Sene K. Polamalu scite author profile

Statistical shape modeling was employed to assess three‐dimensional (3D) bony morphology between distal femurs and proximal tibiae of anterior cruciate ligament (ACL) injured knees, the contralateral uninjured knees of ACL injured subjects, and knees with no history of injury. Surface models were created by segmenting bone from bilateral computed‐tomography scans of 20 subjects of their ACL injured knees and non‐injured contralateral knees, and 20 knees of control subjects with no history of a knee injury. Correspondence particles were placed on each surface, and a principal component analysis determined modes of variation in the positions of the correspondence particles describing anatomical variation. ANOVAs assessed the statistical differences of 3D bony morphological features with main effects of injury state and sex. ACL injured knees were determined to have a more lateral femoral mechanical axis and a greater angle between the long axis and condylar axis of the femur. A smaller anterior–posterior dimension of the lateral tibial plateau was also associated with ACL injured knees. Results of this study demonstrate that there are more bony morphological features predisposing individuals for ACL injury than previously established. These bony morphological parameters may cause greater internal and valgus torques increasing stresses in the ACL. No differences were determined between the ACL injured knees and their uninjured contralateral knees demonstrating that knees of ACL injured individuals are at similar risk for injury. Further understanding of the effect of bony morphology on the risk for ACL injury could improve individualized ACL injury treatment and prevention.

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Increasing the posterior tibial slope lowers in situ forces in the native ACL primarily at deep flexion angles

Winkler

Chan

Lucidi

et al. 2022

Journal Orthopaedic Research

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High tibial osteotomy is becoming increasingly popular but can be associated with unintentional posterior tibial slope (PTS) increase and subsequent anterior cruciate ligament (ACL) degeneration. This study quantified the effect of increasing PTS on knee kinematics and in situ forces in the native ACL. A robotic testing system was used to apply external loads from full extension to 90°flexion to seven human cadaveric knees:(1) 200 N axial compressive load, (2) 5 Nm internal tibial + 10 Nm valgus torque, and (3) 5 Nm external tibial + 10 Nm varus torque. Kinematics and in situ forces in the ACL were acquired for the native and increased PTS state. Increasing PTS resulted in increased anterior tibial translation at 30°(1.8 mm), 60°(1.7 mm), and 90°(0.9 mm) flexion and reduced in situ force in the ACL at 30°(57.6%), 60°(69.8%), and 90°(75.0%) flexion in response to 200 N axial compressive load. In response to 5 Nm internal tibial + 10 Nm valgus torque, there was significantly less (39.

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Knee Lateral Extra-articular Tenodesis Decreases In-situ Force in the ACL

Arner¹,

Novaretti²,

Chan³

et al. 2019

Arthroscopy: The Journal of Arthroscopic & Related Surgery

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Biomechanics of Ligaments

Hughes

Chan

Polamalu

et al. 2021

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Sene K. Polamalu

Does Lateral Extra-articular Tenodesis of the Knee Affect Anterior Cruciate Ligament Graft In Situ Forces and Tibiofemoral Contact Pressures?

Tibiofemoral bony morphology features associated with ACL injury and sex utilizing three‐dimensional statistical shape modeling

Increasing the posterior tibial slope lowers in situ forces in the native ACL primarily at deep flexion angles

Knee Lateral Extra-articular Tenodesis Decreases In-situ Force in the ACL

Biomechanics of Ligaments

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