使用结构性生物诱导支架进行增强型尺侧副韧带修复:生物力学研究

Kenneth M. Lin, Kenneth Brinson, Ran Atzmon, Calvin K. Chan, Seth L. Sherman, Marc R. Safran, Michael T. Freehill
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The order of testing of repair states was alternated to account for possible plastic deformation during testing.Results:The UCL-transected state showed the greatest increase in valgus gapping of all states at all flexion angles. Repair alone showed similar valgus gapping to that of the UCL-transected state at 30° ( P = .62) and 60° of flexion ( P = .11). Bioinductive absorbable scaffold–augmented repair showed less valgus gapping compared with repair alone at all flexion angles ( P = .021, P = .024, and P = .024 at 30°, 60°, and 90°, respectively). Scaffold-augmented repair showed greater gapping compared with the native state at 30° ( P = .021) and 90° ( P = .039) but not at 60° of flexion ( P = .059). There was no difference when testing augmented repair or repair alone first.Conclusion:UCL repair augmented with a bioinductive, biocomposite absorbable structural scaffold imparts additional biomechanical strength to UCL repair alone, without overconstraint beyond the native state. 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引用次数: 0

摘要

背景:与 UCL 重建相比,使用缝合支架增强进行肘关节尺侧韧带(UCL)修复显示出良好的时间零生物力学强度,并能更快地恢复比赛。然而,人们对非吸收性缝合带的过度约束或应力屏蔽表示担忧。最近,一种基于胶原蛋白的生物诱导可吸收结构支架获得了美国食品药品管理局的批准,可用于增强软组织修复。我们假设,在初级 UCL 修复中添加生物诱导性可吸收结构支架将对外翻开口产生额外的零时抑制作用。研究设计:对照实验室研究。方法:使用 8 个尸体肘部标本--从前臂中部到肱骨中部。在原始状态下,肘关节在屈曲30o、60o和90o时进行外翻应力测试,并施加周期性的外翻旋转扭矩。从2-到5-N-m扭矩的外翻旋转变化被记录为外翻间隙。然后在 4 种状态下进行测试:(1) 原生完整 UCL--通过皮肤、筋膜和肌肉解剖至完整的 UCL 复合体;(2) UCL 切断--韧带在近端结节外侧横断;(3) 使用生物诱导可吸收支架进行增强修复;(4) 单独修复,不使用支架。为了考虑测试过程中可能出现的塑性变形,对修复状态的测试顺序进行了交替。结果:在所有状态中,UCL横断状态在所有屈曲角度下的外翻间隙增加最大。在屈曲30°(P = .62)和60°(P = .11)时,单纯修复与UCL横断状态的外翻间隙相似。在所有屈曲角度下,生物诱导性可吸收支架增强修复与单独修复相比都显示出较小的外翻间隙(在30°、60°和90°时分别为P = .021、P = .024和P = .024)。在 30° (P = 0.021)和 90° (P = 0.039)时,与原生状态相比,脚手架增强修复显示出更大的间隙,但在屈曲 60° 时没有显示出更大的间隙(P = 0.059)。结论:使用生物诱导性生物复合可吸收结构支架增强 UCL 修复与单纯 UCL 修复相比具有更高的生物力学强度,而不会产生超出原生状态的过度约束。临床意义:随着增强型初级 UCL 修复术越来越普遍,使用可吸收生物诱导支架可提高零时机械强度,从而更快地康复,同时避免长期过度约束或应力屏蔽。
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Augmented Ulnar Collateral Ligament Repair With Structural Bioinductive Scaffold: A Biomechanical Study
Background:Elbow ulnar collateral ligament (UCL) repair with suture brace augmentation shows good time-zero biomechanical strength and a more rapid return to play compared with UCL reconstruction. However, there are concerns about overconstraint or stress shielding with nonabsorbable suture tape. Recently, a collagen-based bioinductive absorbable structural scaffold has been approved by the Food and Drug Administration for augmentation of soft tissue repair.Purpose/Hypothesis:This study aimed to assess the initial biomechanical performance of UCL repair augmented with this scaffold. We hypothesized that adding the bioinductive absorbable structural scaffold to primary UCL repair would impart additional time-zero restraint to the valgus opening.Study Design:Controlled laboratory study.Methods:Eight cadaveric elbow specimens—from midforearm to midhumerus—were utilized. In the native state, elbows underwent valgus stress testing at 30o, 60o, and 90o of flexion, with a cyclical valgus rotational torque. Changes in valgus rotation from 2- to 5-N·m torque were recorded as valgus gapping. Testing was then performed in 4 states: (1) native intact UCL—with dissection through skin, fascia, and muscle down to an intact UCL complex; (2) UCL-transected—distal transection of the ligament off the sublime tubercle; (3) augmented repair with bioinductive absorbable scaffold; and (4) repair alone without scaffold. The order of testing of repair states was alternated to account for possible plastic deformation during testing.Results:The UCL-transected state showed the greatest increase in valgus gapping of all states at all flexion angles. Repair alone showed similar valgus gapping to that of the UCL-transected state at 30° ( P = .62) and 60° of flexion ( P = .11). Bioinductive absorbable scaffold–augmented repair showed less valgus gapping compared with repair alone at all flexion angles ( P = .021, P = .024, and P = .024 at 30°, 60°, and 90°, respectively). Scaffold-augmented repair showed greater gapping compared with the native state at 30° ( P = .021) and 90° ( P = .039) but not at 60° of flexion ( P = .059). There was no difference when testing augmented repair or repair alone first.Conclusion:UCL repair augmented with a bioinductive, biocomposite absorbable structural scaffold imparts additional biomechanical strength to UCL repair alone, without overconstraint beyond the native state. Further comparative studies are warranted.Clinical Relevance:As augmented primary UCL repair becomes more commonly performed, use of an absorbable bioinductive scaffold may allow for improved time-zero mechanical strength, and thus more rapid rehabilitation, while avoiding long-term overconstraint or stress shielding.
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Thank You, Reviewers! Strengthening the Evidence: Addressing Biases in Anterior Cruciate Ligament Reconstruction Studies: Response Strengthening the Evidence: Addressing Biases in Anterior Cruciate Ligament Reconstruction Studies: Letter to the Editor In Gratitude Presidential Address of the American Orthopaedic Society for Sports Medicine
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