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Lithotomy position

The lithotomy position is a body position in which the patient lies on their back with the hips and knees flexed and abducted, typically with the lower legs supported in stirrups elevated above the level of the , to provide unobstructed to the , , and lower . Named after the ancient surgical procedure of —the removal of or stones—the position derives its from the Greek words lithos (stone) and tomē (incision or cutting). The earliest detailed description of the procedure and its associated positioning appears in the works of the Roman encyclopedist from the 1st century AD, where the patient was placed in this posture to facilitate perineal during stone extraction. Over centuries, the position evolved from its origins in urological surgery to broader applications in and gynecology, particularly gaining prominence in Western medicine during the 18th century alongside the introduction of obstetric , which favored positioning for interventions. In contemporary medical practice, the lithotomy position is primarily indicated for procedures requiring exposure of the pelvic region, including gynecologic surgeries (such as hysterectomies), urologic interventions (like cystoscopies), colorectal operations, and perineal wound care. It is also routinely used for pelvic examinations, vaginal deliveries, and certain endoscopic procedures, as it allows simultaneous access to the and while enabling hemodynamic monitoring. Variations include low, standard, high, and exaggerated lithotomy, differentiated by the degree of leg elevation and hip flexion to suit specific surgical needs. Despite its utility, the lithotomy position carries notable physiological risks, particularly with prolonged duration exceeding two hours, including lower extremity due to reduced , common peroneal from at the fibular head, and hemodynamic shifts such as increased venous return that may elevate intracranial and . In , it has been associated with increased maternal pain, higher rates of , deliveries, perineal trauma, and abnormal fetal patterns compared to upright birthing positions, prompting recommendations for alternatives when feasible. To mitigate complications, guidelines emphasize sequential leg lowering during long procedures, adequate padding, and limiting extreme flexion.

Introduction and History

Definition

The lithotomy position is a standard positioning technique in medical and surgical settings, where the individual lies on their back with the buttocks positioned at or near the edge of the or . The lower extremities are flexed at the s and s, typically with hip flexion ranging from 80 to 100 degrees and knee flexion similarly adjusted, while the thighs are abducted 30 to 45 degrees from the midline. The lower legs are supported in padded stirrups, which elevate the feet and calves above the level of the hips to maintain the configuration and prevent strain. The term "lithotomy" derives from the Greek words lithos (meaning "stone") and tomē (meaning "a cutting" or "incision"), originally referring to the surgical procedure of removing bladder stones through perineal incisions. This etymology reflects the position's historical association with urological interventions, where the configuration allowed precise access to the bladder without abdominal entry. The primary purpose of the lithotomy position is to optimize surgical and diagnostic access to the , , and genitalia, facilitating procedures that require unobstructed visualization and instrumentation in these areas while minimizing interference from the patient's lower body.

Historical Origins

The lithotomy position traces its origins to ancient surgical practices aimed at removing stones, known as . In ancient , the , attributed to the physician around 600 BCE (though compiled later), provides one of the earliest detailed accounts of perineal lithotomy, including patient positioning with flexed hips and knees to facilitate access to the . This text describes the procedure as part of broader urological interventions, emphasizing preoperative preparation and postoperative care. In , the , dating to approximately 400 BCE, references as a specialized operation, with the prohibiting general physicians from performing it to avoid risks, reserving it for trained lithotomists. The procedure gained further documentation in through in the 1st century CE, who in his work De Medicina outlined the technique using the "apparatus minor"—a method involving perineal incision with the patient positioned to expose the surgical site, highlighting potential complications like fever and fistulas. During the and in , the position was refined for improved surgical access. In the 16th century, French surgeon Pierre Franco (1505–1578) pioneered the suprapubic approach to , using an abdominal incision for removal. Later, in the late , Jacques Beaulieu, known as (c. 1651–1717), developed the lateral technique, involving a lateral perineal incision with the patient in the standard with hips and knees flexed and abducted, to enhance perineal exposure and reduce operative trauma. These innovations standardized the lithotomy position for surgery across . The 19th and 20th centuries marked a transition as advancements in anesthesia and antisepsis expanded the position's application beyond urological stone removal to diverse pelvic procedures. Introduced in the mid-19th century, ether anesthesia and Joseph Lister's antiseptic methods in the 1860s enabled longer, more complex operations in the lithotomy position, shifting its use toward gynecology, obstetrics, and general surgery. By the mid-20th century, with the rise of minimally invasive techniques, the position's exclusivity to lithotomy diminished, though it remained integral to pelvic interventions.

Description and Variations

Standard Positioning Technique

The standard lithotomy position begins with the placed on the , typically at the edge to allow for perineal exposure, with arms secured at the sides using padded arm boards or tucked to prevent strain. Preparation involves administering if required for the procedure and adjusting the table to a slight Trendelenburg tilt as needed for optimal pelvic access, while ensuring all necessary equipment is readily available. are monitored throughout the setup to maintain patient stability. The positioning process requires at least two staff members to coordinate efforts and proceeds as follows: the patient's hips and knees are flexed simultaneously to approximately 90 degrees while the thighs are 30 to 45 degrees from the midline; the legs are then raised together and placed into padded stirrups positioned at hip level, with knees aligned parallel to the hips and feet secured to avoid slippage using straps. The foot section of the table is lowered or removed to expose the fully, ensuring the patient's remains neutral and the body is aligned without excessive torsion. This technique forms the basis for variations such as high or low positions, which adjust the degree of or . Key equipment includes adjustable stirrups, such as or knee crutch types, which support the legs from the to the heels, along with padded supports for the calves and heels to distribute pressure evenly. Foam padding (3-4 inches thick) is applied at contact points, and the must allow for height and angle adjustments. Patient considerations emphasize clear communication to ensure comfort during positioning, particularly for awake individuals, and coordinated movement to prevent discomfort from uneven leg elevation. The anesthesia provider oversees the process post-induction, confirming secure placement before proceeding.

Types of Lithotomy Positions

The lithotomy position encompasses several variations that differ primarily in the degree of hip flexion, knee flexion, leg abduction, and elevation to optimize access while minimizing physiological strain. These adaptations are tailored to procedural demands, with lower elevations generally reducing risks like nerve compression and venous pooling. Key variants include low, standard, high, and exaggerated lithotomy, along with modifications such as the Lloyd-Davies position and rare prone adaptations. In the low lithotomy position, the patient's legs are elevated minimally, with stirrups positioned below level to limit during brief procedures. The hips are flexed at 40 to 60 degrees, with thighs abducted minimally and knees flexed to maintain lower leg alignment parallel to the . This configuration provides adequate perineal access while decreasing the risk of compared to higher elevations. The standard lithotomy position involves greater elevation of the legs to mid-level, with stirrups at or near height for routine pelvic exposure. Hips are flexed 80 to 100 degrees, thighs abducted approximately 30 degrees from the midline, and knees flexed 70 to 90 degrees, positioning the lower legs parallel to the floor. This setup is widely used for its balance of access and stability, though it requires padding to mitigate pressure on the calves and peroneal nerves. High lithotomy elevates the legs sharply, placing stirrups above level to enhance access to upper pelvic regions. Hips are flexed 110 to 120 degrees, with increased abduction up to 45 degrees and knees hyperflexed, often requiring additional to prevent slippage. This variant heightens the risk of venous pooling and nerve injuries due to the extreme positioning, necessitating vigilant monitoring. The exaggerated, or steep, lithotomy position combines maximal leg elevation with the Trendelenburg tilt, where thighs are positioned parallel or nearly parallel to the floor for superior abdominal and pelvic visualization in complex interventions. Hips are flexed 130 to 150 degrees, with pronounced and flexion, amplifying hemodynamic shifts and the potential for lower extremity ischemia. It is particularly suited to procedures demanding extensive exposure, such as robotic-assisted surgeries. Other variants include the Lloyd-Davies position, a modification optimized for colorectal and pelvic surgeries requiring dual abdominal and perineal access. In this setup, hips are flexed around 60 degrees, knees at 45 degrees, and ankles at 90 degrees, with legs supported in stirrups and often incorporating a mild Trendelenburg tilt; it differs from standard by reducing overall flexion to facilitate supine abdominal work while providing perineal exposure. Prone lithotomy, though uncommon, involves the patient lying face-down with legs abducted 40 to 60 degrees and buttocks separated, used in select urologic or perianal cases for improved and site visibility without constraints.

Clinical Applications

Surgical Uses

The lithotomy position is widely employed in gynecological surgeries to facilitate access to the pelvic and perineal regions. For procedures such as and , the dorsal lithotomy position provides optimal exposure of the vaginal and perineal areas, allowing surgeons to perform vaginal or laparoscopic approaches effectively. Standard or high lithotomy configurations are preferred to accommodate instruments and manipulators while maintaining patient stability. In urological surgery, the lithotomy position supports procedures requiring urethral and bladder access, including , , and removal. High lithotomy is particularly suited for transurethral resections of the prostate (TURP), where leg elevation enhances visualization and maneuverability of endoscopic tools. Cystoscopy and stone fragmentation or extraction, both historically and in contemporary minimally invasive techniques, routinely utilize the standard lithotomy setup to align the urinary tract for precise intervention. Colorectal surgeries benefit from lithotomy variants for improved perineal and rectal exposure. Low anterior resection often employs the Lloyd-Davies modification, which combines with moderate Trendelenburg tilt to enable simultaneous abdominal and perineal access during . Hemorrhoidectomy procedures may use the standard position to allow direct and excision of hemorrhoidal tissue, though prone alternatives exist for select cases. Vascular and orthopedic interventions in the lower also incorporate lithotomy positioning. Key advantages of the lithotomy position in these pelvic surgeries include enhanced surgical through elevated perineal access and potential reduction in intraoperative blood loss via gravitational effects in Trendelenburg combinations, which pool blood away from the operative field. Procedures typically last 1-4 hours, balancing exposure benefits with positioning constraints.

Obstetric Uses

The lithotomy position has traditionally been applied during the second stage of labor for , where the woman lies with her legs elevated and abducted in stirrups to facilitate pushing and provide perineal access for interventions such as . This positioning supports leg elevation to optimize gravitational assistance in some cases and allows for straightforward of fetal . In standard obstetric practice, the feet are secured in stirrups to maintain the legs' flexed and separated state, reducing the need for manual support during active pushing. Historically, the lithotomy position became prevalent in hospital-based births from the late 18th century onward, coinciding with the introduction of forceps by male practitioners who favored it for operative access; it remained the dominant position in Western obstetrics through the late 20th century, with a majority of U.S. vaginal births occurring in supine or lithotomy variants as late as the early 2010s. Its widespread adoption was driven by institutional convenience, including ease of fetal monitoring and provider intervention, though it restricted maternal mobility compared to pre-hospitalization upright traditions. In contemporary , the lithotomy position is primarily reserved for scenarios where mobility is limited, such as with epidural or during cesarean sections under regional , where it provides optimal pelvic access; it is often adapted into a semi-lithotomy form using adjustable birthing beds that elevate the head and flex the knees partially. For specific interventions like - or vacuum-assisted deliveries, the position is standard due to its facilitation of instrument application and perineal visualization, with the woman placed in dorsal to ensure the is engaged and accessible. Perineal repairs following delivery or are also routinely performed in this position for clear exposure. As of 2025, its use continues to decline in uncomplicated labors, with ongoing reinforcing alternatives. The use of the lithotomy position has declined in uncomplicated labors due to accumulating evidence of its association with prolonged second-stage duration, increased instrumental delivery rates (up to 42% versus 20% in alternatives), higher needs, and greater perineal trauma compared to upright or lateral positions. The World Health Organization's 2018 intrapartum care guidelines recommend discouraging or lithotomy positions during labor and birth, favoring upright alternatives to promote physiological progression and positive experiences in women without epidural ; these recommendations remain current as of 2025. This shift emphasizes patient autonomy in positioning to mitigate risks like reduced diameter and enhanced pain from gravitational effects on the vena cava.

Diagnostic Examinations

The lithotomy position is commonly employed for pelvic examinations, enabling optimal access to the pelvic organs for procedures such as speculum insertion to collect samples for Pap smears and bimanual palpation to assess the and ovaries. This positioning, typically the standard dorsal lithotomy with feet in stirrups, enhances examiner visibility and patient comfort during these non-invasive assessments by aligning the for straightforward instrumentation. Several diagnostic procedures utilize the lithotomy position to facilitate gynecological evaluations, including for detailed cervical visualization, endometrial biopsy for uterine lining sampling, and (IUD) insertion for contraceptive placement. A low lithotomy variant, with legs positioned lower relative to the hips, is often preferred for these to reduce patient discomfort while maintaining adequate access. In urological diagnostics, the lithotomy position supports and urethroscopy by providing clear visualization of the and in both male and female . A higher lithotomy configuration, elevating the legs more acutely, may be used to improve alignment for endoscopic passage through the . The lithotomy position is integral to routine screening, such as annual gynecologic check-ups and (STI) testing, where it allows for comprehensive external and internal pelvic assessments. This setup also accommodates the presence of a chaperone to uphold modesty and during the examination. These diagnostic examinations generally last 5 to and are conducted in outpatient settings, with a strong emphasis on obtaining and ensuring patient privacy through draping and minimal exposure.

Risks and Management

Potential Complications

The lithotomy position, involving flexion, flexion, and leg , can lead to various physiological complications due to prolonged , , and impaired circulation in the lower and . These risks are exacerbated in procedures lasting more than four hours or when combined with Trendelenburg tilt, affecting nerves, muscles, blood flow, and other systems. Nerve injuries are among the most reported complications, primarily involving compression or stretch of the common peroneal, femoral, and sciatic nerves from stirrup pressure, excessive hip flexion, or prolonged positioning. The common peroneal nerve is particularly vulnerable at the fibular head due to direct , while femoral and sciatic nerves may suffer from during hip abduction beyond 45 degrees or knee hyperflexion. Symptoms typically include numbness, , weakness, or , with incidence rates ranging from 0.1% to 2% in surgeries exceeding four hours, though higher rates (up to 15.8%) have been noted in specific cohorts undergoing extended procedures. Well-leg compartment syndrome (WLCS) arises from ischemia in the calf or thigh compartments due to elevated leg positioning that hinders venous return and increases intracompartmental pressure, particularly in the non-operative leg. Risk factors include , , and procedure durations over five hours, leading to post-operative pain, swelling, , and potentially irreversible muscle damage if untreated. The incidence is estimated at 1 in 3,500 for general cases, rising to 1 in 500 for lengthy urologic surgeries like . Circulatory issues stem from venous pooling in the lower extremities caused by leg elevation and flexion, which reduces venous blood flow and promotes stasis, thereby increasing the risk of deep vein thrombosis (DVT). In Trendelenburg-modified lithotomy, reduced cardiac output may further compound hemodynamic instability, especially in patients with cardiovascular comorbidities. Studies indicate a higher DVT incidence in lithotomy compared to alternative positions, with prolonged exposure altering lower extremity hemodynamics and elevating venous thromboembolism risk. Musculoskeletal strains occur from sustained hyperflexion and , which flatten the lumbar and impose on the hips and , potentially causing lower or, in rare cases, if legs are not raised or lowered symmetrically. Pressure ulcers or deep tissue injuries on the heels, , or calves can develop from inadequate padding and immobility, with reported incidences around 0.14% in surgeries. In obese patients, the position may cause respiratory compromise through abdominal compression that restricts and reduces , leading to or , particularly when combined with steep Trendelenburg. Excessive also heightens the risk of genital or perineal , including injury or soft tissue strain, manifesting as perineal or altered in the genitals and .

Prevention Strategies

To minimize risks associated with the lithotomy position, teams should implement evidence-based positioning techniques that prioritize and anatomical alignment. Padded stirrups, such as boot-style holders that support the calf and foot to distribute pressure evenly, are recommended over ankle straps or stirrups, which can compress nerves and vessels; knees should be flexed to less than 90 degrees to avoid excessive hip flexion or , with legs raised and lowered simultaneously by at least two personnel to prevent torsion. Sequential compression devices applied to the lower extremities provide prophylaxis against by promoting venous return, particularly in prolonged cases. Monitoring protocols are essential to detect early of during procedures. Intraoperative assessments should occur every 30 to 60 minutes, including checks of pedal pulses, lower extremity sensation, color, and , with documentation of time in the position; for cases exceeding 2 hours, legs should be lowered to a neutral, heart-level position for 10 to 15 minutes, followed by gentle massage to restore circulation. Procedures longer than 4 hours are considered prolonged and require heightened vigilance, potentially including neurophysiological for . Postoperatively, surveillance for 24 to 48 hours should evaluate for delayed complications such as deficits or swelling. Patient selection plays a critical role in risk mitigation. Preoperative screening for comorbidities, such as , , or joint issues in the hips or knees, helps identify individuals who may require modifications or contraindicate the ; adequate and avoidance of vasodilators are advised to support circulation. Equipment and team practices further enhance safety. Ergonomic operating tables with adjustable heights facilitate proper alignment, while multidisciplinary checklists— involving nurses, surgeons, and anesthesiologists—ensure all contact points (e.g., , knees, heels) are padded with pressure-redistributing materials like or to prevent ischemia. Adherence to the Association of Registered Nurses (AORN) Guideline for Positioning the Patient (updated 2022, with 2023 pocket card reinforcements) has been associated with reduced injury rates through standardized protocols, including preoperative risk assessments and intraoperative repositioning.