Fact-checked by Grok 2 weeks ago

Hip dislocation

Hip dislocation occurs when the ball-shaped head of the femur is forced out of its socket in the acetabulum of the pelvis, typically as a result of high-energy trauma that overwhelms the stabilizing structures of the hip joint, including the labrum, capsule, ligaments, and muscles.^[1]^[2] This injury is classified by direction, with posterior dislocations accounting for approximately 90% of cases and anterior dislocations comprising the remaining 10%.^[1]^[3] Posterior dislocations often result from axial loading on a flexed and adducted hip, such as in motor vehicle collisions where the knee strikes the dashboard, while anterior dislocations arise from forceful abduction and external rotation, commonly in similar high-impact scenarios or falls.^[2]^[4] Up to 95% of motor vehicle-related hip dislocations are associated with other injuries, including acetabular fractures (in approximately 70% of traumatic cases), requiring comprehensive evaluation.^[2]^[5] Symptoms of hip dislocation include severe pain in the hip and groin, inability to bear weight, and characteristic limb deformity: in posterior dislocations, the leg appears shortened, adducted, flexed, and internally rotated, whereas anterior dislocations may present with the leg abducted, extended, and externally rotated, sometimes with the femoral head palpable in the femoral triangle or below the obturator foramen.^[1]^[3] Neurological deficits, such as sciatic nerve injury leading to foot drop or numbness, affect about 10% of posterior dislocation cases.^[1]^[2] Diagnosis is confirmed through physical examination and imaging, starting with anteroposterior and cross-table lateral X-rays, followed by computed tomography (CT) to assess for fractures, loose bodies, or residual displacement.^[3]^[4] Treatment is a medical emergency to minimize complications, prioritizing closed reduction under sedation or anesthesia using maneuvers like Allis or Bigelow, ideally within 6 hours of injury to reduce the risk of avascular necrosis (osteonecrosis) of the femoral head, which occurs in 2-10% of cases and increases with delays beyond 6-12 hours.^[1]^[2] If closed reduction fails or fractures are present, open reduction and internal fixation are necessary, often followed by immobilization and protected weight-bearing for 2-3 months.^[3]^[4] Long-term complications include post-traumatic arthritis, recurrent dislocation, and heterotopic ossification, with outcomes improving through early intervention and multidisciplinary care.^[1]^[2]

Anatomy and Stability

Bony and Ligamentous Structures

The hip joint is a multiaxial ball-and-socket synovial articulation formed between the head of the femur and the acetabulum of the pelvis, providing a wide range of motion while supporting substantial body weight.^[6] The femoral head is a smooth, spherical structure at the proximal end of the femur, covered by hyaline articular cartilage except at the fovea capitis, with an average diameter of 40-50 mm in adults.^[7] The acetabulum, a deep cup-shaped cavity formed by the confluence of the ilium, ischium, and pubis, accommodates the femoral head and has an average depth of approximately 22 mm in adults, enhanced by the fibrocartilaginous acetabular labrum.^[8] The labrum is a triangular wedge of fibrocartilage attached to the acetabular rim, encircling the femoral head and deepening the socket by up to 21% while distributing compressive forces across the joint.^[9] The primary ligamentous stabilizers of the hip are the three extracapsular ligaments—iliofemoral, pubofemoral, and ischiofemoral—which arise as thickenings of the joint capsule and reinforce its integrity against dislocation.^[7] The iliofemoral ligament, the strongest of the trio, originates from the anterior inferior iliac spine and acetabular margin, inserting onto the intertrochanteric line of the femur, and primarily resists hip hyperextension.^[6] The pubofemoral ligament extends from the superior pubic ramus and iliopectineal eminence to the intertrochanteric line and lesser trochanter, limiting excessive abduction and external rotation.^[10] The ischiofemoral ligament arises from the ischial portion of the acetabular rim, passing posteriorly to insert on the greater trochanter and intertrochanteric crest, where it helps constrain internal rotation and adduction.^[11] The hip joint capsule is a fibrous sheath that envelops the joint, attaching proximally to the acetabular rim and the transverse acetabular ligament, and distally to the intertrochanteric line anteriorly and about 1 cm proximal to the intertrochanteric crest posteriorly.^[6] It thickens anteriorly into the iliofemoral ligament, inferiorly into the pubofemoral ligament, and posteriorly into the ischiofemoral ligament, with the zona orbicularis forming a circumferential band of circular fibers around the femoral neck that acts as an aperture to maintain femoral head containment.^[12] These bony and ligamentous elements collectively provide the hip's inherent static stability, resisting subluxation through their geometric and tensile properties.^[10]

Biomechanical Stability

The hip joint exhibits inherent biomechanical stability primarily due to its ball-and-socket configuration, where the deep acetabular socket envelops approximately 40% of the femoral head across various positions of motion, providing substantial containment and resistance to subluxation.^[7] This osseous architecture creates a favorable leverage for load distribution, minimizing shear forces on the joint during weight-bearing activities. In addition to the bony structures, the acetabular labrum marginally increases the effective depth of the socket, further augmenting containment without compromising mobility.^[13] A critical dynamic stabilizer is the negative intra-articular pressure, which generates a vacuum seal effect that maintains joint cohesion and resists distractive forces, contributing significantly to the total restraining force in neutral positions.^[14] This suction mechanism, facilitated by the intact labral seal, enhances overall joint stability by promoting uniform synovial fluid distribution and reducing the risk of femoral head migration under physiological loads.^[15] Surrounding musculature provides active stabilization through balanced force vectors that counteract potential dislocating moments. The gluteal muscles, particularly the gluteus medius and maximus, generate compressive forces across the joint during gait and single-leg stance, comprising about 33% of the hip's muscular cross-sectional area and essential for pelvic stability and abduction control.^[16] Similarly, the iliopsoas muscle contributes anterior stability by flexing the hip and countering posterior shear, with its activation patterns optimizing pelvic alignment and joint centering during dynamic movements.^[17] Biomechanically, the femoral neck-shaft angle, averaging approximately 127 degrees (normal range 125-135 degrees) in adults, influences stability by determining the moment arms of abductor muscles and the overall leverage ratio for joint loading.^[18] Deviations from this angle alter force transmission, potentially increasing joint reactive forces and reducing the efficiency of muscular stabilization, as evidenced by musculoskeletal modeling showing variations in hip contact pressures with angular changes.^[19]

Classification and Types

Posterior Dislocation

Posterior dislocation represents the predominant form of traumatic hip dislocation, comprising 90-95% of all cases.^[20]^[2]^[1] This high prevalence stems from common mechanisms such as dashboard injuries in motor vehicle accidents, where axial loading on a flexed and adducted hip forces the femoral head out of the acetabulum posteriorly.^[2]^[20] Anatomically, the femoral head displaces posterosuperiorly relative to the acetabulum, typically positioning superior and slightly lateral to the socket while remaining posterior to it.^[21] This displacement frequently involves an associated fracture of the posterior acetabular rim, which occurs in 50-70% of instances and contributes to joint instability.^[5] Posterior wall fractures predominate among these, often resulting from the femoral head impacting the rim during the traumatic event.^[2] Posterior dislocations are classified using the Thompson-Epstein system based on associated bony injuries: type I (simple dislocation with or without minor wall fragment), type II (large posterior wall fracture), type III (comminuted wall fracture), type IV (acetabular floor fracture), and type V (femoral head fracture).^[2]^[22] Associated injuries are notable, with sciatic nerve damage occurring in 10-20% of cases, primarily affecting the peroneal division due to stretching or compression during dislocation.^[23]^[20] This may manifest briefly as leg shortening or altered gait, though detailed symptoms are addressed elsewhere.^[2]

Anterior Dislocation

Anterior hip dislocation represents a less common variant, accounting for approximately 5-10% of all traumatic hip dislocations, compared to the predominant posterior type.^[24] This injury typically arises from hyperextension combined with abduction and external rotation of the hip, often in high-energy scenarios such as motor vehicle accidents or falls from height.^[4] In anterior dislocation, the femoral head displaces anteroinferiorly from the acetabulum, potentially positioning it adjacent to the obturator foramen or pubic region.^[25] The condition is subclassified into superior (pubic or iliac) and inferior (obturator) types, with the inferior subtype comprising about 70% of cases.^[24] The superior subtype occurs with hip extension and external rotation, directing the femoral head superiorly toward the pubic or iliac area, whereas the inferior subtype involves flexion with abduction and external rotation, driving the head inferiorly through the obturator foramen.^[4] Associated injuries in anterior hip dislocation include compression of the femoral neurovascular bundle, which can lead to thrombosis in the femoral vein due to direct pressure from the displaced femoral head.^[26] Additionally, the mechanism often results in significant capsular tears, conferring a higher risk of recurrent instability compared to other dislocation types, particularly when accompanied by acetabular or femoral head fractures.^[24]

Etiology and Mechanisms

Traumatic Mechanisms

Traumatic hip dislocations typically result from high-energy impacts that overcome the joint's inherent stability, most commonly occurring in motor vehicle accidents, falls from height, and high-impact sports injuries.^[27] In motor vehicle collisions, a classic mechanism involves the dashboard striking the flexed knee, transmitting an axial load through the femur to a flexed and adducted hip, often leading to posterior dislocation.^[28] Falls from significant heights produce similar axial loading forces on the lower extremity, while sports-related incidents, such as those in football or rugby, involve direct blows or twisting forces during contact.^[29] The biomechanical forces driving these dislocations depend on the hip's position at the time of injury. Posterior dislocations, which account for approximately 85-90% of cases, arise from a combination of hip flexion, adduction, and internal rotation, which directs the femoral head posteriorly through a weakened or torn posterior capsule.^[2] In contrast, anterior dislocations, comprising about 10% of traumatic cases, result from hyperextension combined with external rotation and often abduction, propelling the femoral head anteriorly.^[30] These positional vulnerabilities exploit the acetabulum's limited coverage in extreme ranges of motion. Dislocating the hip requires substantial forces, such as axial loads exceeding 4000 N in high-energy trauma scenarios like dashboard impacts, far exceeding routine joint loads and necessitating high-energy trauma to disrupt the strong ligamentous and capsular restraints.^[31] Such events frequently involve concomitant injuries, with pelvic fractures—particularly acetabular fractures—occurring in up to 70% of cases due to the transmitted forces fracturing the bony socket.^[5]

Non-Traumatic Causes

Non-traumatic hip dislocations are uncommon and typically arise from underlying congenital, pathologic, or iatrogenic conditions that compromise joint stability rather than acute injury.^[3] One primary cause is developmental dysplasia of the hip (DDH), a spectrum of abnormalities in infant hip development characterized by a shallow acetabulum that fails to adequately cover the femoral head, leading to instability, subluxation, or frank dislocation.^[32] This condition often manifests in the neonatal period due to in utero positioning factors, such as breech presentation, or genetic predispositions, resulting in progressive femoral head displacement if untreated.^[32] The prevalence of DDH is approximately 1 to 2 per 1,000 live births, with about 1 per 1,000 infants exhibiting dislocation at birth.^[32] Pathologic conditions, particularly neuromuscular disorders like cerebral palsy, contribute to hip dislocation through chronic muscle imbalance, spasticity, and impaired motor control that erode capsular integrity over time.^[33] In children with cerebral palsy who cannot walk independently by age 5, subluxation or dislocation occurs in 30% to 60% of cases, often bilaterally and worsening with disease severity.^[33] Similarly, connective tissue disorders such as Ehlers-Danlos syndrome (EDS) cause ligamentous laxity and joint hypermobility, predisposing to recurrent or congenital dislocations; the arthrochalasia type of EDS frequently presents with bilateral hip dislocations at birth due to defective collagen synthesis.^[34] Iatrogenic dislocations commonly occur following total hip arthroplasty, with an incidence of 1% to 2% in primary procedures, often resulting from surgical malpositioning of components, such as excessive anteversion of the acetabular cup or inadequate soft tissue tension.^[35] These events typically manifest in the early postoperative period due to patient positioning errors or component instability rather than external force.^[35] Septic or inflammatory processes represent rare non-traumatic etiologies, where joint infections or erosive arthropathies like rheumatoid arthritis weaken the hip capsule and supporting structures, potentially leading to pathologic dislocation.^[36] In pediatric cases, acute septic arthritis can cause secondary dislocation through purulent effusion and capsular destruction, though this is infrequent and often associated with delayed diagnosis in vulnerable populations.^[36]

Clinical Features

General Signs and Symptoms

Hip dislocation typically presents with severe acute pain in the affected hip or groin area, often described as immediate and intense following a traumatic event, which severely limits any movement of the hip joint.^[2] This pain is a hallmark symptom that arises from the disruption of the joint capsule, ligaments, and surrounding soft tissues.^[37] A characteristic deformity is often visible, including apparent shortening of the affected leg in posterior dislocations or apparent lengthening in anterior dislocations due to the femoral head's displacement from the acetabulum, along with rotation of the leg—internal rotation for posterior dislocations and external rotation for anterior ones.^[2]^[37] Functional impairment is profound, with patients unable to bear weight on the affected leg and exhibiting markedly limited range of motion in the hip, often rendering ambulation impossible.^[22]^[38] In cases stemming from high-energy trauma, systemic signs such as shock or evidence of multiple associated injuries may accompany the dislocation, necessitating comprehensive trauma evaluation.^[20]

Type-Specific Presentations

Posterior hip dislocations, which account for approximately 90% of cases, typically present with the affected leg held in a characteristic position of flexion, adduction, and internal rotation, with the foot rotated inward toward the midline of the body.^[20]^[1] On physical examination, the femoral head may be palpable in the gluteal region posteriorly, indicating displacement from the acetabulum, and this finding can be accentuated by performing a log roll maneuver, where the supine patient's leg is gently rolled to assess for posterior prominence or irregularity.^[3]^[39] Neurovascular deficits occur in 10-20% of posterior dislocations, most commonly involving the sciatic nerve due to stretch or compression, leading to symptoms such as foot drop, weakness in dorsiflexion or plantar flexion, diminished ankle reflexes, and sensory loss in the posterior leg and foot.^[20]^[40] In contrast, anterior hip dislocations, comprising about 10% of cases, manifest with the leg positioned in extension or slight flexion, marked abduction, and external rotation, often with the knee and foot turned outward away from the midline, and the affected leg may appear lengthened.^[20]^[4] Palpation may reveal a mass or prominence in the groin area due to anterior displacement of the femoral head, particularly in obturator or inferior subtypes where it protrudes into the femoral triangle or obturator foramen.^[41]^[42] Neurovascular complications are less frequent but can include femoral nerve involvement, resulting in sensory deficits over the anteromedial thigh, leg, or foot, quadriceps weakness, and reduced knee reflexes; vascular injuries to the femoral artery or vein are rare but warrant immediate assessment for hematoma or absent pulses.^[4]^[40] The log roll test remains useful here to evaluate overall hip stability and detect any asymmetric mobility or pain provocation specific to the anterior displacement.^[39]

Diagnosis

Clinical Assessment

Clinical assessment of hip dislocation begins with a thorough history to identify the mechanism of injury and immediate post-event limb position, which are critical for suspecting the diagnosis. High-energy trauma, such as motor vehicle accidents involving dashboard impacts, is the most common cause, typically resulting in posterior dislocation when axial force is applied to a flexed, adducted, and internally rotated hip. Anterior dislocations may occur from hyperextension or abduction mechanisms, like falls onto an abducted leg. Patients often report the leg assuming a characteristic position immediately after injury: flexed, adducted, and internally rotated for posterior types, or abducted, extended, and externally rotated for anterior types. Severe pain in the hip and groin, along with inability to bear weight, is a hallmark symptom.^[43]^[20]^[3] Physical examination requires careful inspection and palpation while avoiding axial traction to prevent further damage to neurovascular structures. Inspection reveals obvious deformity, such as limb shortening, apparent internal rotation, or adduction in posterior dislocations, with the affected leg often appearing shorter and held in a guarded position. Palpation should gently assess for the femoral head's position—posteriorly in the gluteal region for posterior dislocations or anteriorly in the femoral triangle for anterior ones—while checking skin integrity and soft-tissue swelling. Neurovascular evaluation is essential, including assessment of distal pulses (femoral and dorsalis pedis), sensation in dermatomes (particularly L4-S1 for sciatic nerve involvement), and motor strength; sciatic nerve injury occurs in 10-20% of cases, more commonly with posterior dislocations.^[43]^[20]^[3] Key diagnostic maneuvers include testing for inability to perform a straight-leg raise, which elicits severe pain and instability due to the disrupted joint. These findings, combined with the history, heighten suspicion before imaging. Hip dislocation is an orthopedic emergency requiring urgent reduction, ideally within 6 hours, to minimize the risk of avascular necrosis of the femoral head, which arises from disrupted blood supply and affects 2-10% of cases if addressed promptly but rises to 60% with delays beyond 12 hours.^[43]^[20]^[44]

Imaging and Confirmation

The initial imaging modality for suspected hip dislocation is plain radiography, typically consisting of anteroposterior (AP) and lateral views of the hip and pelvis, which demonstrate the position of the femoral head relative to the acetabulum and confirm the direction of dislocation (posterior, anterior, or inferior).^[20] These views also reveal associated bony injuries, such as acetabular rim fractures or femoral head fractures, and disruption of Shenton's line—an arc formed by the inferior border of the superior pubic ramus and the medial aspect of the femoral neck—indicating displacement of the proximal femur.^[45]^[44] Computed tomography (CT) scanning is the gold standard for evaluating associated fractures following initial plain films or after attempted closed reduction, as it provides detailed multiplanar images to detect small acetabular rim fragments, intra-articular loose bodies, or femoral head fractures that may be missed on radiographs.^[46]^[47] CT is particularly valuable for preoperative planning in cases requiring surgical intervention, quantifying fragment size and displacement to guide fixation or reconstruction.^[48] In post-reduction scenarios, routine CT is recommended to ensure concentric reduction and identify occult injuries that could lead to complications like avascular necrosis.^[20] Magnetic resonance imaging (MRI) plays a limited role in the acute setting due to time constraints and patient instability but is indicated for assessing soft tissue injuries, such as labral tears or capsuloligamentous damage, particularly in chronic dislocations or after reduction to evaluate persistent symptoms.^[49] MRI effectively identifies associated injuries like labral tears from traumatic dislocation, muscle strains, joint effusions, and potential nerve involvement (e.g., sciatic nerve in posterior dislocations), providing superior soft tissue contrast compared to CT.^[50]^[51] It is especially useful in cases with suspected intra-articular pathology or when plain films and CT are inconclusive for non-bony structures.^[48] Ultrasound has a restricted role in acute traumatic hip dislocation in adults, as it is less effective for evaluating deep bony structures and is primarily reserved for screening and diagnosis of developmental dysplasia of the hip (DDH) in pediatric patients under 6 months of age, where it assesses femoral head coverage and acetabular morphology without radiation exposure.^[52]^[53] In neonates and infants at risk for DDH, dynamic ultrasound using techniques like the Graf method can detect subluxation or dislocation by visualizing the cartilaginous femoral head position relative to the acetabulum.^[54] It is not routinely used for confirming acute traumatic dislocations in older children or adults due to acoustic shadowing from bone and limited field of view.^[55]

Management

Closed Reduction and Nonoperative Care

Closed reduction is the initial management approach for uncomplicated traumatic hip dislocations, particularly posterior types without associated fractures, aiming to restore joint alignment non-surgically under sedation to minimize complications such as avascular necrosis.^[20] This procedure is ideally performed emergently within 6 to 12 hours of injury to optimize outcomes.^[56] Common techniques include the Allis maneuver, performed with the patient supine, where an assistant provides countertraction via a sheet around the pelvis while the operator applies inline traction to the flexed hip and knee, followed by gentle rotation to relocate the femoral head.^[56] The Stimson maneuver involves positioning the patient prone with the hip and knee flexed over the edge of the bed, allowing gravity-assisted reduction with downward pressure on the knee, often requiring less force and considered the least traumatic option.^[46] Both methods necessitate procedural sedation for muscle relaxation and pain control.^[57] Success rates for closed reduction of posterior hip dislocations without fracture range from 70% to 90%, with higher rates achieved in timely interventions by experienced providers in the emergency setting.^[57] Failure may necessitate open reduction, particularly if intra-articular fragments or soft tissue interposition is present. Following successful reduction, immediate post-reduction anteroposterior and lateral radiographs confirm concentric alignment, supplemented by computed tomography to exclude retained loose bodies or occult fractures.^[20] Protected weight-bearing is recommended for 4 to 6 weeks.^[20] Pain is managed with intravenous analgesics such as opioids, and ongoing monitoring assesses for stability through clinical examination and serial imaging.^[56]

Surgical Interventions

Surgical interventions are indicated for hip dislocations that cannot be successfully managed with closed reduction, such as cases involving incarcerated intra-articular fragments, persistent instability following attempted reduction, or associated acetabular fractures that require internal fixation.^[58]^[1] Incarcerated fragments, often soft tissue or bony debris blocking the joint space, necessitate surgical removal to achieve stable reduction and prevent ongoing damage to the articular surfaces.^[3] Similarly, post-reduction instability, where the femoral head fails to remain congruent within the acetabulum, warrants operative stabilization to avoid recurrent subluxation or further dislocation.^[20] Associated acetabular fractures, particularly posterior wall or column fractures common in posterior dislocations, demand surgical intervention for anatomic reconstruction and fixation to restore joint stability and function.^[59] The primary surgical procedure for these indications is open reduction with or without internal fixation, most commonly performed via the posterior Kocher-Langenbeck approach for posterior hip dislocations, which account for the majority of traumatic cases.^[60] This approach provides direct access to the posterior acetabulum, allowing visualization and clearance of any interposed tissue or fragments, followed by reduction of the femoral head into the acetabulum.^[59] For fracture-associated dislocations, internal fixation is achieved using screws, plates, or a combination to secure the acetabular fragments, ensuring stable joint congruence and minimizing the risk of malunion or nonunion.^[58] Anterior dislocations may require alternative approaches, such as the Smith-Petersen or Watson-Jones, to address anterior structures, though these are less frequent.^[3] Arthroscopic techniques are emerging as minimally invasive options for select cases, particularly for capsule repair, labral refixation, or removal of small intra-articular fragments in irreducible dislocations without major fractures.^[61] These procedures utilize small portals and an arthroscope to address soft tissue pathology, such as labral tears or capsular defects contributing to instability, offering reduced morbidity compared to open surgery in appropriately selected patients.^[62] However, arthroscopy is typically reserved for cases without complex bony involvement, as open approaches remain the standard for fracture fixation.^[61] Timing of surgical intervention is critical, with emergent operation recommended within 6 hours of injury to minimize the risk of avascular necrosis (AVN) of the femoral head, a major complication arising from prolonged dislocation-induced vascular compromise.^[63] Meta-analyses confirm that reductions or surgeries performed within this window significantly lower AVN rates compared to delays beyond 6-12 hours.^[64]^[63] Delays often stem from failed closed reduction attempts, underscoring the need for rapid escalation to operative management when nonoperative efforts prove insufficient.^[58]

Rehabilitation and Recovery

Immediate Postoperative Protocols

Following closed reduction of a traumatic hip dislocation, immediate postoperative protocols emphasize joint stability, prevention of complications, and early initiation of supportive care to facilitate recovery while minimizing risks such as avascular necrosis and recurrent injury. Patients are typically admitted to the hospital for observation, with legs maintained in slight abduction using pillows or a pad to avoid adduction forces that could precipitate redislocation.^[56] For more complex dislocations (e.g., those with associated fractures), an abduction brace is often applied to hold the hip in neutral to slight external rotation and abduction, allowing limited flexion-extension while restricting other motions; this immobilization is maintained for 4-6 weeks alongside protected weight-bearing restrictions, such as toe-touch or non-weight-bearing status using crutches or a walker.^[2] ^[20] In select cases, particularly involving instability or in pediatric patients, a spica cast may be used for immobilization, though abduction bracing is more common in adults to promote earlier mobility.^[56] Skeletal traction is sometimes employed for 1-2 weeks post-reduction to maintain alignment and reduce intra-articular pressure, especially in posterior dislocations.^[56] Monitoring begins immediately with repeat neurovascular assessments and post-reduction radiographs (anteroposterior and lateral views) to confirm concentric reduction and joint stability, followed by a CT scan to evaluate for occult fractures, loose bodies, or incongruity.^[20] ^[2] Serial X-rays are performed at intervals (e.g., 2 weeks, 6 weeks, and 3 months) to detect redislocation, which occurs in approximately 1% of cases but warrants vigilant surveillance given the potential for associated soft tissue damage.^[65] ^[1] Deep vein thrombosis (DVT) prophylaxis is initiated promptly, typically with low-molecular-weight heparin (LMWH) or aspirin, continuing for the duration of immobilization due to the elevated thromboembolic risk from bed rest and injury-related hypercoagulability.^[56] Pain management employs a multimodal approach, including parenteral narcotics for acute severe pain, nonsteroidal anti-inflammatory drugs (NSAIDs) for inflammation, and ice application to reduce swelling during the initial 24-48 hours.^[2] Gentle passive range-of-motion (ROM) exercises, such as pendulum swings, are introduced as early as day 1 post-reduction if stability is confirmed, progressing under supervision to avoid excessive stress on the capsule.^[2] ^[1] A multidisciplinary team, including orthopedic surgeons, physical therapists, and nurses, coordinates care from the outset; physical therapy involvement focuses on safe non-weight-bearing transfers, bed mobility, and patient education on hip precautions to prevent inadvertent dislocation during daily activities.^[2] ^[1] This integrated approach ensures compliance with restrictions and supports a transition to outpatient follow-up within 1-2 weeks.^[56]

Long-Term Rehabilitation Exercises

Long-term rehabilitation for hip dislocation typically begins after the initial healing phase, once the joint has been stabilized through reduction and immobilization, focusing on restoring range of motion (ROM), strength, and functional stability to minimize the risk of redislocation. Rehabilitation protocols vary based on the type of dislocation, presence of associated injuries, and patient factors such as age, with no universally established standard; individualized programs under medical supervision are recommended.^[58] ^[66] These programs progressively challenge the hip while protecting healing tissues, emphasizing muscle strengthening around the hip to enhance joint stability. For simple dislocations without fractures, full activity may be possible in 3-4 months.^[58] Rehabilitation is often divided into phases, though timelines and specifics differ by case: Early Phase (typically weeks 4-12 post-injury): This phase prioritizes gentle ROM restoration and isometric strengthening to rebuild muscle activation without stressing the joint. Common exercises include isometric gluteal sets (contracting the gluteus maximus by squeezing the buttocks for 5-10 seconds, 10-15 repetitions several times daily) and heel slides (supine sliding of the heel toward the buttocks to improve flexion to 0-90 degrees, 10-20 repetitions). Core exercises like supine bridges may be added for pelvic stability. Aquatic therapy can provide low-impact ROM work toward the end of this phase.^[58] Intermediate Phase (months 2-4): This phase incorporates dynamic strengthening and conditioning to improve endurance and function. Stationary biking with low resistance (10-15 minutes, 3-5 times weekly) promotes flexion and extension. Progressive resistance exercises, such as clamshells (side-lying knee lifts with feet together, using a band after initial weeks, 8-12 repetitions), target abductors like the gluteus medius. Closed-chain exercises like mini-squats or step-ups (8-12 repetitions) integrate strength with balance, progressing as tolerated.^[58] Advanced Phase (4+ months): Focus shifts to functional training for return to pre-injury activities. Balance exercises, such as single-leg stance (30-60 seconds), enhance proprioception. Cardiovascular activities like elliptical training or walking on soft surfaces build to 20-30 minutes. Sport-specific drills are tailored for athletes. Regular assessments ensure safe progression.^[58]

Prognosis and Complications

Short-Term Outcomes

Short-term outcomes following treatment for traumatic hip dislocation are generally favorable when reduction is achieved promptly, with anatomic reduction succeeding in approximately 90-95% of cases using closed techniques in timely interventions. Emergent closed reduction, ideally within 6-12 hours of injury, minimizes early risks and allows for concentric joint positioning confirmed by post-reduction imaging. In simple dislocations without associated fractures, outcomes are optimized, enabling early mobilization under protected conditions.^[20]^[2] Early complications, though relatively uncommon, include redislocation rates of less than 2% in native hips post-reduction, rising to 2-10% in cases with capsular tears or intra-articular fragments. Postoperative infection occurs in 1-2% of surgical interventions, such as open reductions or fracture stabilizations, necessitating vigilant monitoring and prophylactic antibiotics. Heterotopic ossification, an abnormal bone formation in soft tissues, develops in 7.5-64% of cases depending on trauma severity, often detectable within weeks via imaging and potentially limiting motion if severe.^[20]^[24]^[67] Recovery timelines typically involve pain resolution within 4-6 weeks, transitioning from acute management with analgesics to functional improvement. Partial weight-bearing is introduced by 6 weeks for uncomplicated cases, supported by crutches or braces to protect joint stability, with pendulum exercises beginning around 1 week post-reduction. Outcomes are superior in isolated dislocations compared to those in polytrauma settings, where associated injuries occur in up to 95% of cases, complicating rehabilitation and increasing early morbidity.^[20]^[2]^[24]

Long-Term Complications

One of the most significant long-term complications following traumatic hip dislocation is avascular necrosis (AVN) of the femoral head, with reported incidences ranging from 5% to 40%.^[67] The risk of AVN increases substantially if closed reduction is delayed beyond 12 hours, with a meta-analysis showing an odds ratio of 5.627 compared to reductions performed within 12 hours.^[64] This interruption of blood supply to the femoral head can progress to structural collapse, often resulting in severe pain, joint degeneration, and the need for total hip replacement in advanced stages.^[68] Post-traumatic arthritis represents another prevalent delayed sequela, affecting 16% of patients with uncomplicated dislocations and rising to as high as 88% in cases involving associated acetabular or femoral fractures, typically manifesting within 10 years post-injury.^[69] The development of this osteoarthritis stems from initial cartilage damage and joint incongruity, leading to progressive pain, stiffness, and functional decline that may ultimately require joint arthroplasty.^[70] Recurrent instability occurs in approximately 2% of traumatic hip dislocations, though rates can vary with injury severity and may necessitate revision surgical procedures such as capsulorrhaphy or arthroplasty to restore stability.^[71] Additionally, functional deficits persist in up to 24% of cases long-term, manifesting as a persistent limp, reduced range of motion, and limitations in daily activities, particularly when AVN or arthritis complicates recovery.^[72] These outcomes underscore the importance of timely intervention to mitigate quality-of-life impacts.

Epidemiology

Incidence and Demographics

Traumatic hip dislocation is a rare orthopedic injury, with an estimated global incidence of approximately 5 to 6 cases per 100,000 population annually, though rates vary by region and data source.^[73]^[74] The condition predominantly affects adults in the 20- to 50-year age group, reflecting the typical demographics of high-energy trauma victims.^[75]^[76] Demographically, traumatic hip dislocation exhibits a marked male predominance, with a male-to-female ratio of approximately 3:1, attributed to greater male exposure to high-risk activities such as motor vehicle operation and contact sports.^[77]^[78] Up to 70% of cases are associated with motor vehicle accidents, underscoring the role of dashboard injuries or unrestrained impacts in posterior dislocations, the most common subtype.^[24]^[76] Geographically, incidence is elevated in low- and middle-income countries, where road traffic injuries contribute disproportionately due to limited safety infrastructure. In high-income countries, such as the United States, there has been a slight decline in incidence over recent decades, with age-standardized rates decreasing by about 21% from 1990 to 2019, largely attributable to improved vehicle safety measures and seatbelt usage.^[79]

Risk Factors and Prevention

Hip dislocation can occur due to traumatic, congenital, or iatrogenic factors, with certain predisposing elements elevating the likelihood. High-energy trauma, such as motor vehicle accidents or falls from significant heights, is a primary cause of traumatic hip dislocation, often involving forces that exceed the joint's stability.^[80] Alcohol impairment contributes to this risk by increasing the probability of involvement in such accidents, as it is associated with a substantial portion of road traffic injuries worldwide.^[81] Prior hip surgery, including procedures like total hip arthroplasty or fracture fixation, significantly elevates the odds of subsequent dislocation, with studies indicating at least a doubled risk compared to patients without such history.^[82] Congenital conditions, particularly untreated developmental dysplasia of the hip (DDH), predispose individuals to dislocation by resulting in a shallow acetabulum that compromises joint stability and increases the potential for subluxation or full dislocation later in life.^[83] This dysplasia often stems from risk factors like breech presentation during pregnancy, female sex, and family history, which can lead to abnormal hip development if not addressed early.^[84] Prevention strategies focus on mitigating trauma and addressing congenital risks proactively. Seatbelt use in vehicles substantially lowers the risk of hip dislocation from dashboard impacts during collisions, reducing overall injury severity by approximately 45-50% in frontal crashes.^[1] In sports and high-risk activities, wearing protective gear such as padded shorts or hip guards can help absorb impact forces and prevent dislocation.^[80] For congenital prevention, early screening with ultrasound is recommended for high-risk infants, such as those with breech presentation or family history, typically performed between 4-6 weeks of age to detect DDH and enable timely intervention like bracing.^[85] On a public health level, organized trauma systems play a crucial role by streamlining patient transport and care, thereby reducing the time from injury to reduction—ideally within 6 hours—which minimizes complications like avascular necrosis associated with delayed treatment.^[4]

Veterinary Aspects

Occurrence in Animals

Hip dislocation, also known as coxofemoral luxation, is a notable orthopedic condition in veterinary medicine, with varying incidence across species that often differs from the trauma-centric patterns observed in humans. In dogs, it represents one of the most common joint luxations, comprising up to 90% of all reported joint dislocations in this species.^[86] The condition is particularly prevalent in large breeds such as Labrador Retrievers and German Shepherds, where it accounts for approximately 20% of all hip joint disorders in clinical surveys.^[87] Trauma, including blunt force from motor vehicle accidents or falls, is the primary cause in over 80% of cases, while hip dysplasia serves as a significant predisposing factor that can lead to spontaneous or recurrent luxation due to joint instability.^[88]^[89] In cats, hip dislocation is less common than in dogs but frequently arises from high-impact trauma, such as falls from heights or vehicular collisions, which disrupt the joint capsule and ligaments.^[90] Although hip dysplasia occurs in up to 20% of purebred cats and can contribute to subluxation or luxation over time, traumatic dislocation predominates in domestic shorthair cats, where the overall incidence of dysplasia-related issues remains low at around 5%.^[91]^[92] Species variations highlight further differences; in horses, hip luxation is rare and uncommon compared to smaller animals, primarily affecting young foals, ponies, or miniature breeds due to traumatic events like dystocia during foaling or slips on slick surfaces.^[93]^[94] In cattle, the condition is a leading cause of proximal hindlimb lameness, often triggered by calving trauma that ruptures supporting structures, with craniodorsal luxation being the predominant form and caudoventral luxation as the secondary type.^[95]

Treatment Differences

In veterinary medicine, treatment for hip dislocation, or coxofemoral luxation, diverges significantly from human approaches, which prioritize joint preservation through techniques like open reduction and internal fixation. In animals, management often emphasizes salvage procedures due to anatomical differences, economic considerations, and the animal's inability to comply with prolonged immobilization, leading to higher rates of euthanasia or conservative care in severe cases.^[89] For dogs, closed reduction under anesthesia is attempted but succeeds in only about 50% of cases and is rarely pursued long-term due to frequent reluxation from ligamentous instability. Instead, femoral head ostectomy (FHO) serves as a primary salvage procedure, involving removal of the femoral head and neck to eliminate painful articulation while allowing formation of a fibrous pseudojoint. Total hip replacement (THR) is an alternative for younger, larger-breed dogs where superior biomechanics and joint preservation are feasible, though it is more costly and invasive.^[89]^[96]^[97] In large animals such as horses, conservative management with slings, sedation, and stall rest is preferred for minor or craniodorsal luxations, achieving survival to discharge in all treated cases and long-term return to use in approximately 71%. However, severe traumatic luxations—often resulting from high-impact falls—carry a guarded prognosis, with 50% or fewer horses surviving due to complications like fracture or infection, frequently necessitating euthanasia as a humane option. Femoral head ostectomy is reserved for small equids or ponies as a salvage measure, given the technical challenges and poor outcomes in full-sized horses.^[98]^[99]^[100] Postoperative protocols in veterinary patients highlight shorter rehabilitation timelines compared to human care, with small animals like dogs typically requiring 4-8 weeks of controlled activity, passive range-of-motion exercises, and hydrotherapy to restore function. Emphasis on perioperative antibiotics, such as cephazolin or amoxicillin-clavulanate administered intravenously during surgery and orally for 7-10 days postoperatively, aims to prevent infection in the high-risk orthopedic environment.^[101]^[96]^[102] Outcomes reflect these pragmatic goals, with 93-96% owner satisfaction and good-to-excellent limb function in dogs following FHO, prioritizing pain relief over anatomic restoration—contrasting human objectives of full joint congruence. In equine cases, successful conservative or surgical interventions yield functional recovery in select survivors, but overall survival remains lower than in small animals.^[103]^[98]

References

[1]
Hip Dislocation - OrthoInfo - AAOS
A traumatic hip dislocation occurs when the head of the thighbone (femur) is forced out of its socket in the hip bone (pelvis). It typically takes a major ...
[2]
Posterior Hip Dislocation - StatPearls - NCBI Bookshelf
A hip dislocation occurs when the internal forces of the hip (labrum, capsule, ligamentum teres, muscles, bones, and mechanical anatomy) are overpowered by the ...
[3]
Dislocation of the Hip: A Review of Types, Causes, and Treatment
Dislocation of the hip is a well-described event that occurs in conjunction with high-energy trauma or postoperatively after total hip replacement.
[4]
Anterior Hip Dislocation - StatPearls - NCBI Bookshelf - NIH
Anterior hip dislocations are usually caused by forceful abduction with external rotation of the thigh and most commonly following a motor vehicle accident or ...Missing: definition | Show results with:definition
[5]
https://musculoskeletalkey.com/hip-dislocations-and-fractures-of-the-femoral-head/
[6]
Anatomy, Bony Pelvis and Lower Limb, Hip - StatPearls - NCBI - NIH
Jul 24, 2023 · The hip joint capsule is formed by three major ligaments: the iliofemoral, pubofemoral, and ischiofemoral ligaments. The capsular ligaments ...Introduction · Structure and Function · Nerves · Surgical Considerations
[7]
Hip Anatomy - Physiopedia
The hip joint is a ball and socket joint that is the point of articulation between the head of the femur and the acetabulum of the pelvis.Description · Motions Available · Ligaments & Joint Capsule · Labrum
[8]
Hip Capsulolabral Complex: Anatomy, Disease, MRI Features, and ...
Feb 1, 2024 · The labrum is a fibrocartilaginous structure along the acetabular rim that encircles most of the femoral head.<|separator|>
[9]
Hip joint: Bones, movements, muscles | Kenhub
Hip joint is an articulation between the femoral head and the acetabulum of the hip bone. Learn about its anatomy and function now at Kenhub!
[10]
Ischiofemoral Ligament - Physiopedia
The ischiofemoral ligament originates from the ischium at a point below and behind the acetabulum and attaches to the intertrochanteric line of the femur. It ...Introduction · Attachments · Clinical Relevance
[11]
Hip Joint Capsular Anatomy, Mechanics, and Surgical Management
The zona orbicularis resists joint distraction (during neutral positions), and its aperture mechanism stabilizes the hip from adverse edge-loading (during ...
[12]
Biomechanics, anatomy, pathology, imaging and clinical evaluation ...
One of the many important functions of the labrum is to increase the stability of the hip. This is accomplished by both increasing the depth of the acetabulum ...
[13]
Hip Labral Augmentation With Tibialis Anterior Tendon Allograft ...
The chondrolabral seal is essential for the function of a normal hip joint.1, 2 ... seal,” the vacuum effect that imparts joint stability.5, 6 Not all ...Surgical Technique · Labral Augmentation... · Graft Fixation
[14]
Arthroscopic Labral Repair of the Hip, Using a ... - PubMed Central
One of the properties of the labrum includes increasing the surface area and depth of the acetabulum to improve joint stability and the distribution of ...
[15]
BUILDING A BETTER GLUTEAL BRIDGE - NIH
The strength of these two gluteal muscles, which comprise about 33% of the hip musculature, is essential for athletic, non-athletic, and post-surgical ...Table 3 · Figure 2 · Figure 4
[16]
The role of the psoas and iliacus muscles for stability and ... - PubMed
Selective activation of the iliacus could, however, be seen to stabilize the pelvis in contralateral hip extension during standing. Psoas was found to be ...
[17]
Femoral neck-shaft angle | Radiology Reference Article
Aug 16, 2020 · A known normal range of the caput-collum-diaphyseal (CCD) angle is generally considered 125°-135° 3, with a global mean of 126.4° and standard ...
[18]
Influence of femoral anteversion angle and neck-shaft angle on ...
Oct 12, 2023 · The objective of our study was to investigate the influence of femoral AVA and NSA on muscle forces and joint loads during walking.
[19]
Hip Dislocation - Trauma - Orthobullets
May 2, 2024 · Hip dislocations are traumatic hip injuries that result in femoral head dislocation from the acetabular socket. ... posterior dislocation (90%).
[20]
Posterior dislocation of the hip | Radiology Reference Article
Jul 31, 2025 · However, in a posterior dislocation, the femoral head is usually displaced posterior, superior, and slightly lateral to the acetabulum and also ...
[21]
Unusual Posterior Traumatic Hip Dislocations at Yopougon/Abidjan ...
We report on one case of a bilateral posterior hip dislocation associated with symmetric acetabular fracture and two cases of infracotyloid dislocation.Missing: infra cotyloid
[22]
Hip Dislocation - Physiopedia
Posterior Traumatic Hip Dislocations constitute a significant majority, accounting for approximately 85% to 90% of all THD cases. Posterior dislocation, also ...<|control11|><|separator|>
[23]
Nerve injury in traumatic dislocation of the hip - PubMed
A review of the literature reveals an incidence of approximately 10% in adults and 5% in children.Missing: prevalence | Show results with:prevalence<|control11|><|separator|>
[24]
Hip Dislocation Management in the ED - Medscape Reference
Oct 21, 2025 · Posterior dislocation. Posterior dislocations constitute approximately 90% of hip dislocations caused by motor vehicle accidents. The femoral ...
[25]
Anterior hip dislocation | Radiology Reference Article
Aug 21, 2025 · The hip is abducted or hyperabducted, and the femoral head is usually inferior to the acetabulum. Shenton's line is also broken. Whereas ...<|control11|><|separator|>
[26]
Anterior hip dislocation complicated by thrombus in the common ...
Dec 3, 2020 · One underreported complication is femoral vessel thrombosis from direct compression against the femoral head. Dedicated imaging should be ...
[27]
Hip Dislocation: Practice Essentials, Epidemiology, Functional ...
Feb 23, 2023 · The large sciatic nerve lies just inferoposterior to the hip joint, whereas the femoral nerve lies just anterior to the hip. The proximal shaft ...Practice Essentials · Functional Anatomy · Sport-Specific Biomechanics · Etiology
[28]
Injuries to the hip joint in frontal motor-vehicle crashes - ResearchGate
Aug 7, 2025 · Hip fractures and dislocations in frontal crashes are of substantial concern to clinicians and automotive safety engineers because of the ...
[29]
Acute athletic trauma to the hip and pelvis - ScienceDirect
At least 70% of posterior hip dislocations occur as a result of a motor vehicle accident [18]. Although athletic hip dislocations typically occur in contact ...
[30]
Hip Dislocation - Emergency Management - DynaMed
Anterior hip dislocations. Often result from forceful hip abduction with external rotation, or hyperextension with external rotation. Epidemiology. Posterior ...
[31]
Review Hip dislocations—Epidemiology, treatment, and outcomes
1, 34 Arvidsson demonstrated that a traction force of 400 N (90 lbs) was needed in order to cause separation of the hip joint.2 The direction of the force ...
[32]
Hip Dislocations and Fractures of the Femoral Head
Jun 12, 2016 · (a) Acetabular fractures—One study reported that 70% of patients with hip dislocations had an associated acetabular fracture. Fracture of ...<|separator|>
[33]
Developmental Dysplasia of the Hip - StatPearls - NCBI Bookshelf
May 4, 2024 · Developmental dysplasia of the hip encompasses several hip abnormalities, including instability, acetabular dysplasia, subluxation, and dislocation.
[34]
Hip dislocation in cerebral palsy - PMC - NIH
Lateral migration of the hip (subluxation or partial dislocation) occurs in 30-60% of children with cerebral palsy who are not walking independently at 5 years.
[35]
Ehlers-Danlos Syndrome - StatPearls - NCBI Bookshelf - NIH
Complications of this disease include arterial rupture, organ rupture, joint dislocation, chronic pain, and fatigue, among many others. Proper diagnosis of EDS ...
[36]
Dislocation Following Total Hip Replacement - PMC - NIH
The risk of dislocation after primary total hip arthroplasty is approximately 2%. Dislocation rates of up to 28% are found after revision and implant exchange ...
[37]
Outcome of acute septic dislocation of hip in children reduced ... - NIH
The complication of acute septic dislocation of hip in children may not have a sinister prognosis as commonly believed. These hips however were associated with ...
[38]
Hip Dislocations - Injuries and Poisoning - Merck Manuals
Symptoms of a Dislocated Hip · Hip dislocations are very painful. People usually cannot move their leg. · When the thighbone is pushed backward, the affected leg ...
[39]
Dislocated Hip Symptoms, Diagnosis and Treatments - HSS
Anatomy of the hip joint ... In most hip dislocations, the femoral head of the thighbone is forced out of the acetabulum toward the rear (posterior dislocation).
[40]
Clinical Examination of the Hip | New England Journal of Medicine
Jun 15, 2022 · The log-roll test is frequently used in patients with trauma to detect injuries such as femoral neck fractures, hip fractures, hip dislocations, ...Missing: palpable | Show results with:palpable
[41]
Hip Dislocation Management in the ED Clinical Presentation
Oct 21, 2025 · The patient with vascular injury may present with hematoma, loss of pulses, and pallor. If a neurovascular deficit is found, the need to reduce ...Missing: symptoms | Show results with:symptoms
[42]
[PDF] Synopsis of Causation Traumatic Hip Dislocation - GOV.UK
Anterior dislocations may be associated with a palpable lump in the groin. In either case, the leg is usually shortened. The patient experiences extreme pain ...
[43]
Management and Outcomes of Anterior Hip Dislocation with Multiple ...
This report describes the presentation, diagnosis, and treatment of a 44-year-old woman with anterior hip dislocation and multiple comminuted fractures due to ...
[44]
Hip Dislocation Clinical Presentation: History, Physical Examination
Feb 23, 2023 · Patients often present in obvious severe pain in the hip region and upper leg. They may also complain of knee, lower leg, or even back pain.
[45]
Acute Hip Dislocation - Emergency Care BC
Hip dislocations are a true orthopedic emergency and reduction should be performed within 6 hours to reduce the risk of AVN. · Overall condition of the patient, ...
[46]
Shenton line | Radiology Reference Article - Radiopaedia.org
Aug 9, 2025 · Shenton line is an imaginary curved line drawn along the inferior border of the superior pubic ramus (superior border of the obturator foramen)
[47]
Hip Dislocation Workup - Medscape Reference
Feb 23, 2023 · CT scanning is helpful to the physician for diagnosing loose bodies and fragments that impede closed reduction and to evaluate acetabular ...
[48]
Evaluating the utility of post-reduction imaging for simple hip joint ...
Following closed reduction of hip dislocations, computed tomography (CT) is considered standard of care to identify occult fractures or intra-articular loose ...
[49]
Traumatic Hip Dislocation: What the Orthopedic Surgeon Wants to ...
Nov 13, 2017 · This article reviews the most commonly used classification systems of hip dislocation and emphasizes the most clinically important imaging findings.
[50]
Hip Dislocation Management in the ED Workup - Medscape Reference
Oct 21, 2025 · Magnetic resonance imaging (MRI) has a limited role in acute diagnosis and delineation of hip dislocation. Patients with multiple trauma are ...
[51]
Traumatic hip dislocation: early MRI findings - PubMed
MRI can effectively identify and quantify the muscle injury and joint effusion that invariably accompany traumatic hip dislocations.
[52]
Acetabular labral tear | Radiology Reference Article | Radiopaedia.org
Oct 15, 2025 · Major trauma (e.g. hip dislocation) may cause a labral tear. However, there is no history of previous trauma in most cases. Structural osseous ...On This Page · Radiographic Features · Mri
[53]
Developmental dysplasia of the hip | Radiology Reference Article
Oct 14, 2025 · This article describes the commonly used radiographic measurements and lines involved in developmental dysplasia of the hip.Graf method for ultrasound... · Hilgenreiner line · Acetabular angle · Perkin line
[54]
Developmental Dysplasia of the Hip (DDH) - Pediatrics - Orthobullets
Aug 28, 2025 · Developmental dysplasia of the hip (DDH) is a disorder of abnormal development resulting in dysplasia, subluxation, and possible dislocation ...
[55]
Developmental Dysplasia of the Hip - The Radiology Assistant
Dec 1, 2017 · Developmental dysplasia of the hip is a common musculoskeletal disorder in newborns. In this article we will discuss the ultrasound examination technique ...Ultrasound examination · Ultrasound orientation · Graf's classification · Type II
[56]
Imaging Update on Developmental Dysplasia of the Hip With the ...
The American College of Radiology recommends that a standard ultrasound examination be performed in two orthogonal planes: a coronal view in the standard plane ...
[57]
Hip Dislocation Management in the ED Treatment & Management
Oct 21, 2025 · If relocation of the hip is successful, immobilize the legs in slight abduction by using a pad between the legs to prevent adduction until ...
[58]
Hip Dislocation Treatment & Management - Medscape Reference
Feb 23, 2023 · Surgical intervention should be performed if closed reduction is unsuccessful, bony fragments or soft tissue remains in the joint space, or the ...
[59]
Kocher-Langenbeck approach to the acetabulum
The Kocher-Langenbeck approach is an approach to the posterior structures of the acetabulum. It allows direct visualization of the posterior column and the ...
[60]
Posterior Approach to the Acetabulum (Kocher-Langenbeck)
Oct 23, 2021 · Kocher-Langenbeck is used to refer to an approach used to address the acetabulum which is more extensile · Southern/Moore approach more commonly ...
[61]
Arthroscopic Treatment of Traumatic Hip Dislocation - PubMed
The use of hip arthroscopy to treat the sequelae and symptoms resulting from traumatic hip dislocations recently has increased, however.
[62]
Arthroscopic Treatment of a Posterior Labral Interposition after ... - NIH
Removal of bony fragments, reduction, sutures, or labral resections can be performed to gain a stable reduced hip. The procedure should be performed by ...
[63]
Early versus delayed hip reduction in the surgical treatment of ...
Dec 20, 2021 · A meta-analysis showed that early reduction of posterior hip dislocation within 6 h have a lower rate of osteonecrosis of the femoral head ...
[64]
Systematic Review and Meta-Analysis of Avascular Necrosis and ...
Analysis of posterior dislocations revealed that the event rate for AVN ranged from 0.106 to 0.430; additionally, the event rate for PTA ranged from 0.194 to ...Missing: prevalence | Show results with:prevalence
[65]
Hip dislocation | Radiology Reference Article | Radiopaedia.org
Mar 15, 2025 · Redislocation after a traumatic hip dislocation is uncommon (~1%) 9. Non-traumatic dislocations can occur in cerebral palsy patients 7,8 ...Posterior dislocation of the hip · Hip joint dislocation · Question 3101 · Question 236
[66]
Hip Conditioning Program - OrthoInfo - AAOS
This hip conditioning program should be continued for 4 to 6 weeks, unless otherwise specified by your doctor or physical therapist.Missing: guidelines | Show results with:guidelines
[67]
[PDF] Rehabilitation Guidelines for Surgical Hip Dislocation
Post-operatively the patient will begin outpatient physical therapy at about three weeks and eventually be able to return to full weight bearing, walking.
[68]
Non-Operative Rehabilitation Principles for Use in Individuals ... - NIH
Dec 2, 2023 · Both short and long lever hip flexion exercises should be discontinued if the patient reports increased pain. Muscle Stretching Principles.
[69]
Prevalence of Surgical Site Infection After Hip Arthroplasty - NIH
The study findings indicated a prevalence rate of 1.9% for SSI following hip arthroplasty. This prevalence underscores the importance of vigilance in infection ...
[70]
Prognostic factors after a traumatic hip dislocation. A long ... - Elsevier
Traumatic dislocation of the hip can have severe complications that include osteonecrosis, post-traumatic arthrosis, heterotopic ossifications, sciatic nerve ...
[71]
Avascular necrosis of the femoral head after traumatic posterior hip ...
Sep 14, 2020 · An essential prerequisite for the prevention of AVN of the femoral head after hip dislocation is emergency hip reduction.
[72]
Coxarthrosis After Traumatic Hip Dislocation in the Adult - PubMed
Sixteen percent of patients with uncomplicated hip dislocations have posttraumatic arthritis develop. Incidences as high as 88% are reported for patients ...
[73]
Long-term outcomes of traumatic hip dislocation: a minimum 10-year ...
Aug 28, 2025 · Patients after traumatic hip dislocation are at high risk for PTOA or AVN, especially with concomitant acetabular or femoral head fractures, ...
[74]
Adult Post-traumatic Recurrent Posterior Hip Dislocation with 17 ...
Introduction: Recurrent hip dislocations are quite uncommon, and only 2% of cases of all hip dislocations exhibit recurrence.
[75]
(PDF) The long-term results of traumatic posterior dislocation of the hip
Aug 7, 2025 · We found that 15 years after simple dislocation 24 per cent of the cases had a poor result by both clinical and radiological criteria, but in ...<|control11|><|separator|>
[76]
https://www.sciencedirect.com/science/article/abs/pii/S0020138309004392
[77]
A comprehensive study of hip dislocation: global health burden from ...
The age-standardized incidence rates for hip dislocations for both sexes were as follows: road injuries, 3.21 (95% UI: 1.63 to 6.08); exposure to mechanical ...
[78]
Epidemiology of traumatic hip dislocation in patients treated in ...
The most frequent type of hip dislocation observed was posterior dislocation (93%), and only 7% of anterior dislocations. The classification of lesions can be ...
[79]
Traumatic Greater Trochanteric Avulsion with Obturator Dislocation ...
Apr 1, 2025 · The third decade of life accounts for 35% of all traumatic hip dislocations, with a male-to-female ratio of 3:1 [1-5]. The ratio of posterior ...
[80]
Epidemiology of Sports-Related Traumatic Hip Dislocations ... - NIH
The estimated incidence per million persons per year was 0.88 (95% CI, 0.71-1.05). Male patients sustained more hip dislocation injuries (0.813) than female ...
[81]
Epidemiology of Hip Dislocations in the United States From 1990 to ...
Jun 28, 2025 · From 1990 to 2019, the U.S. saw a 1.67% decrease in the mean rate of YLDs, a 0.32% decrease in the mean prevalence rate, and a 4.74% decrease in ...
[82]
A comprehensive study of hip dislocation: global health burden from ...
The disease burden is relatively high among the youth (15–24) and the older population (50+). In SDI-stratified analyses, incidence gaps narrowed across all ...Abstract · Introduction · Results · Discussion
[83]
Dislocated Hip: Symptoms, Treatment & Recovery - Cleveland Clinic
It causes acute pain and disables your leg until it's corrected. It can also cause secondary injuries to the surrounding blood vessels, nerves, ligaments and ...Missing: deficits | Show results with:deficits
[84]
Risk Factors for Dislocation During the First 3 Months After Primary ...
[21 ] also found that a history of excessive alcohol intake was a risk factor for dislocation after revision hip replacement but found that it was not a ...Missing: impairment | Show results with:impairment
[85]
Causes of and treatment options for dislocation following total hip ...
In this review, we discuss the causes leading to dislocation following THA and evaluate the different treatment options available.Missing: symptoms | Show results with:symptoms
[86]
Hip Dysplasia: Symptoms, Causes & Treatment - Cleveland Clinic
Most people with hip dysplasia are born with it. It can develop during pregnancy if the fetus's position puts pressure on its hips. It can also be a genetic ...
[87]
Developmental Dysplasia of the Hip - AAFP
Oct 15, 2006 · Plain radiographs are useful after four to six months of age. Several ... (B) Shenton's line is disrupted on the left (dislocated) hip.<|separator|>
[88]
Infant Screening for Developmental Dysplasia of the Hip (DDH)
Jun 20, 2016 · If the hip feels normal but risk factors for DDH are present, CHOP orthopedists recommend that screening ultrasounds be performed at 4-6 weeks of age.
[89]
Outcome and complications following modified prosthetic capsule ...
Canine coxofemoral luxation is the most common luxation encountered in dogs, accounting for up to 90% of all joint luxations (1–12). Most cases are due to road ...
[90]
[PDF] INCIDENCE OF PELVIS AND HIP JOINT DISORDERS IN DOGS
Jun 1, 2024 · Among the hip joint disorders, highest occurrence was that of hip dysplasia (64.40%) followed by hip dislocation. (20.33%), femur head fracture ...
[91]
Hip Dislocation and Post-Operative Care in Dogs
The most common cause of hip dislocation is blunt force trauma, such as a fall or an automobile injury, but any traumatic injury to the hip area may cause a hip ...
[92]
Hip Luxation - American College of Veterinary Surgeons
Partial dislocation of the hip joint (subluxation) can occur and is typically associated with joint degeneration as with hip dysplasia. Subluxation is commonly ...
[93]
Joint Subluxations in Cats | VCA Animal Hospitals
The most common cause of hip dislocation is blunt force trauma such as a fall or an automobile injury. Most cats with a hip dislocation will have severe hind ...
[94]
New Knowledge and New Treatments for Feline Hip Dysplasia
Mar 2, 2016 · The incidence of hip dysplasia in domestic shorthair cats is low, just over 5 percent, but runs as high as 20 percent in purebred cats. The ...
[95]
The Prevalence of Feline Hip Dysplasia, Patellar Luxation and ... - NIH
Aug 24, 2021 · The prevalence of hip joint dysplasia in all pedigree cats was 46.7%, of which 78% of cats had bilateral dysplasia. Dysplasia was mainly from ...
[96]
Disorders of the Hip in Horses - MSD Veterinary Manual
The hip can dislocate when ligaments or joint membranes are ruptured due to trauma; however dislocation of the hip is uncommon in horses. When dislocation does ...Coxitis · Pelvic Fracture · Trochanteric Bursitis...
[97]
Radiographic diagnosis of craniodorsal coxofemoral luxation in ...
Feb 19, 2014 · Coxofemoral luxation is a rare injury in horses, but occurs most commonly in young equids and miniature horse breeds (Squire et al. 1991 ...
[98]
ajvr.22.05.0080.pdf - AVMA Journals
Coxofemoral or hip joint luxation is among the most common causes of orthopedic injury in the bovine proximal hindlimb1 and the second most com-.Missing: prevalence | Show results with:prevalence
[99]
Femoral Head Ostectomy (FHO) in Dogs | VCA Animal Hospitals
Approximately 90-95% of dogs with a total hip replacement do very well and have excellent post-surgical function. Hip Dislocation and Post-Operative Care in ...
[100]
Hip Dysplasia Surgery in Dogs - PetMD
Feb 13, 2024 · Total hip replacement surgery can return dogs to normal limb function with a success rate ranging from 80–98%. For puppies undergoing juvenile ...
[101]
Outcome of conservative and surgical treatment for luxations of the ...
Sep 1, 2017 · Following conservative treatment all horses (n = 8) survived to hospital discharge. At long-term follow-up 71.4% (5/7) had returned to intended ...
[102]
Femoral head ostectomy and medial patellar ligament desmotomy to ...
Overall, the prognosis following treatment of coxofemoral joint luxations is guarded, with 50% or fewer of horses surviving (7,8,10,17,24). If reduction of the ...Missing: euthanasia | Show results with:euthanasia
[103]
Coxofemoral luxation - How does our knowledge of treatment in ...
Femoral head ostectomy is generally considered a salvage procedure for small equids and ponies with chronic coxofemoral joint luxation [16, 17,22,23]. The ...
[104]
https://www.sustainablevet.org/blog/fho-surgery-dog-recovery-timeline
[105]
Post-Operative Management Following Fracture and Intra-Articular ...
A standard protocol I use is: Intravenous cephazolin (Kefzol @ 22mg/kg IV) or amoxicillin-clavulanate (Augmentin 20 mg/kg IV) is administered no less than 30 ...
[106]
Effect of Femoral Head and Neck Osteotomy on Canines' Functional ...
Jun 24, 2022 · Over the long term, the FHO limb has muscle atrophy, decreased coxofemoral extension, and decreased static weight bearing. However, this does not seem to ...