BACKGROUND: Allowing for humeral external rotation while loading rotator cuff repairs has been shown to affect tendon biomechanics when compared with testing with the humerus fixed. Adding dynamic external rotation to a tendon-loading model using footprint-restoring repairs may improve our understanding of rotator cuff repair response to a common postoperative motion. HYPOTHESIS: A tendon suture-bridging repair will demonstrate better load sharing compared to a double-row repair, and there will be a differential gap formation between the anterior and posterior tendon regions. STUDY DESIGN: Controlled laboratory study. METHODS: In 6 fresh-frozen human cadaveric shoulders, a tendon suture-bridging rotator cuff repair was performed; a suture limb from each of 2 medial anchors was bridged over the tendon and fixed laterally with an interference screw. In 6 contralateral match-paired specimens, a double-row repair was performed. For all specimens, a custom jig was employed that allowed dynamic external rotation (0 degrees to 30 degrees ) with loading. A materials testing machine was used to cyclically load each repair from 0 N to 90 N for 30 cycles; each repair was then loaded to failure. A deformation rate of 1 mm/s was employed for all tests. Gap formation between tendon edge and insertion was measured using video digitizing software. RESULTS: The yield load for the suture-bridging technique (161.88 +/- 35.09 N) was significantly larger than the double-row technique (135.17 +/- 24.03 N) (P = .026). The yield gap between tendon and lateral footprint was significantly greater anteriorly than posteriorly (1.62 +/- 0.82 mm and 0.68 +/- 0.47 mm, respectively) for the suture-bridging technique (P = .024) but not for the double-row technique (1.35 +/- 0.52 mm and 1.05 +/- 0.50 mm, respectively) (P = .34). There were no differences for gap formation, stiffness, ultimate load to failure, and energy absorbed to failure between the 2 repairs (P > .05). The anterior regions of the repair were the first to fail in all constructs. The suture-bridging repair remained interconnected for 5 of 6 repairs. CONCLUSIONS: The tendon suture-bridging rotator cuff repair has a yield load that is higher than the double-row repair when allowing for external rotation during load testing. External rotation can accentuate gap formation anteriorly at a repaired rotator cuff footprint. CLINICAL RELEVANCE: Based on the tension of repair, there may be a role for reinforcing the repair anteriorly and limiting external rotation postoperatively.
BACKGROUND: Allowing for humeral external rotation while loading rotator cuff repairs has been shown to affect tendon biomechanics when compared with testing with the humerus fixed. Adding dynamic external rotation to a tendon-loading model using footprint-restoring repairs may improve our understanding of rotator cuff repair response to a common postoperative motion. HYPOTHESIS: A tendon suture-bridging repair will demonstrate better load sharing compared to a double-row repair, and there will be a differential gap formation between the anterior and posterior tendon regions. STUDY DESIGN: Controlled laboratory study. METHODS: In 6 fresh-frozen human cadaveric shoulders, a tendon suture-bridging rotator cuff repair was performed; a suture limb from each of 2 medial anchors was bridged over the tendon and fixed laterally with an interference screw. In 6 contralateral match-paired specimens, a double-row repair was performed. For all specimens, a custom jig was employed that allowed dynamic external rotation (0 degrees to 30 degrees ) with loading. A materials testing machine was used to cyclically load each repair from 0 N to 90 N for 30 cycles; each repair was then loaded to failure. A deformation rate of 1 mm/s was employed for all tests. Gap formation between tendon edge and insertion was measured using video digitizing software. RESULTS: The yield load for the suture-bridging technique (161.88 +/- 35.09 N) was significantly larger than the double-row technique (135.17 +/- 24.03 N) (P = .026). The yield gap between tendon and lateral footprint was significantly greater anteriorly than posteriorly (1.62 +/- 0.82 mm and 0.68 +/- 0.47 mm, respectively) for the suture-bridging technique (P = .024) but not for the double-row technique (1.35 +/- 0.52 mm and 1.05 +/- 0.50 mm, respectively) (P = .34). There were no differences for gap formation, stiffness, ultimate load to failure, and energy absorbed to failure between the 2 repairs (P > .05). The anterior regions of the repair were the first to fail in all constructs. The suture-bridging repair remained interconnected for 5 of 6 repairs. CONCLUSIONS: The tendon suture-bridging rotator cuff repair has a yield load that is higher than the double-row repair when allowing for external rotation during load testing. External rotation can accentuate gap formation anteriorly at a repaired rotator cuff footprint. CLINICAL RELEVANCE: Based on the tension of repair, there may be a role for reinforcing the repair anteriorly and limiting external rotation postoperatively.
Authors: Olaf Lorbach; Mike H Baums; Tanja Kostuj; Stephan Pauly; Markus Scheibel; Andrew Carr; Nasim Zargar; Maristella F Saccomanno; Giuseppe Milano Journal: Knee Surg Sports Traumatol Arthrosc Date: 2015-01-09 Impact factor: 4.342
Authors: Mirco Sgroi; Thomas Kappe; Marius Ludwig; Michael Fuchs; Daniel Dornacher; Heiko Reichel; Anita Ignatius; Lutz Dürselen; Anne Seywald; Andreas Martin Seitz Journal: Clin Orthop Relat Res Date: 2022-03-01 Impact factor: 4.755
Authors: Frank McCormick; Anil Gupta; Ben Bruce; Josh Harris; Geoff Abrams; Hillary Wilson; Kristen Hussey; Brian J Cole Journal: Int J Shoulder Surg Date: 2014-01