lacerations require direct suture repair under . Avoid uterotonics like oxytocin if abruption is likely, as they may worsen hypertonus, but use judiciously for augmentation if needed. Delivery is expedited via the safest route: instrumental vaginal if head is low and stable, or cesarean section for instability, malpresentation, or fetal distress. Continuous fetal monitoring guides timing. Post-delivery, transition to active management to prevent PPH, but primary focus remains intrapartum stabilization. Protocols emphasize quantitative blood loss measurement (e.g., calibrated drapes) and drills for . In low-resource settings, increase mortality .

Postpartum Hemorrhage

Causes

Postpartum hemorrhage (PPH) is a leading cause of maternal mortality worldwide, with being the most common etiology. The causes of primary PPH, occurring within 24 hours of delivery, are systematically classified using the "4 Ts" mnemonic: Tone, Trauma, Tissue, and . Tone refers to uterine atony, which accounts for 70-80% of PPH cases and arises from the failure of myometrial contraction to compress uterine blood vessels after placental expulsion. This is often precipitated by uterine overdistension from factors such as multiple gestation, fetal macrosomia, or , as well as or augmented labor. Additional risks include operative , which can contribute to and impaired contractility. Trauma encompasses physical injuries to the genital tract and represents approximately 20% of PPH etiologies. These include vaginal or cervical lacerations, hematomas in the or broad ligament, and , particularly in cases of or operative interventions such as forceps-assisted or vacuum delivery. Tissue involves retained , occurring in 2-3% of deliveries and preventing effective by occupying the endometrial cavity. This category includes incomplete placental separation, succenturiate placental lobes, or fragments of membranes, often linked to prior cesarean delivery or abnormal . Thrombin denotes coagulopathies, which cause about 1% of PPH cases through impaired hemostasis. Acquired forms include disseminated intravascular coagulation (DIC) secondary to placental abruption, amniotic fluid embolism, or severe preeclampsia, while inherited disorders such as von Willebrand disease exacerbate bleeding tendencies. Late PPH, defined as excessive bleeding more than 24 hours postpartum, has distinct etiologies including subinvolution and infection. Subinvolution involves delayed or incomplete involution of the placental site, where persistent myometrial hypertrophy and open vascular channels fail to regress, leading to ongoing hemorrhage typically 1-2 weeks after delivery. This may result from hormonal imbalances or retained tissue impairing normal uterine remodeling. Infection, such as endometritis, promotes tissue breakdown through inflammatory cytokine release and bacterial invasion of the endometrium, eroding the healing placental bed and provoking bleeding, often in the context of prolonged rupture of membranes or cesarean delivery.

Prevention

Prevention of postpartum hemorrhage (PPH) focuses on proactive measures implemented antenatally, intrapartum, and immediately following delivery to mitigate risks such as . Antenatal strategies include routine iron supplementation to address , a key modifiable , with guidelines recommending 30–60 mg of elemental iron daily for all pregnant individuals to prevent . Screening for coagulopathies during is also essential, involving laboratory assessments like and fibrinogen levels in those with identified risks, to enable early intervention and reduce bleeding complications. Intrapartum interventions emphasize optimizing labor progression to avoid exhaustion of uterine musculature. Active efforts to prevent , through timely augmentation if needed, have been shown to lower PPH incidence by reducing uterine fatigue. Judicious use of —restrictive rather than routine—is advised to minimize genital tract trauma, with evidence supporting its selective application in cases like fetal distress to avoid unnecessary extensions that could exacerbate bleeding. Preparedness for surgical interventions, such as internal iliac artery ligation, is incorporated into care bundles for high-risk deliveries, ensuring rapid access to vascular control techniques if bleeding escalates. The cornerstone of immediate postpartum prevention is of the third stage of labor (AMTSL), which comprises administration of a agent like oxytocin (10 IU intramuscularly or intravenously), controlled cord traction, and to expedite placental delivery and promote . This bundled approach significantly reduces PPH risk, with systematic reviews indicating up to a 60% decrease in severe compared to expectant management. Per the 2025 WHO/FIGO guidelines, prevention emphasizes such as oxytocin as first-line, with heat-stable or as alternatives in low-resource settings where is unavailable; prophylactic is not recommended. Global initiatives, including WHO and UNICEF-supported care bundles, integrate these elements with and . The 2025 consolidated guidelines introduce standardized protocols, including the MOTIVE bundle for treatment, to reduce mortality in low-resource settings.

Diagnosis and Treatment

According to the 2025 WHO/FIGO guidelines, postpartum hemorrhage (PPH) is defined as blood loss of ≥300 mL accompanied by signs of (e.g., >100 bpm, systolic <100 mmHg) or ≥500 mL within 24 hours of birth, with particular vigilance in the first 2 hours postpartum. begins with quantitative assessment of blood loss, which is more accurate than visual estimation and involves tools such as calibrated under-buttocks drapes to collect and measure fluid volume during vaginal delivery. Vital signs monitoring, including heart rate, blood pressure, and shock index (heart rate divided by systolic blood pressure), is essential to detect early, with a shock index ≥1 indicating severe compromise. A bimanual uterine examination assesses for atony by evaluating tone and contraction, often combined with uterine massage to stimulate response. For suspected coagulopathy, rotational thromboelastometry (ROTEM) or thromboelastography provides point-of-care evaluation of hemostasis, guiding targeted transfusion and reducing unnecessary plasma use. Treatment follows a stepwise approach aligned with the 2025 WHO/FIGO MOTIVE bundle (Massage, Oxytocics, Tranexamic acid, Intravenously, Empty bladder/Examination, eScalate), initiated within 15 minutes of diagnosis. Oxytocin infusion (20-40 IU in 1 L crystalloid at 125-250 mL/hour) is first-line, administered immediately upon PPH recognition. If ineffective, misoprostol 600 mcg rectally is added as a second-line uterotonic. Tranexamic acid 1 g IV, given within 3 hours of bleeding onset, reduces mortality from hemorrhage without increasing thromboembolic risks, as demonstrated in the WOMAN trial. Mechanical measures, such as uterine balloon tamponade with a device like the Bakri balloon, control atonic bleeding in up to 85% of cases unresponsive to uterotonics. If bleeding persists, surgical interventions escalate progressively. Uterine compression sutures, such as the B-Lynch technique, restore tone non-destructively. Uterine artery embolization offers a fertility-preserving option in hemodynamically stable patients with interventional radiology access. Hysterectomy serves as the last resort for uncontrollable hemorrhage, performed when all prior measures fail. Concurrent resuscitation is critical, employing massive transfusion protocols with a 1:1:1 ratio of packed red blood cells, fresh frozen plasma, and platelets to address dilutional coagulopathy. Fibrinogen concentrate is administered if levels fall below 2 g/L, as low fibrinogen predicts severe PPH progression and responds well to supplementation. For late or secondary PPH occurring 24 hours to 12 weeks postpartum, management targets infection or retained tissue. Broad-spectrum antibiotics, such as ampicillin, metronidazole, and gentamicin, are initiated if endometritis is suspected, continuing until clinical improvement. Dilatation and curettage (D&C) evacuates confirmed retained products of conception under ultrasound guidance.

Risk Factors

Antepartum and Intrapartum

Antepartum hemorrhage (APH) refers to bleeding from or into the genital tract after 20 weeks of gestation but before delivery, with key risk factors including maternal characteristics and pregnancy complications that predispose to conditions like placental abruption or previa. Advanced maternal age greater than 35 years is associated with an increased risk of placental abruption, with a pooled odds ratio (OR) of 1.42 (95% CI 1.22–1.65) in case-control studies. A history of prior APH significantly elevates recurrence risk, with pooled ORs of 4.04 (95% CI 1.27–12.87) for prior abruption in case-control analyses. Lifestyle and medical factors further contribute to antepartum risks. Smoking during pregnancy doubles the likelihood of placental abruption, evidenced by a pooled OR of 1.90 (95% CI 1.74–2.08) across case-control studies. Cocaine use is a recognized risk factor for abruption due to vasoconstrictive effects on placental vessels, though pooled quantitative data remain limited to individual reports. Hypertension and pre-eclampsia strongly correlate with APH, particularly abruption, with pooled ORs of 2.57 (95% CI 2.29–2.90) for hypertension and 2.45 (95% CI 2.09–2.86) for pre-eclampsia in case-control meta-analyses. Intrapartum hemorrhage arises during active labor and delivery, often linked to labor dynamics and interventions that impair hemostasis. Prolonged labor exceeding 12 hours in the active phase is associated with severe postpartum hemorrhage, necessitating heightened monitoring to mitigate bleeding escalation. Oxytocin overstimulation, typically from prolonged augmentation (≥4.5 hours), increases hemorrhage risk with an adjusted OR of 1.73 (95% CI 1.09–2.75), due to potential uterine fatigue and atony. Instrumental deliveries, such as vacuum or forceps, elevate bleeding risk through genital tract trauma. Chorioamnionitis during labor heightens postpartum hemorrhage odds via inflammation-induced myometrial dysfunction, consistently reported as a modifiable intrapartum risk. Certain factors span antepartum and intrapartum phases, amplifying overall bleeding vulnerability. Multiple gestation increases APH risk through uterine overdistension, contributing to abruption or previa complications. Polyhydramnios similarly predisposes to bleeding by exacerbating overdistension, raising placental abruption and subsequent atony risks. A history of placenta previa markedly heightens recurrent APH likelihood, often necessitating vigilant antepartum surveillance into labor. Meta-analyses underscore moderate risks from prior uterine surgery, with previous cesarean delivery linked to obstetric hemorrhage via placental invasion issues, showing pooled ORs of 1.70 (95% CI 1.53–1.89) for abruption in case-control studies and ranging 1.5–4 overall for hemorrhage events. These antepartum and intrapartum risks facilitate early identification, guiding preventive strategies like blood pressure control for hypertension or labor augmentation limits to curb bleeding incidence.

Postpartum

Postpartum hemorrhage (PPH) risk is influenced by several factors related to the delivery process and immediate postpartum period, with a 2025 systematic review and meta-analysis in The Lancet classifying associations as weak (OR >1–1.5), moderate (OR >1.5–2), or strong (OR >2) based on pooled data from over 100 studies. Delivery-related factors significantly elevate PPH risk, particularly cesarean delivery, which has a strong association (OR 5.18) due to increased surgical trauma and potential for . Macrosomia, defined as greater than 4 kg, also contributes, with moderate risk for weights of 4,000–4,499 g (OR 1.67) escalating to strong associations for higher weights (OR 2.08 for 4,500–4,999 g; OR 3.25 for ≥5,000 g). , often performed to facilitate , can lead to extended genital tract trauma and bleeding. A history of in prior deliveries further heightens vulnerability, forming part of validated risk models for PPH alongside prolonged third-stage labor. Maternal characteristics play a key role in postpartum bleeding susceptibility. Anemia, typically defined as hemoglobin <11 g/dL in pregnancy, carries a strong association with PPH (OR 2.36 overall; up to OR 4.27 for severe cases with Hb <9 g/dL), impairing oxygen delivery and hemostatic reserve during blood loss. Obesity, with BMI ≥30 kg/m², shows moderate risk (OR 1.51), linked to uterine atony from impaired myometrial contractility. Asian ethnicity is a weak but notable predictor (OR 1.15), potentially due to genetic or socioeconomic factors influencing clotting and access to care. Prior PPH exhibits the strongest recurrence risk among maternal factors (OR 3.17), underscoring the need for vigilant monitoring in subsequent deliveries. Coagulation disturbances in the postpartum phase amplify bleeding risks, with demonstrating moderate association (OR 1.54) through and potential progression to . Precursors to , such as multiparity or , indirectly heighten PPH likelihood by predisposing to acute during or shortly after delivery. Some overlap exists with antepartum risks, such as multiple (OR 5.86), which can compound postpartum vulnerabilities.

Diagnostic Approaches

Laboratory Tests

Laboratory tests play a crucial role in evaluating obstetrical bleeding by assessing blood loss, status, and potential underlying causes, guiding timely interventions such as transfusion. Routine evaluations begin with a (CBC) to measure and platelet levels, which help quantify from blood loss and detect that may exacerbate bleeding. Blood typing and are performed immediately to prepare for potential transfusions, while fibrinogen levels are assessed as a key early indicator of , with values below 2 g/L strongly predicting severe postpartum hemorrhage (PPH). Coagulation studies, including (PT), (PTT), international normalized ratio (INR), and , provide insights into the clotting cascade and fibrin degradation, identifying deficiencies or common in severe obstetrical bleeding. For real-time assessment, viscoelastic hemostatic assays such as (TEG) or rotational thromboelastometry (ROTEM) are increasingly utilized, offering rapid profiling of clot formation; for instance, a prolonged R-time on TEG indicates factor deficiency, enabling .00730-X/fulltext) Specialized tests address specific scenarios: the Kleihauer-Betke test quantifies fetal-maternal hemorrhage, which can contribute to maternal bleeding and guide Rh immunoglobulin administration in sensitized cases. (hCG) levels may be measured to rule out or retained products mimicking obstetrical bleeding, while arterial blood gas analysis detects acidosis in , signaling the need for aggressive resuscitation. Interpretation of results includes thresholds like fibrinogen below 2 g/L prompting administration and platelets under 50 × 10^9/L warranting to prevent progression of hemorrhage. These tests are particularly valuable in conditions like , where early detection can alter management.

Imaging and Monitoring

Imaging plays a crucial role in the and of obstetrical bleeding by identifying the source, extent, and associated complications without invasive procedures in most cases. Non-invasive techniques, particularly , are first-line due to their availability, safety, and real-time capabilities, allowing for rapid assessment of placental position, integrity, and fetal status during antepartum or intrapartum hemorrhage. Continuous monitoring complements by tracking fetal well-being and maternal , guiding timely interventions to prevent maternal and fetal morbidity. Transvaginal ultrasound is highly effective for diagnosing placenta previa, a common cause of , with reported sensitivity ranging from 83% to 100% depending on and technique. This approach provides detailed visualization of the lower uterine segment and cervical os, outperforming transabdominal ultrasound in accuracy, with overall diagnostic accuracy up to 92.8% in confirming placental location relative to the internal os. Color Doppler ultrasound enhances detection of vascular abnormalities, such as in vasa previa, where it identifies fetal vessels crossing the internal os with excellent performance, often using transvaginal color mapping and pulsed-wave Doppler for confirmation. For , Doppler can assess placental blood flow disruptions, though ultrasound primarily identifies retroplacental hematomas as hypoechoic areas. In the , transvaginal or transabdominal ultrasound evaluates for retained , a frequent contributor to secondary postpartum hemorrhage, with endometrial thickness exceeding 10 mm or heterogeneous echogenic masses indicating potential retained tissue. When findings are inconclusive, particularly in suspected complex or , () serves as a valuable adjunct, accurately depicting hematomas, placental separation, and uterine wall defects through variable signal intensities based on hemorrhage age. Computed tomography (CT) may reveal abruption as areas of decreased placental enhancement or high-attenuation retroplacental clots, but its use is limited in due to risks, reserved for rare cases where is unavailable or maternal trauma necessitates evaluation. These advanced modalities provide superior soft-tissue contrast compared to but are not routine due to accessibility and safety considerations. Fetal monitoring via non-stress test (NST) or (CTG) is essential during episodes of antepartum hemorrhage to evaluate fetal , detecting accelerations in fetal heart rate in response to movement or contractions, which indicate reassuring oxygenation. A reactive NST, defined by at least two accelerations within 20 minutes, correlates with low risk of fetal acidosis. In severe cases of postpartum hemorrhage (PPH), invasive monitoring offers continuous, beat-to-beat assessment of maternal and , facilitating rapid fluid and vasopressor administration when non-invasive methods are insufficient. For refractory PPH, is a critical advanced tool for planning , enabling identification of active bleeding sites through selective catheterization of pelvic arteries. This technique achieves high success rates, often over 90%, in controlling hemorrhage from atony or vascular malformations while preserving .

Differential Diagnosis

Non-Obstetric Causes

Non-obstetric causes of during stem from underlying genital tract pathologies unrelated to the itself, such as benign structural abnormalities, infections, or trauma. These conditions can present with spotting, , or more profuse hemorrhage, often mimicking obstetrical etiologies and requiring prompt evaluation to avoid unnecessary interventions like tocolysis or cesarean delivery. Unlike placental causes, which involve intrauterine sources, non-obstetric bleeding typically originates from visible lesions or below the cervical os, identifiable via speculum examination. Gynecologic causes predominate among non-obstetric etiologies and are often benign, exacerbated by pregnancy-related hormonal and vascular changes. Cervical polyps, finger-like projections of endocervical tissue, occur in approximately 2-5% of pregnancies and frequently cause intermittent spotting or postcoital bleeding due to their friable surface. Cervical ectropion (eversion of the endocervical columnar epithelium onto the ectocervix) is a physiologic response to elevated estrogen levels, affecting a substantial proportion of pregnant individuals and leading to contact bleeding from the exposed, vascular mucosa. Rarer vascular anomalies, such as hemangiomas of the cervix or vagina, represent benign malformations that enlarge during pregnancy and can result in significant hemorrhage from rupture or erosion. Similarly, rupture of a Bartholin's cyst—a blocked gland in the vulvovaginal area—may produce localized bleeding or hematoma, though this is uncommon antepartum. Infectious causes involve inflammation of the lower genital tract, often from sexually transmitted pathogens. , particularly due to or , manifests as with spotting or irregular , affecting untreated cases in up to 10% of pregnancies if screening is inadequate. , resulting from ascending bacterial infection of the , is less frequent in the antepartum period but can cause alongside and fever in non-obstetric contexts. Traumatic causes arise from mechanical disruption of the hypervascular pregnant genital tissues. Coital injury, including minor lacerations from intercourse, is a common trigger for bright red bleeding, amplified by the engorged vaginal and cervical vasculature. Retained foreign bodies, such as tampons or contraceptive devices, provoke , ulceration, and secondary leading to persistent hemorrhage. These non-obstetric factors are a notable cause of third-trimester episodes, underscoring the value of speculum examination for localization and differentiation from intrauterine sources.

Mimicking Conditions

Certain non-obstetric conditions can present with symptoms resembling obstetrical bleeding, such as apparent during or postpartum, potentially leading to diagnostic delays if not carefully evaluated. These mimicking conditions often involve bleeding from adjacent anatomical sites or local gynecologic pathologies unrelated to the pregnancy itself, and differentiation typically requires targeted , , and ancillary tests like speculum evaluation or . Hematuria from urinary tract disorders is a notable mimic, particularly in , where gross blood in the may be misinterpreted as by patients or initially by clinicians. For instance, tumors can cause life-threatening that is frequently mistaken for obstetric hemorrhage, as reported in cases of primary diagnosed during , where one presentation was initially attributed to vaginal sources despite the absence of genital tract . Urinary tract infections or urolithiasis can similarly produce bloody discharge that appears vaginal, especially if contamination occurs during voiding, emphasizing the need to rule out renal or origins through and of samples. Such misattribution has been documented in pregnant women aged 27 to 41 years, where initial symptoms of gross were overlooked as until confirmed the source. Gastrointestinal bleeding, particularly rectal, can also simulate vaginal hemorrhage, especially in the postpartum period when lochia is expected. Hemorrhoids, prevalent after vaginal delivery due to straining and venous congestion, may cause bright red blood per rectum that patients mistake for continued vaginal discharge, potentially confounding assessments of postpartum hemorrhage resolution. Anal fissures, another common postpartum issue from constipation or episiotomy-related trauma, similarly lead to bleeding mistaken for vaginal origin, as both conditions produce small amounts of fresh blood on wiping or undergarments. Broader gastrointestinal pathologies, such as or Behçet's syndrome, may rarely contribute to lower GI bleeding that mimics vaginal sources, though these are less common in the peripartum context. Local non-obstetric gynecologic conditions further complicate the picture by causing true unrelated to pregnancy dynamics. Cervical polyps, benign growths that become more friable due to elevated levels in , often bleed upon contact during intercourse or pelvic exams, presenting as spotting or hemorrhage that mimics threatened or implantation bleeding. or eversion, an inflammatory change exacerbated by hormonal shifts, can likewise produce contact bleeding without underlying obstetric pathology. Vaginal infections, such as or , or traumatic lesions from foreign bodies, may result in bloody discharge that simulates early bleeding. Rarely, extra-pelvic hemorrhages can mimic severe obstetrical events like . Splenic , for example, has been reported to present with acute abdominal pain and hemodynamic instability postpartum, initially suspected as ruptured due to overlapping shock and peritoneal signs, but confirmed via as a non-gynecologic source. These cases underscore the importance of comprehensive evaluation, including abdominal or CT when obstetrical causes are not evident, to avoid inappropriate interventions.

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