An in-vitro study of rotator cuff tear and repair kinematics using single- and double-row suture anchor fixation

Kedgley, Angela E.; Shore, Benjamin J.; Athwal, George S.; Johnson, James A.; Faber, Kenneth J.

doi:10.4103/0973-6042.114224

Cited by 5 publications

(2 citation statements)

References 34 publications

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“…Ex vivo approaches offer the potential to measure these variables but are methodologically limited by the complex task of replicating in vivo behavior. Using GH simulators, Kedgley et al [ 11 , 12 ] found inferior GH translation with RC tears compared to intact shoulders, while other studies [ 13 , 14 , 15 ] reported superior GH translation with inactive RC muscles. Differences in experimental simulators may contribute to these discrepancies due to differences in muscle force application.…”

Section: Introductionmentioning

confidence: 99%

“…Differences in experimental simulators may contribute to these discrepancies due to differences in muscle force application. Kedgley et al's [ 11 , 12 ] simulator used a predetermined muscle force ratio based on healthy electromyography (EMG) patterns, whereas other simulators mimicked isotonic muscle contractions of RC muscles and controlled the DELT muscle force [ 13 , 15 , 16 , 17 ] or used uniformly distributed muscle forces that were determined iteratively [ 14 ]. Expanding on current GH simulators summarized in a recent scoping review [ 18 ], we developed a GH simulator that employs a musculoskeletal model-based control strategy that accounts for GH stability [ 19 ].…”

Section: Introductionmentioning

confidence: 99%

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Influence of Critical Shoulder Angle and Rotator Cuff Tear Type on Load‐Induced Glenohumeral Biomechanics: A Sawbone Simulator Study

Genter,

Croci,

Müller

et al. 2024

Applied Bionics and Biomechanics

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Glenohumeral (GH) biomechanics after rotator cuff (RC) tears are not fully understood. The purpose of our study was to determine if the critical shoulder angle (CSA), type of RC tears, and level of weight bearing increase GH translation, instability based on the instability ratio, muscle forces and joint reaction force (JRF), and shifts the center of force (CoF) superiorly. A GH simulator with muscle‐mimicking cable systems was used to simulate 30° abduction in the scapular plane. A Sawbone humerus and five specimen‐specific scapular anthropometries were used to test six types of RC tears, three weight‐bearing loads, and the native and adjusted (to different CSAs) deltoid origin sites. Linear mixed effects models (CSA, RC tear type, and weight bearing) with random effects (specimen and sex) were used to assess differences in GH biomechanics. With increasing CSA, GH translation increased, JRF decreased, and the CoF position was more inferior. RC tears did not significantly alter GH translation but shifted the CoF position superiorly, close to where glenoid erosion occurs in patients with RC tears with secondary osteoarthritis. Weight bearing significantly increased GH translation and JRF. RC and deltoid muscle forces increased with the presence of RC tears and increased weight bearing. The remaining RC muscles of intact tendons compensated for the torn RC tendons but not for the altered CoF position. GH translation remained comparable to shoulders with intact RC. These findings highlight the importance of early detection, clinical management, and targeted rehabilitation strategies for patients with RC tears.

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