Biomechanical Evaluation of the Medial Collateral Ligament of the Elbow

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The Journal of Bone and Joint Surgery 79:1223-31 (1997)
© 1997 The Journal of Bone and Joint Surgery, Inc.

Biomechanical Evaluation of the Medial Collateral Ligament of the Elbow*

G. H. CALLAWAY, M.D. ${dagger}$ , L. D. FIELD, M.D. ${ddagger}$ , X.-H. DENG, M.D. $§$ , P. A. TORZILLI, PH.D. $§$ , S. J. O'BRIEN, M.D. $§$ , D. W. ALTCHEK, M.D. $§$ and R. F. WARREN, M.D. $§$ , NEW YORK, N.Y.

Investigation performed at The Hospital for Special Surgery, Affiliated with The New York Hospital—Cornell University Medical College, New York City

Anatomical dissection and biomechanical testing were used tostudy twenty-eight cadaveric elbows in order to determine therole of the medial collateral ligament under valgus loading.The medial collateral ligament was composed of anterior, posterior,and occasionally transverse bundles. The anterior bundle was,in turn, composed of anterior and posterior bands that tightenedin reciprocal fashion as the elbow was flexed and extended. Sequential cutting of the ligament was performed while rotationcaused by valgus torque was measured. The anterior band of theanterior bundle was the primary restraint to valgus rotationat 30, 60, and 90 degrees of flexion and was a co-primary restraintat 120 degrees of flexion. The posterior band of the anteriorbundle was a co-primary restraint at 120 degrees of flexionand a secondary restraint at 30 and 90 degrees of flexion. Theposterior bundle was a secondary restraint at 30 degrees only. The reciprocal anterior and posterior bands have distinctbiomechanical roles and theoretically may be injured separately.The anterior band was more vulnerable to valgus overload whenthe elbow was extended, whereas the posterior band was morevulnerable when the elbow was flexed. The posterior bundle wasnot vulnerable to valgus overload unless the anterior bundlewas completely disrupted. The intact elbows rotated a meanof 3.6 degrees between the neutral position and the two-newton-metervalgus torque position. Cutting of the entire anterior bundlecaused an additional 3.2 degrees of rotation at 90 degrees offlexion, where the effect was greatest. CLINICAL RELEVANCE:Physical findings in a patient who has an injury of the anteriorbundle may be subtle, and an examination should be performedwith the elbow in 90 degrees of flexion for greatest sensitivity.As the anterior bundle is the major restraint to valgus rotation,reconstructive procedures should focus on anatomical reproductionof that structure. Parallel limbs of tendon graft placed fromthe inferior aspect of the medial epicondyle to the area ofthe sublimis tubercle will simulate the reciprocal bands ofthe anterior bundle. Temporary immobilization with the elbowin flexion may relax the critically important anterior bandof the reconstruction during healing.

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