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Vacuum extraction

Vacuum extraction, also known as vacuum-assisted vaginal delivery, is an operative obstetric procedure in which a soft or rigid cup is applied to the fetal scalp via suction to facilitate the expulsion of the baby through the birth canal during the second stage of labor.^[1]^[2] This method is typically performed when maternal pushing efforts are insufficient or fetal well-being is at risk, allowing for a vaginal birth while avoiding the need for cesarean section in many cases.^[1] The procedure requires the cervix to be fully dilated, the fetal head to be engaged in the pelvis, and the fetal position to be known, ensuring safe application of traction synchronized with uterine contractions.^[2] Indications for vacuum extraction include maternal exhaustion from prolonged labor, a non-reassuring fetal heart rate tracing suggestive of distress, or medical conditions in the mother such as cardiac disease that contraindicate extended pushing.^[2] It is contraindicated in cases of fetal coagulopathies like hemophilia, skeletal disorders such as osteogenesis imperfecta, or gestations under 34 weeks due to heightened risks of injury.^[2] Soft-cup extractors are preferred over rigid metal cups for their lower incidence of fetal scalp injuries, though they may detach more frequently.^[2] While vacuum extraction can expedite delivery and reduce maternal fatigue, it carries potential complications for both mother and fetus. Maternal risks include vaginal or perineal lacerations, postpartum hemorrhage, and anal sphincter injury, which may contribute to long-term incontinence.^[1]^[2] For the neonate, common issues involve scalp bruising, swelling (caput succedaneum), or cephalohematoma, with rarer but serious concerns such as intracranial hemorrhage occurring in approximately 1 in 650 to 850 cases, retinal hemorrhages, or transient neurological deficits.^[1]^[2] Successful outcomes depend on the provider's expertise, as the procedure is operator-dependent and requires informed consent, emphasizing its role as a skilled intervention in modern obstetrics to balance maternal and fetal safety.^[1]^[2]

Fundamentals

Definition and principles

Vacuum extraction is an instrumental method of assisted vaginal delivery employed during the second stage of labor to facilitate the expulsion of the fetus by applying a vacuum cup to the fetal head, creating suction that adheres the device to the scalp and enables controlled traction.^[2] This technique shortens the duration of labor by augmenting the natural forces of delivery without requiring direct manipulation of the fetal body.^[3] The biophysical principles underlying vacuum extraction rely on the generation of negative pressure within a cup placed on the fetal scalp, typically building to 0.6–0.8 bar to achieve secure attachment and effective traction.^[4] ^[5] Available cup types include soft, flexible silicone models, which conform to the head but may detach more readily, and rigid variants made of plastic or metal, offering greater stability for challenging positions.^[6] Anterior cups, often bell-shaped, are designed for occiput anterior presentations, while posterior or flexible cups accommodate rotational needs in other fetal positions.^[7] Traction mechanics involve applying force along the pelvic curve, synchronized with maternal pushing and uterine contractions, to promote flexion, descent, and rotation of the fetal head in alignment with the birth canal's axis.^[2] ^[3] For safe application, anatomical prerequisites must be met, including full engagement of the fetal head in the maternal pelvis and a station of +2 cm or greater (i.e., +2, +3) relative to the ischial spines, ensuring the presenting part is sufficiently descended to avoid excessive force or malposition.^[2] Physiologically, vacuum extraction enhances the expulsive effects of uterine contractions and voluntary maternal efforts by providing supplemental traction, thereby accelerating delivery while preserving the integrity of the natural labor process.^[3] Originating as a 19th-century innovation by figures such as James Young Simpson, it represents an early mechanical advancement in obstetric assistance.^[8]

Indications and contraindications

Vacuum extraction is indicated in various clinical scenarios during the second stage of labor to facilitate vaginal delivery when maternal or fetal well-being is at risk or when progression is inadequate. Absolute indications include a prolonged second stage of labor, defined as exceeding 3 hours in nulliparous women with regional anesthesia or 2 hours without, and exceeding 2 hours in multiparous women with anesthesia or 1 hour without; maternal exhaustion; nonreassuring fetal status evidenced by Category III fetal heart rate tracings on continuous electronic monitoring; and the need to expedite delivery due to maternal conditions such as cardiovascular or neurologic disease, or active hemorrhage.^[2] These indications are typically assessed using a partogram to monitor labor progress and identify dystocia, alongside standard fetal monitoring protocols to detect abnormal heart rate patterns indicative of distress.^[9] Relative indications encompass situations where vacuum extraction may augment labor progress in cases of inadequate maternal pushing efforts or to shorten the second stage in select low-risk scenarios, provided prerequisites such as fetal head engagement are met.^[2]^[9] Absolute contraindications to vacuum extraction include fetal gestational age less than 34 weeks, cephalopelvic disproportion, unengaged fetal head (station less than 0), fetal scalp defects such as infections or recent electrode application, non-vertex presentations (e.g., face, brow, or breech), and maternal or fetal coagulopathy, including conditions like hemophilia or von Willebrand disease that increase bleeding risk.^[2]^[9] Additional absolute barriers are fetal demineralizing disorders such as osteogenesis imperfecta and primary fetal bleeding disorders.^[2] Relative contraindications involve suspected fetal macrosomia exceeding 4500 g, HIV-positive maternal status without viral suppression (HIV RNA ≥50 copies/mL near delivery), and scenarios where extraction time may be prolonged, potentially exacerbating fetal distress.^[9]^[10] In HIV cases with viral loads below 50 copies/mL and adherence to antiretroviral therapy, vacuum extraction may proceed per standard obstetric indications without heightened transmission risk.^[10]

Procedure

Preparation and equipment

Vacuum extraction requires specific equipment to ensure safe and effective application during operative vaginal delivery. The primary components include the vacuum cup, which attaches to the fetal head; a suction pump, either manual or electric, capable of generating negative pressure of 500 to 600 mmHg for optimal traction; a traction handle or chain connected to the cup for controlled pulling; and a release valve to rapidly discontinue suction if needed.^[3]^[11] Common vacuum cup types are the Malmstrom metal cup, a rigid reusable device for straightforward applications; the Kiwi silicone cup, a disposable soft option that conforms to the fetal scalp; and the OmniCup, a flexible disposable cup designed for rotational deliveries.^[12]^[13] Selection of the vacuum cup depends on fetal position, head station, and maternal anatomy to minimize slippage and trauma. For occiput anterior positions, an anterior or posterior cup such as the ProCup variant of the Kiwi system is preferred due to its alignment with the flexion point on the fetal scalp.^[14] Cup sizes typically range from 4 to 8 cm in diameter, with 5 cm options suited for smaller or molded heads and 6 cm for average cases, while material properties like silicone's pliability enhance grip on irregular surfaces without excessive pressure.^[15]^[13] All equipment must be sterile or single-use to prevent infection, and operators should verify functionality, including airtight seals, prior to use. Patient preparation begins with obtaining informed consent, where the obstetrician discusses the procedure's risks, benefits, and alternatives, such as cesarean section, ensuring the patient understands the potential for maternal perineal injury or fetal scalp trauma.^[2] The bladder is emptied via catheterization to avoid interference with cup placement and reduce uterine displacement during traction.^[2] The mother is positioned in the lithotomy stance with legs supported in stirrups for optimal perineal access, and regional analgesia, such as an epidural if already in place, is confirmed or administered to manage discomfort, though pudendal block may be used if needed. Perineal cleansing with antiseptic solution, typically chlorhexidine or povidone-iodine, establishes a sterile field, and the vulva is draped accordingly. A multidisciplinary team supports the procedure to enhance safety, particularly in high-risk scenarios. The obstetrician or trained operator performs the extraction, assisted by a midwife or nurse who monitors maternal vital signs, provides counterpressure, and handles equipment. In cases with fetal distress, a neonatologist or pediatric team is present for immediate neonatal resuscitation.^[2] Sterile field maintenance is maintained by all team members through gloved hands, draped instruments, and avoidance of unnecessary contact, with ongoing communication to coordinate actions. Facilities must be equipped for immediate escalation if vacuum extraction fails, which occurs in up to 10-15% of attempts. Backup options include forceps delivery by a proficient provider or rapid conversion to cesarean section, necessitating an operating room and anesthesia team on standby, along with neonatal intensive care capabilities for preterm or compromised infants.^[16]^[2]

Step-by-step technique

The step-by-step technique for vacuum extraction begins with an initial assessment to ensure suitability for the procedure. The operator confirms the fetal position, typically occipitoanterior, through vaginal examination or ultrasound if needed, verifies that the fetal head is at a station of +2 or greater (indicating engagement in the pelvis), and identifies the flexion point on the fetal scalp, which is the area over the posterior fontanelle along the midline sagittal suture, approximately 3 cm from the posterior fontanelle.^[7]^[17] This assessment ensures proper alignment and reduces the risk of malapplication. Next, the vacuum cup—typically a soft or rigid model selected based on fetal head size and position—is applied to the flexion point, ensuring no vaginal tissue is trapped between the cup and scalp. Suction is then activated gradually, building to the full vacuum level of 450–600 mm Hg over 1–2 minutes to allow for secure attachment without excessive trauma, followed by a gentle test pull during a uterine contraction to confirm adhesion and assess initial descent.^[17]^[18] Traction is coordinated with maternal pushing and contractions, applied at an initial angle of approximately 45 degrees to the pelvic axis, using a hand-over-hand technique to follow the natural curve of the birth canal—starting downward and curving upward as the head advances—while maintaining the vacuum extractor in line with the pelvic axis to avoid torque or rocking.^[17]^[19] Traction guidelines emphasize controlled application: limit to no more than three pulls per contraction, with a total of three sets of pulls across contractions, applying steady force (typically ≤11.5 kg) only while monitoring for progressive descent with each pull.^[18]^[19] During the procedure, continuous monitoring is essential, including fetal heart rate auscultation every 15–30 seconds to detect distress, maternal vital signs, and manual palpation with the non-dominant hand in the vagina to track head descent and detect cup detachment (pop-off), which indicates potential misalignment.^[7]^[17] Completion occurs once the fetal head crowns and the jaw is visible, at which point the vacuum is released, the cup is removed, and the operator assists with spontaneous delivery of the body and shoulders using standard maneuvers.^[7]^[18] The procedure is abandoned as a failure if there is no descent after three pulls, more than three cup detachments occur, or the total operative time exceeds 20 minutes without progress, prompting immediate preparation for alternative delivery methods such as cesarean section.^[7]^[19]

Risks and Outcomes

Maternal complications

Vacuum extraction is associated with several immediate maternal risks, primarily related to soft tissue trauma during delivery. Perineal lacerations occur in approximately 20.9% of cases, with third- and fourth-degree tears affecting 2.8% of vacuum-assisted deliveries.^[20] Vaginal hematomas may develop due to vessel injury, though specific incidence rates are not uniformly reported across studies. Postpartum hemorrhage is also elevated, occurring in 9.4% of vacuum extractions compared to 0.5% in spontaneous vaginal births, often resulting from perineal or cervical trauma.^[20] In the short term, maternal complications include urinary incontinence, particularly stress type, arising from pelvic floor strain and pudendal nerve compression during the procedure. Pain management is frequently required postpartum due to perineal trauma, and infections such as endometritis can arise if labor is prolonged, increasing exposure to pathogens. Overall, maternal trauma is reported in 13.2% of attempted vacuum deliveries.^[21] Long-term effects stem largely from anal sphincter injuries sustained during extraction, which can lead to fecal incontinence in up to 31% at 3-6 months postpartum, increasing to 69% at 20 years after delivery.^[21] Dyspareunia and pelvic organ prolapse are additional concerns, linked to chronic pelvic floor dysfunction following sphincter damage or levator ani trauma. Specific risk factors for these maternal complications include epidural analgesia, which can prolong the second stage and reduce pushing efficacy.^[22] Compared to forceps delivery, vacuum extraction generally results in lower rates of severe perineal lacerations.^[7] Recent 2024-2025 studies confirm consistent maternal complication rates, emphasizing the role of provider training in risk mitigation (as of November 2025).^[23]

Fetal and neonatal risks

Vacuum extraction poses several risks to the fetus and neonate, primarily involving scalp and neurological trauma due to the mechanical forces applied during delivery. Scalp trauma is among the most common complications, including caput succedaneum, which manifests as diffuse subcutaneous edema and typically resolves spontaneously within a few days without intervention.^[24] Cephalohematoma, a collection of blood under the periosteum, occurs in approximately 2 to 6 percent of cases and may lead to anemia or jaundice if extensive.^[3] Subgaleal hemorrhage, a potentially life-threatening accumulation of blood in the loose subgaleal space, has an incidence of approximately 0.5% in vacuum-assisted deliveries and can result in rapid hypovolemic shock due to significant blood volume loss, sometimes exceeding 200 mL in severe cases.^[25] Neurological injuries are less frequent but serious, often stemming from traction or pressure on the fetal head. Intracranial hemorrhage, including subdural or subarachnoid types, is reported in 0.5 to 1.7 percent of vacuum extractions and may cause seizures, altered consciousness, or long-term neurodevelopmental issues if undetected.^[26] Brachial plexus injury, resulting from excessive lateral traction on the neck and shoulders, affects nerve roots and leads to arm weakness or paralysis, with the risk increasing with duration of extraction.^[27] Retinal hemorrhage, caused by sudden pressure changes, occurs in up to 50 percent of neonates born via vacuum assistance and usually resolves without sequelae, though severe cases can impair vision.^[28] Adverse neonatal outcomes are associated with these injuries, including an elevated risk of neonatal intensive care unit admission, often for management of jaundice secondary to scalp bruising or birth asphyxia. Vacuum extraction is contraindicated in preterm fetuses under 34 weeks gestation, as the immature and fragile skull heightens susceptibility to hemorrhage and other traumas.^[2] To prevent and detect complications, post-delivery protocols emphasize close monitoring, including serial measurements of head circumference to identify expanding hematomas, assessment of hemoglobin levels for blood loss, and cranial ultrasound imaging if clinical signs such as lethargy or poor feeding suggest intracranial involvement.^[26] Technique errors, like misplacement of the vacuum cup, can exacerbate these risks by increasing traction forces.^[29] Recent 2024-2025 studies report consistent neonatal risk profiles with no major guideline changes (as of November 2025).^[23]

Comparisons and Evidence

Versus forceps delivery

Vacuum extraction and forceps delivery are both operative vaginal techniques used to assist in the second stage of labor, but they differ in procedural application, ease of use, and associated risks. Vacuum extraction typically requires less anesthesia than forceps delivery, as it is less uncomfortable for the mother during low or outlet procedures, often allowing for pudendal block or even no additional analgesia in some cases.^[17] In contrast, forceps application frequently necessitates regional anesthesia due to greater maternal discomfort.^[7] Vacuum extraction also has a gentler learning curve, making it more accessible for providers with varying levels of experience compared to the precise technique required for forceps.^[18] However, vacuum extraction has a higher failure rate, ranging from 10% to 20%, versus approximately 5% for forceps, often leading to sequential instrumentation or cesarean delivery. Forceps enable fetal head rotation, which is particularly useful in occiput posterior or transverse positions, a capability not reliably offered by vacuum.^[30] Conversely, forceps carry a higher risk of facial nerve palsy in the neonate due to direct pressure on the facial structures.^[31] Regarding maternal outcomes, vacuum extraction is associated with less severe perineal trauma, including third- and fourth-degree lacerations, with an odds ratio of approximately 0.6 compared to forceps. Postpartum hemorrhage rates are similar between the two methods. Forceps delivery, however, increases the risk of urinary incontinence and other pelvic floor issues due to greater tissue compression.^[32] For fetal outcomes, vacuum extraction is linked to more scalp injuries, such as cephalohematoma, from the suction cup application, while forceps are associated with fewer such injuries but higher rates of facial and eye traumas, including bruising or lacerations.^[7] Overall neonatal morbidity remains similar between the two, with a relative risk of about 1.1 for adverse events in vacuum deliveries.^[33] Selection criteria favor vacuum extraction for outlet procedures where the fetal head is low in the pelvis, whereas forceps are preferred for mid-cavity or rotational deliveries requiring head manipulation.^[18] The easier training for vacuum extraction makes it safer for less experienced providers, potentially reducing litigation risks associated with procedural errors.^[34]

Clinical efficacy and guidelines

Vacuum extraction demonstrates high clinical efficacy as an assisted vaginal delivery method, with overall success rates ranging from 85% to 95% in appropriately selected cases.^[35] Success is influenced by factors such as fetal head station, maternal parity, and operator experience; for instance, rates are lower in nulliparous women (approximately 80-87%) compared to multiparous women due to reduced pelvic compliance and stronger perineal resistance.^[36] In high-station cases (mid-pelvis), success drops to around 70-80%, emphasizing the need for careful patient selection to minimize failure and subsequent cesarean delivery.^[30] Evidence from systematic reviews supports vacuum extraction's role in improving labor outcomes, particularly in the second stage. A 2023 meta-analysis of 15 studies involving over 50,000 births found that vacuum extraction, compared to second-stage cesarean section, was associated with lower perinatal mortality (0.12% vs. 0.45%) and shorter decision-to-birth intervals, without increasing severe maternal morbidity in high-resource contexts.^[37] Regarding cesarean reduction versus expectant management, operative vaginal delivery including vacuum extraction has been shown to reduce the risk of cesarean in prolonged second-stage labor, though no significant perinatal mortality benefit was observed overall.^[38] The American College of Obstetricians and Gynecologists (ACOG) recommends operative vaginal delivery, including vacuum extraction, in cases of fetal distress when prerequisites are met, as a safe alternative to cesarean section (conditional recommendation, low-quality evidence per 2024 guideline).^[39] Current guidelines from ACOG and the Society of Obstetricians and Gynaecologists of Canada (SOGC) outline strict criteria for vacuum extraction to ensure safety and efficacy. Both recommend its use only when the fetal head is engaged (no more than 1/5 palpable abdominally), vertex presentation is confirmed, cervical dilation is complete, membranes are ruptured, and maternal pelvis is adequate. ACOG classifies procedures as outlet, low, or mid based on station, preferring vacuum for low-risk cases due to easier application and lower risk of severe perineal trauma compared to forceps (RR 0.53 for third/fourth-degree lacerations). SOGC similarly endorses vacuum as the instrument of first choice for most operative deliveries, with emphasis on operator proficiency through simulation-based training to reduce complications. Key prerequisites include informed consent, adequate analgesia, and immediate cesarean backup availability. The 2024 ACOG guideline conditionally recommends operative vaginal delivery before cesarean for second-stage arrest (low-quality evidence) and stresses simulation-based training. Outcome metrics highlight vacuum extraction's benefits in expediting delivery while noting trade-offs. It typically shortens the second stage of labor by 15-20 minutes on average, facilitating timely intervention for maternal exhaustion or fetal compromise.^[17] However, in certain cohorts such as nulliparous women or those with occiput posterior position, it may increase the need for additional interventions like episiotomy. Despite these advantages, usage has declined from approximately 10% of deliveries in the 1990s to 2-3% as of 2023, attributed to rising cesarean rates and concerns over neonatal cephalohematoma or retinal hemorrhage.^[41] Limitations include the paucity of randomized trials assessing long-term neonatal neurodevelopmental outcomes, underscoring the need for further high-quality research to refine indications.02583-2/fulltext)

Historical Context

Development and evolution

The origins of vacuum extraction trace back to 1848, when Scottish obstetrician James Young Simpson introduced the "air tractor," an early device consisting of a brass cup with a leather skirt designed to apply suction during labor. Intended as an alternative to forceps, Simpson's invention aimed to facilitate delivery through atraumatic traction but was quickly abandoned due to issues with maintaining vacuum seal and excessive fetal scalp trauma.^[42] Practical advancements emerged in the mid-20th century, with Swedish physician Tage Malmström developing the modern ventouse in 1953–1954, featuring a rigid metal cup with a posterior rim for stable traction on the fetal head. This design addressed prior limitations by allowing controlled negative pressure application, positioning vacuum extraction as a safer option to forceps by minimizing maternal perineal injury while relying on physiological maternal pushing efforts.^[42]^[43] Early adoption faced significant challenges in the 1950s and 1960s, as clinical trials revealed high failure rates and elevated risks of neonatal trauma from rigid metal cups, including cephalhematomas, scalp lacerations, and intracranial hemorrhages due to prolonged traction times up to 40 minutes or improper application before full cervical dilation. Despite these issues, vacuum extraction spread across Europe in the 1960s, driven by its perceived simplicity over forceps, while U.S. uptake lagged until the early 1980s following regulatory approval and accumulating safety data.^[42]^[17] A pivotal evolution occurred in the 1980s with the transition from metal to flexible silicone rubber cups, such as the Silc cup introduced in 1982, which reduced detachment risks and fetal cosmetic injuries compared to rigid designs. Key contributions included pressure limit studies establishing a maximum safe local pressure of 0.77 kg/cm² (approximately 0.77 bar) to prevent excessive traction force, and innovations like Aldo Vacca's Kiwi OmniCup design, which enhanced cup flexion for versatile fetal head positions. These developments reinforced vacuum extraction's rationale as an atraumatic alternative to forceps, prioritizing reduced maternal morbidity amid ongoing concerns over neonatal risks.^[44]^[4]^[45]

Key milestones and controversies

In the 1980s, the introduction of disposable vacuum extraction systems marked a significant advancement, addressing concerns over infection risks associated with reusable metal cups and promoting wider adoption in clinical practice.^[45] The U.S. Food and Drug Administration (FDA) regulated fetal vacuum extractors under 21 CFR Part 884, with early clearances for disposable components enabling sterile, single-use applications that improved hygiene and ease of use.^[46] During the 1990s, the American College of Obstetricians and Gynecologists (ACOG) issued key guidelines, including Committee Opinion No. 208 in 1998, which standardized training requirements for vacuum-assisted delivery to ensure competency among practitioners and reduce procedural errors.^[47] Technological innovations followed, such as the launch of the Kiwi OmniCup system, a hand-held vacuum extractor with a flexible stem designed for easier application and reduced maternal trauma compared to traditional setups. Flexion-optimized cups, like those in the OmniCup, were engineered to target the fetal flexion point, resulting in up to 30% fewer cup pop-offs and improved success rates in low- and mid-cavity deliveries.^[48] In the 2000s, meta-analyses solidified vacuum extraction's role as noninferior to forceps, with Johanson and Menon's 2000 Cochrane review analyzing randomized trials and finding significantly less severe perineal trauma and fewer regional analgesia requirements with vacuum, though with a slight increase in failed extractions.^[49] Controversies emerged prominently in the 1990s, including high-profile lawsuits related to subgaleal hemorrhages following failed extractions, which highlighted risks of excessive traction and prompted restrictions in some U.S. regions to mitigate medicolegal liabilities.^[50] Debates intensified over preterm applications, leading to ACOG's reinforcement of contraindications for gestations under 34 weeks based on studies showing elevated risks of intracranial hemorrhage and neonatal morbidity.^[17] Medicolegal fears contributed to a sharp decline in U.S. vacuum extraction rates, dropping approximately 50% from around 3.4% of deliveries in 2000 to 1.7% by 2019 and further to about 2.7% of all births as of 2023, as providers shifted toward cesarean sections amid rising litigation over neonatal injuries.^[38]^[51] Globally, usage patterns vary, with higher rates in low-resource settings for emergency deliveries due to its portability and lower skill barrier compared to forceps; the World Health Organization endorses vacuum extraction for use by skilled birth attendants in basic emergency obstetric care to reduce maternal and fetal risks in under-resourced areas.^[52] Current trends emphasize enhanced training through simulation programs like PROMPT, which integrate vacuum extraction modules to improve technical proficiency and team coordination, reducing error rates in operative vaginal births.^[53] Ongoing research explores AI-assisted positioning, using computational models and haptic feedback devices to optimize cup placement and traction force, potentially minimizing pop-offs and injuries in complex cases.^[54]

References

[1]
Assisted Vaginal Delivery - ACOG
A vacuum device is a suction cup with a handle attached. The suction cup is placed in the vagina and applied to the top of the fetus's head. Gentle, well- ...
[2]
Vacuum Extraction - StatPearls - NCBI Bookshelf - NIH
Traction is applied during contractions and maternal expulsive efforts. The suction is removed, and the cup is detached once the fetal head is crowning. The ...
[3]
Assisted Vaginal Delivery Using the Vacuum Extractor - AAFP
Sep 15, 2000 · Effective traction usually requires a pressure of at least −0.6 kg per cm2 (440 mm Hg). Although more negative pressures reduce the risk of cup ...
[4]
Simplifying the use of the Kiwi vacuum - Obstetrics and Gynecology
Jan 11, 2024 · When the baby is in the direct occipito-anterior (OA) position, negative pressure is built up immediately to −0.8 bar, and traction commenced.
[5]
Vacuum-assisted birth (Chapter 4) - ROBuST
... vacuum pressure of 60–80 kPa may be attained in one step.Reference Lim, Holm ... vacuum extraction and they should be offered to all obstetric trainees.<|control11|><|separator|>
[6]
Soft versus rigid vacuum extractor cups for assisted vaginal delivery
Soft cups are thought to have a poorer success rate than metal cups. However they are also thought to be less likely to be associated with scalp trauma.
[7]
Vacuum-Assisted Vaginal Delivery - AAFP
Oct 15, 2008 · Operative vaginal delivery using a vacuum device can cause less maternal trauma than forceps, but it can increase the risk of neonatal cephalohematoma and ...
[8]
Odon childbirth device: Car mechanic uncorks a revolution - BBC
Dec 3, 2013 · The earliest known vacuum extractor - the Air Tractor - was produced in 1838 by James Young Simpson in Edinburgh. But it only really became a ...
[9]
Operative vaginal delivery: Number 7 – July 2023 - PMC - NIH
Aug 18, 2023 · Vacuum extraction should be avoided before 32 weeks and caution should be exercised between 32 and 36 weeks, as the lower safe limit for ...
[10]
Special Populations: Intrapartum Care for People With HIV | NIH
Jun 12, 2025 · Based on these data, the Panel recommends that operative birth with forceps or a vacuum extractor should follow standard obstetric indications ...
[11]
[PDF] Vacuum Assisted Delivery Procedures - Medela
The obstetric vacuum extractor (also known as the ventou se) has been used for many years to assist women during parturition.
[12]
Kiwi Omnicup versus Malmstrom metal cup in vacuum assisted ...
Aug 5, 2025 · Kiwi Omnicup is an effective alternative to the currently available Malmstrom metal cup for vacuum assisted delivery with no increase in maternal or neonatal ...
[13]
Vacuum-Assisted Vaginal Delivery - PMC - NIH
Operative vaginal delivery refers to the application of either forceps or a vacuum device to assist the mother in effecting vaginal delivery of a fetus. The ...
[14]
[PDF] Instructions for Use - Medical Dynamics
The Kiwi system has been designed with two different style cups: The ProCup for outlet and low occiput anterior positions and the OmniCup for all positions ...Missing: criteria | Show results with:criteria
[15]
927 The impact of cup size on complications in vacuum-assisted ...
Conclusion. A larger Malmström cup size (60 mm) during VAD is associated with a decreased risk of neonatal birth trauma compared to a 50 mm diameter.
[16]
OB Guideline 18: Operative Vaginal Delivery - crico
Apr 8, 2022 · The vacuum extractor or forceps should only be used if all of the following conditions are met: The delivering clinician has clinical ...<|separator|>
[17]
Vacuum Extraction - Medscape Reference
Mar 18, 2022 · The ACOG practice bulletin discourages the use of vacuum extraction prior to 34 weeks of gestation; however, it does not establish a safe lower ...
[18]
Operative Vaginal Birth - ACOG
Use of obstetric forceps or vacuum extractor requires that an obstetrician or other obstetric care provider be familiar with the proper use of the instruments ...Missing: definition | Show results with:definition<|control11|><|separator|>
[19]
[PDF] Instrumental vaginal birth | ranzcog
Vacuum delivery should not be used for a face presentation, or at a gestation less than 34 weeks. The safety of vacuum extraction at between 34 and 36.0 weeks ...
[20]
Maternal and Neonatal Complications Resulting From Vacuum ... - NIH
May 11, 2021 · Operative vaginal delivery is a procedure that is performed using forceps or vacuum to extract an infant from the birth canal. It has many ...
[21]
Maternal and neonatal trauma during forceps and vacuum delivery ...
Oct 19, 2023 · One in four (25.3%) attempted forceps deliveries and one in eight (13.2%) attempted vacuum deliveries result in maternal (obstetric) trauma, most commonly ...
[22]
Risk factors for failed vacuum extraction and associated ... - PubMed
Risk factors for failed VE included occipito posterior position, mid-pelvic fetal station, high birth weight, short maternal stature, epidural analgesia, and ...
[23]
Vacuum Extraction Delivery: Procedure, Risks & Recovery
Vacuum extraction is one kind of assisted delivery procedure that can help get your baby through the birth canal when labor is stalled in the second stage.Missing: ACOG | Show results with:ACOG
[24]
Neonatal subgaleal hemorrhage: diagnosis and management - PMC
The prevalence at birth of moderate-to-severe subgaleal hemorrhages is approximately 1.5 per 10 000 births.
[25]
Cranial ultrasound screening in term and late preterm neonates ...
Vacuum-assisted delivery is associated with an increased incidence of neonatal morbidities, such as cephalohematoma, subgaleal and intracranial haemorrhage (ICH) ...
[26]
Obstetric Brachial Plexus Palsy Risk Factors by Vacuum Extraction
Conclusion: Shoulder dystocia in the setting of vacuum extraction is a prominent risk factor for OBPP in the newborn. The risk of OBPP increases with the time ...
[27]
Retinal Hemorrhage: Symptoms, Causes & Treatment
Around half of babies born via assisted delivery (like vacuum extraction and forceps delivery) have a retinal hemorrhage at birth. It's more common for ...
[28]
Precision of vacuum cup placement and its association ... - PubMed
Apr 5, 2023 · Results: The VE rate was 5.89% in the study period. There were 17(4.9%) failures among 345 attempted VEs. Thirty babies suffered from subgaleal ...
[29]
Operative Vaginal Birth: ACOG Practice Bulletin, Number 219
Vacuum extraction is believed to be easier to learn and may be used when asynclitism prevents proper forceps placement. Use of forceps provides a more secure ...
[30]
Facial nerve palsy due to birth trauma - MedlinePlus
Jun 13, 2024 · The proper use of forceps and improved childbirth methods have reduced the rate of facial nerve palsy.
[31]
Forceps or vacuum delivery - NHS
Urinary incontinence (leaking pee) is not unusual after childbirth. It's more common after a ventouse or forceps delivery. You should be offered physiotherapy ...
[32]
Forceps compared with vacuum: rates of neonatal and maternal ...
Conclusion: Vacuum-assisted vaginal birth is more often associated with shoulder dystocia and cephalohematoma. Forceps delivery is more often associated with ...Missing: scalp facial eye RR
[33]
Will vacuum delivery go the way of vaginal breech delivery?
Jul 10, 2019 · The history of using vacuum to aid vaginal delivery has been described in multiple texts, most notably by J.A. Chalmers in his book “ The ...<|control11|><|separator|>
[34]
Attempted and Successful Vacuum-Assisted Vaginal Delivery ... - NIH
Among the women who had a vacuum-assisted vaginal delivery attempt (N=1,652), the vast majority was successful, regardless of pre-pregnancy BMI (92.6–96.3%, ...
[35]
Angle of fetal head progression measured using transperineal ...
Jul 17, 2015 · AoP was measured in 235 women. Vacuum extractions failed in 30 (12.8%) women (29/184 nulliparous and 1/51 parous) and resulted in 28 vaginal ...
[36]
Vacuum extraction or caesarean section in the second stage of ...
Jan 20, 2023 · Risks of caesarean section extend into every subsequent pregnancy and include uterine rupture, placenta accreta spectrum, PPH and preterm birth.
[37]
[PDF] Operative Vaginal Birth - ACOG PRACTICE BULLETIN
Mar 26, 2020 · Use of obstetric forceps or vacuum extractor requires that an obstetrician or other obstetric care provider be familiar with the proper use ...
[38]
Lateral episiotomy or no episiotomy in vacuum assisted delivery in ...
Jun 17, 2024 · Lateral episiotomy can be recommended for nulliparous women requiring vacuum extraction to significantly reduce the risk of obstetric anal sphincter injury.
[39]
The evolution of the obstetric vacuum extractor - O&G Magazine
This article will outline the use and design of the obstetric vacuum extractor over the past 300 years.
[40]
Operative Vaginal Birth - CREOGS Over Coffee
Apr 26, 2020 · Some history. The first vacuum extractor was developed by James Young Simpson in 1849. Didn't really catch on until a Swedish doc named Tage ...
[41]
Cohort study of silastic obstetric vacuum cup deliveries - PubMed
A prospective study was undertaken to determine the safety of the Silastic vacuum extractor. Between November 1982 and July 1983, a cohort of 84 successful ...Missing: adoption Europe 1960s 1980s
[42]
Vacuum Extraction
Rigid-cup designs include the classic Malmstr闣 stainless steel vacuum cup and various modifications of this instrument, such as the Bird cup (see Picture 4).<|control11|><|separator|>
[43]
21 CFR Part 884 -- Obstetrical and Gynecological Devices - eCFR
Feb 12, 1990 · An approval under section 515 of the act consists of FDA's issuance ... A fetal vacuum extractor is a device used to facilitate delivery.
[44]
Comparison of Obstetric Efficacy and Safety of the Kiwi OmniCup ...
Purpose: The aim of the present study was to compare the safety and efficacy of the Kiwi OmniCup system with conventional vacuum delivery.Missing: selection | Show results with:selection
[45]
Vacuum extraction versus forceps for assisted vaginal delivery
Use of the vacuum extractor for assisted vaginal delivery when compared to forceps delivery was associated with significantly less maternal trauma.Missing: learning curve
[46]
Controversies in the use of the vacuum extractor - ScienceDirect
35. Benaron DA. Subgaleal Hematoma Causing Hypovolemic Shock During Delivery After Failed Vacuum Extraction: A Case Report. J Perinatol, 13 (1993), pp. 228 ...
[47]
Reintroducing vacuum extraction in primary health care facilities
Jun 19, 2018 · In rural Tanzania access to emergency obstetric and newborn care is threatened by poor roads and understaffed facilities among other ...
[48]
Assisted Vaginal Birth Module (AVB) - PROMPT Flex - Limbs & Things
This module can be used to perform both ventouse and forceps deliveries. Ventouse delivery – To aid in vacuum assisted vaginal delivery, the AVB module comes ...Missing: extraction | Show results with:extraction
[49]
Reliability and educational potential of a computational model of ...
Highlights · A computational simulation of realistic vacuum-assisted delivery is proposed. · A training dummy has been modelled for validation purposes.