Modeling of ACL impingement against the intercondylar notch.

OBJECTIVE

To develop a 3-D mathematical model that accurately evaluates anterior cruciate ligament impingement against the intercondylar notch.

DESIGN

The model simulated physical interactions between the anterior cruciate ligament and the intercondylar notch in tibiofemoral movement.

BACKGROUND

Anterior cruciate ligament impingement has been evaluated through planar radiographic images, which may not characterize the complex 3-D notch shape associated with impingement.

METHODS

After examining potential anterior cruciate ligament impingement in five cadaver knee specimens, the model was implemented using data from an individual cadaveric knee with representative impingement. The knee was loaded passively in various patterns to induce impingement, and the impingement force and six degrees-of-freedom tibiofemoral kinematics were measured. The femur, tibia, and anterior cruciate ligament were digitized. Spatial data points representing the notch surfaces were surface-fitted using bicubic splines. The model detected for impingement during the tibiofemoral movement and used a "crawling algorithm" to determine the deformed geometry of the impinging ligament.

RESULTS

The model detected the impingement accurately and the ligament strain determined by the model was highly correlated with the recorded impingement force when impingement occurred during the tibiofemoral movement. Distance between the anterior cruciate ligament and the notch wall was determined when impingement was not detected.

CONCLUSION

The model quantitatively characterized impingement of the anterior cruciate ligament against the intercondylar notch in 3-D space.

RELEVANCE

The approach helps us better understand anterior cruciate ligament injury mechanisms in individual knees. Clinically, the model could potentially be used to analyze subject-specific potential/actual anterior cruciate ligament impingement based on the subject's MRI scans.