Editors: Frassica, Frank J.; Sponseller, Paul D.; Wilckens, John H.
Title: 5-Minute Orthopaedic Consult, 2nd Edition
Copyright ©2007 Lippincott Williams & Wilkins
> Table of Contents > Posterior Cruciate Ligament Injury
Posterior Cruciate Ligament Injury
Marc Urquhart MD
John H. Wilckens MD
BasicsDescription
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Injury to the OSD, the primary stabilizer to posterior translation of the tibia on the femur at the knee (1)
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Classification (see “Posterior drawer test” under “Physical Exam”) (2):
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Grade 1: Tibial plateau is anterior to the femoral condyles.
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Grade 2: Tibial plateau is level with the femoral condyles.
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Grade 3: Tibial plateau is posterior to the femoral condyles.
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Epidemiology
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Young adults
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Males affected more than females
Incidence
Uncommon
Risk Factors
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Motor vehicle accident
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Participation in collision sports
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Hyperextension injury to the knee
Genetics
No Mendelian pattern is known.
Etiology
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Direct blow to the anterior tibia with the knee flexed and the foot plantarflexed
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Hyperflexion without a blow
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Hyperextension
Associated Conditions
Popliteal artery injury
DiagnosisSigns and Symptoms
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Knee pain and swelling after the injury with gradual improvement in generalized pain symptoms
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Minimal symptomatic instability, usually when climbing stairs
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Recurrent effusion
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Posterior knee pain
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Knee recurvatum (late finding)
Physical Exam
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Perform a complete neurovascular examination.
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Tests for ligamentous stability:
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Posterior drawer test:
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Position the patient supine with the knee flexed 90° and the foot stabilized on the examination table.
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Apply posterior force to the anterior tibia.
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Note the excursion of the tibia underneath the femoral condyles.
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Note the quality of the end point.
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Compare the involved and contralateral sides.
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The position of the affected knee can
reveal a posterior sag of the tibia when the patient is supine with
hips flexed 45°, knees flexed 90°, and feet flat on the examination
table.
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Lachman test:
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Anterior drawer test at 30° of flexion
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To rule out associated ACL rupture
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Rule out collateral ligament injury
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Tests
Lab
None indicated
Imaging
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Radiography:
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Plain film AP and lateral views of the knee:
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To evaluate for fracture about the knee
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May reveal an avulsion fracture off the proximal posterior tibia
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Stress radiography
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MRI is very sensitive for identifying PCL injury and associated injuries
Pathological Findings
Either midsubstance rupture or proximal or distal bony avulsion is noted.
Differential Diagnosis
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ACL injury
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Tibial plateau fracture
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Meniscal tear
TreatmentGeneral Measures
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Patients may be partial weightbearing as tolerated.
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History and physical examination for a provisional diagnosis
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Radiography and MRI to confirm the diagnosis
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Nonoperative treatment initially, except for high-grade injuries/knee dislocations
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Knee immobilizer and crutch ambulation as tolerated until comfortable
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Early ROM and strengthening
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Knee braces are of questionable use.
P.339
Special Therapy
Physical Therapy
A specific OSD-insufficiency knee program is initiated.
Medication
First Line
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NSAIDs
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Acetaminophen
Second Line
Mild, as-needed narcotics for acute/severe pain
Surgery
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Relative indications for surgery:
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Grade 3 PCL injuries
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Posterolateral corner injuries
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Associated ligamentous, meniscal, or articular surface injuries
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Giving-way of the knee
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Pain
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Radiographically documented progressive articular deterioration
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Reduction and internal fixation of avulsion fractures
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Reconstruction is reserved for patients with symptomatic swelling and activity-related pain (3).
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The procedure entails reconstruction of the ligament with an autograft or allograft.
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Arthroscopically assisted reconstructions are demanding technically but obviate wide surgical exposure.
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Follow-upPrognosis
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Extremely good
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Most patients do not require surgery (4).
Complications
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Recurrent symptomatic giving-way of the knee
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Failure of reconstruction
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Progressive medial compartment arthrosis, followed by patellofemoral compartment arthrosis
Patient Monitoring
Patients are followed at 3–6-month intervals to check on their prognosis with ROM, muscle strength, and function.
References
1. Miller MD, Bergfeld JA, Fowler PJ, et al. The posterior cruciate ligament injured knee: principles of evaluation and treatment. Instr Course Lect 1999;48:199–207.
2. Shelbourne
KD, Rubinstein RA, Jr. Methodist Sports Medicine Center’s experience
with acute and chronic isolated posterior cruciate ligament injuries. Clin Sports Med 1994;13:531–543.
KD, Rubinstein RA, Jr. Methodist Sports Medicine Center’s experience
with acute and chronic isolated posterior cruciate ligament injuries. Clin Sports Med 1994;13:531–543.
3. Johnson
TS, Cosgarea AJ. Posterior cruciate ligament injuries. In: Garrick JG,
ed. Orthopaedic Knowledge Update: Sports Medicine 3. Rosemont, IL:
American Academy of Orthopaedic Surgeons, 2004:155–168.
TS, Cosgarea AJ. Posterior cruciate ligament injuries. In: Garrick JG,
ed. Orthopaedic Knowledge Update: Sports Medicine 3. Rosemont, IL:
American Academy of Orthopaedic Surgeons, 2004:155–168.
4. Shelbourne
KD, Davis TJ, Patel DV. The natural history of acute, isolated,
nonoperatively treated posterior cruciate ligament injuries. A
prospective study. Am J Sports Med 1999;27:276–283.
KD, Davis TJ, Patel DV. The natural history of acute, isolated,
nonoperatively treated posterior cruciate ligament injuries. A
prospective study. Am J Sports Med 1999;27:276–283.
MiscellaneousCodes
ICD9-CM
717.84 Disruption of the posterior cruciate ligament
Patient Teaching
Isolated PCL injuries often are treated nonoperatively.
FAQ
Q: What is the natural history of nonoperatively treated isolated PCL injuries?
A:
Most patients are able to return to functional activity in 6–8 weeks.
Although progressive laxity is uncommon, patients can develop medial
and patellofemoral compartment changes over the ensuing years of PCL
laxity.
Most patients are able to return to functional activity in 6–8 weeks.
Although progressive laxity is uncommon, patients can develop medial
and patellofemoral compartment changes over the ensuing years of PCL
laxity.
Q: Are other injuries associated with PCL injury?
A:
Low-energy PCL injuries usually are isolated. However, high-energy PCL
injuries usually are accompanied by collateral ligament injury and/or
ACL injury. A patient with a high-energy PCL tear should be evaluated
for concomitant vascular and neurologic injury.
Low-energy PCL injuries usually are isolated. However, high-energy PCL
injuries usually are accompanied by collateral ligament injury and/or
ACL injury. A patient with a high-energy PCL tear should be evaluated
for concomitant vascular and neurologic injury.