Tibiofemoral Dislocations

A dislocated knee (tibiofemoral dislocation) is rarer and more serious than a dislocated kneecap, because of the force required to misalign the leg bones and the damage, it does to the ligaments. A tibiofemoral dislocation is a formal name for a dislocated knee. It’s a fairly rare injury, but a serious one. On the inner side is the medial tibiofemoral compartment and on the outer side is the lateral tibiofemoral compartment. A tibiofemoral dislocation can cause damage to the structures that support your knee. This may result in joint instability, which can be a long-term problem. Symptoms a “popping” sensation, severe knee pain, being unable to straighten the knee, and the sudden swelling of the knee.

Pathophysiology

• Definition
  • Not all patients will present with an acutely dislocated knee or with an obvious deformity
  • Often, knee dislocation will reduce spontaneously or easily
• Direction of dislocation
  • Anterior (40%), due to forced hyperextension
  • Posterior (30%), common mechanism tibia impacting the dashboard during deceleration in motor vehicle accidents
  • Medial (18%)
  • Lateral (4%)
  • Rotational (less than 5%)

Etiology

• High energy trauma including motor vehicle accidents, falls from height, and industrial injuries
• Can occur in lower energy sports and sport-related activities
• Spontaneous injuries during ambulation in the morbidly obese

Associated Injuries

• Most commonly injured are the major knee stabilizers
  • Multi Ligament Knee Injury, often bicruciate, including ACL + PCL + LCL/MCL
  • ACL Injury
  • PCL Injury
  • MCL Injury
  • LCL Injury
  • Biceps tendon avulsions
  • Popliteus tendon tears
  • Arcuate complex injuries
• Less commonly injured orthopedic structures
  • Meniscal Tear in about 50% of cases
  • Chondral injuries
  • Bone bruises are seen in the majority of cases
  • Fractures are seen in about 1/3 of cases
  • Extensor Mechanism Injuries

• Sports with reported cases
  • Soccer
  • Wrestling
  • Rugby
  • Kabaddi
  • Long jump
  • Skating
  • Cycling
  • Skiing
  • Gymnastics
  • Motorsports
  • Extreme adventure sports
• Other
  • Morbid Obesity is a risk factor for low energy mechanism

Differential Diagnosis

• Fractures
  • Distal Femur Fracture
  • Patellar Fracture
  • Tibial Plateau Fracture
• Dislocations & Subluxations
  • Patellar Dislocation (and subluxation)
  • Knee Dislocation
  • Proximal Tibiofibular Joint Dislocation
• Muscle and Tendon Injuries
  • Quadriceps Contusion
  • Iliotibial Band Syndrome
  • Quadriceps Tendonitis
  • Patellar Tendonitis
  • Popliteus Tendinopathy
  • Extensor Mechanism Injury
    • Patellar Tendon Rupture
    • Quadriceps Tendon Rupture
    • Patellar Fracture
• Ligament Pathology
  • ACL Injury
  • PCL Injury
  • MCL Injury
  • LCL Injury
  • Meniscal Pathology
  • Posterolateral Corner Injury
  • Multiligament Injury
• Arthropathies
  • Knee Osteoarthritis
  • Septic Arthritis
  • Gout
• Bursopathies
  • Prepatellar Bursitis
  • Pes Anserine Bursitis
  • MCL Bursitis
  • Infrapatellar Bursitis
• Patellofemoral Pain Syndrome (PFPS)/ Anterior Knee Pain)
  • Chondromalacia Patellae
  • Patellofemoral Osteoarthritis
  • Osteochondral Defect Knee
  • Plica Syndrome
  • Infrapatellar Fat Pad Impingement
  • Patellar Instability
• Neuropathies
  • Saphenous Nerve Entrapment
• Other
  • Bakers Cyst
  • Patellar Contusion
• Pediatric Considerations
  • Patellar Apophysitis (Sinding-Larsen-Johansson Disease)
  • Patellar Pole Avulsion Fracture
  • Tibial Tubercle Avulsion Fracture
  • Tibial Tuberosity Apophysitis (Osgood Schalatters Disease)

Diagnosis

• History
  • Most commonly high energy trauma and deformity of the knee
  • May also report lower energy mechanism with pain +/- deformity
  • Also endorses instability if attempting to ambulate
• Physical Exam: Physical Exam Knee
  • About 50% of cases will have no obvious deformity and gross appearance may be normal!
  • Dimple Sign: buttonholing of medial femoral condyle through a medial capsule
  • Very important to document a thorough vascular exam
  • The presence of peripheral pulses does not exclude vascular injury
  • A serial vascular exam is mandatory
  • Assess Peroneal Nerve, Tibial Nerve
• Special Tests
  • Ankle Brachial Index: can be used to compare vascular flow to the contralateral limb
  • Need to perform structural exam assessing ACL, PCL, MCL, and LCL

Ankle Brachial Index

• Excellent screening tool since arteriography is impractical in all patients
  • If ABI < 0.9, must pursue further vascular workup
• Mills et al: ABI <0.9 has 100% sensitivity, specificity, and PPD for vascular injuries in knee dislocations^[10]

Radiographs

• Standard Radiographs Knee
• It May be normal depending on the mechanism
  • look for asymmetric, irregular or widening joint space
  • Segunda Fracture, Osteochondral Defect may be seen
• Post reduction or post splinting films are necessary

MRI

• Indicated in most cases
  • After reduction, prior to surgical intervention if possible
• Helpful to identify the degree of soft tissue injury
  • Especially in the multi-ligament knee injury
• Consider angiography

CT

• Useful to evaluate for fracture patterns
• Findings
  • Tibial eminence fracture
  • Tibial tubercle fracture
  • Tibial Plateau fracture
• Consider angiography

Ultrasound

• Duplex arterial sonography may be useful to evaluate arterial supply

Classification

Kennedy Position Classification

• Anterior
  • Frequency: 40% (most common)
  • Mechanism: Hyperextension
  • Typically no medial or lateral damage
  • PCL can be intact
  • Vascular injury is common
• Posterior
  • Frequency: 30%
  • Mechanism: Direct anterior-posterior force
  • Sometimes ACL is intact
  • Vascular damage is common
• Lateral/ Lateral
  • Frequency: Rare in isolation (often with anterior or posterior)
  • Most of the time is posterolateral or posteromedial
  • Bicruciate injury with ACL and PCL
  • Vascular damage
  • Nerve damage in medial dislocations
• Rotatory
  • Frequency: Rare
  • Often complex lesions

Schenck Anatomic Knee Dislocation (KD) Classification

• KD I: Knee dislocation with either cruciate intact
• KD II: Bicruciate with collateral intact
• KD III: Bicruciate injury with one collateral ligament injury
  • KD IIIM: Bicruciate + MCL injury
  • KD IIIL: Bicruciate + LCL injury
• KD IV: Bicruciate with both collateral ligaments injured
• KD V: Periarticular fracture-dislocation

Treatment

Prognosis

• Levy et al systematic review compared operative to nonoperative management^[11]
  • Overall, operative treatment results in the better functional outcomes as compared to nonoperative treatment
  • International Knee Documentation Committee [IKDC] excellent/good results 58% operative vs 20% nonoperative
  • Return to sport is 29% in operative group vs 10% in the nonoperative group
  • Range of motion (126° vs. 123°) and flexion (4° vs. 3°) loss was similar among groups
• Levy looked at the timing of surgery^[12]
  • More likely to return to sport if surgery is done within 3 weeks
  • No difference in functional outcomes between early and late surgery

Acute

• Follow ATLS protocol when appropriate
• Physicians should be suspicious based on mechanism and examination, regardless of whether the deformity is present or not
• Reduction
  • Perform after XR only to confirm the diagnosis, exclude fracture
  • Recommend procedural sedation
  • The gentle extension is often all that is required
  • Will often self reduce with minimal manipulation
• Examination
  • Thorough structural examination
  • Confirm palpable dorsalis pedis, posterior tibia, and popliteal artery pulses
• Immobilization
  • Full-extension in long Hinged Knee Brace or Posterior Long Leg Splint
  • If the posterior capsule is injured, may require 20° of flexion to avoid posterior subluxation
  • May require temporary external fixation
• Imaging
  • Pre and post-reduction radiographs
  • Consider CT (with angiography), emergent MRI
  • Vascular- consider ABI, duplex arterial sonography
• Emergent surgery
  • Irreducible knee dislocation
  • Open knee dislocation
  • Vascular injury

Nonoperative

• Indications
  • Elderly
  • Patients who are not good surgical candidates or have multiple comorbidities

Operative

• Indications
  • Most patients
• Open reduction indications^[13]
  • Irreducible knee
  • Posterolateral dislocation
  • Open fracture-dislocation
  • Obesity (may be difficult to obtain closed)
  • Vascular injury
• External fixation indications
  • Vascular repair (takes precedence)
  • Open fracture-dislocation
  • Compartment syndrome
  • Obese (if difficult to maintain reduction)
  • Polytrauma patient
• Delayed ligamentous reconstruction/repair

Complications

• Amputation
  • The rate reported to be up to 85% for injuries not corrected in 8 hours^[4]
• Traumatic Osteoarthritis
• Chronic pain
  • 25% to 68% complain of chronic pain
• Arthrofibrosis
  • 5% to 71% develop arthrofibrosis making it the most common complication
  • 29% of patients will eventually require adhesiolysis
• Knee stiffness
  • Higher risk with 3 or more ligaments repaired
• Persistent knee instability
  • Instability in at least one plane ranges from 18% to 100% (mean 42%)
• Popliteal Artery injury
  • Reported in 18 to 64% of knee dislocations^[14]
  • Approximately 80% are repaired, 12% require amputation
  • Lower risk in sports-related injuries than high-velocity injuries^[15]
  • Early interventions within 8 hours (11%) are associated with lower rates of amputation than beyond (86%)^[16]
  • The highest risk with KD IV injuries
  • McDonough case series on popliteal artery injuries following MLKI^[17]
    • 4/12 identified by physical exam, 5/12 identified with arteriography, and 3/12 identified in OR with vascular exam and arteriography
• Peroneal Nerve Injury
  • Most commonly the Common Peroneal Nerve, however Superficial Peroneal Nerve, Deep Peroneal Nerve also affected
  • Injured in between 25% and 33% of dislocations, particular posterior and lateral^[18][19]
  • As high as 41% in posterolateral corner injuries^[20]
  • Among sports, skiing and football are most commonly associated^[21]
  • Approximately 30% have a complete palsy, with only 38.4% of them having a functional recovery
  • Approximately 70% have an incomplete palsy, and 87.3% of them have a functional recovery