Steadman Philippon Research Institute, Vail, Colorado, USA.
Oslo University Hospital and University of Oslo, Oslo, Norway.
Am J Sports Med. 2018 May;46(6):1352-1361. doi: 10.1177/0363546518759053. Epub 2018 Mar 20.
The individual kinematic roles of the anterolateral ligament (ALL) and the distal iliotibial band Kaplan fibers in the setting of anterior cruciate ligament (ACL) deficiency require further clarification. This will improve understanding of their potential contribution to residual anterolateral rotational laxity after ACL reconstruction and may influence selection of an anterolateral extra-articular reconstruction technique, which is currently a matter of debate. Hypothesis/Purpose: To compare the role of the ALL and the Kaplan fibers in stabilizing the knee against tibial internal rotation, anterior tibial translation, and the pivot shift in ACL-deficient knees. We hypothesized that the Kaplan fibers would provide greater tibial internal rotation restraint than the ALL in ACL-deficient knees and that both structures would provide restraint against internal rotation during a simulated pivot-shift test.
Controlled laboratory study.
Ten paired fresh-frozen cadaveric knees (n = 20) were used to investigate the effect of sectioning the ALL and the Kaplan fibers in ACL-deficient knees with a 6 degrees of freedom robotic testing system. After ACL sectioning, sectioning was randomly performed for the ALL and the Kaplan fibers. An established robotic testing protocol was utilized to assess knee kinematics when the specimens were subjected to a 5-N·m internal rotation torque (0°-90° at 15° increments), a simulated pivot shift with 10-N·m valgus and 5-N·m internal rotation torque (15° and 30°), and an 88-N anterior tibial load (30° and 90°).
Sectioning of the ACL led to significantly increased tibial internal rotation (from 0° to 90°) and anterior tibial translation (30° and 90°) as compared with the intact state. Significantly increased internal rotation occurred with further sectioning of the ALL (15°-90°) and Kaplan fibers (15°, 60°-90°). At higher flexion angles (60°-90°), sectioning the Kaplan fibers led to significantly greater internal rotation when compared with ALL sectioning. On simulated pivot-shift testing, ALL sectioning led to significantly increased internal rotation and anterior translation at 15° and 30°; sectioning of the Kaplan fibers led to significantly increased tibial internal rotation at 15° and 30° and anterior translation at 15°. No significant difference was found when anterior tibial translation was compared between the ACL/ALL- and ACL/Kaplan fiber-deficient states on simulated pivot-shift testing or isolated anterior tibial load.
The ALL and Kaplan fibers restrain internal rotation in the ACL-deficient knee. Sectioning the Kaplan fibers led to greater tibial internal rotation at higher flexion angles (60°-90°) as compared with ALL sectioning. Additionally, the ALL and Kaplan fibers contribute to restraint of the pivot shift and anterior tibial translation in the ACL-deficient knee.
This study reports that the ALL and distal iliotibial band Kaplan fibers restrain anterior tibial translation, internal rotation, and pivot shift in the ACL-deficient knee. Furthermore, sectioning the Kaplan fibers led to significantly greater tibial internal rotation when compared with ALL sectioning at high flexion angles. These results demonstrate increased rotational knee laxity with combined ACL and anterolateral extra-articular knee injuries and may allow surgeons to optimize the care of patients with this injury pattern.
前交叉韧带(ACL)缺失时,前外侧韧带(ALL)和阔筋膜张肌 Kaplan 纤维的个体运动学作用需要进一步阐明。这将有助于更好地理解它们对 ACL 重建后残余前外侧旋转松弛的潜在贡献,并可能影响到目前存在争议的前外侧关节外重建技术的选择。假说/目的:比较 ACL 缺失膝关节中 ALL 和 Kaplan 纤维在稳定膝关节对抗胫骨内旋、胫骨前移和前抽屉试验中的作用。我们假设在 ACL 缺失的膝关节中,Kaplan 纤维比 ALL 提供更大的胫骨内旋约束,并且这两种结构在模拟前抽屉试验中都会提供对内旋的约束。
对照实验室研究。
使用六个自由度机器人测试系统研究 ACL 缺失膝关节中切断 ALL 和 Kaplan 纤维的效果。ACL 切断后,随机进行 ALL 和 Kaplan 纤维的切断。利用已建立的机器人测试方案,评估标本在以下情况下的膝关节运动学:施加 5-N·m 的内旋扭矩(0°-90°,每隔 15°递增),施加 10-N·m 的外翻和 5-N·m 的内旋扭矩(15°和 30°)模拟前抽屉试验,以及施加 88-N 的胫骨前负荷(30°和 90°)。
与完整状态相比,ACL 切断导致胫骨内旋(0°-90°)和胫骨前移(30°和 90°)显著增加。进一步切断 ALL(15°-90°)和 Kaplan 纤维(15°、60°-90°)会导致更大的内旋。在较高的屈曲角度(60°-90°)下,切断 Kaplan 纤维会导致比切断 ALL 纤维更大的内旋。在前抽屉试验模拟中,切断 ALL 会导致在 15°和 30°时内旋和胫骨前移显著增加;切断 Kaplan 纤维会导致在 15°和 30°时胫骨内旋和胫骨前移显著增加。在前抽屉试验模拟或单独的胫骨前负荷中,ACL/ALL 缺陷状态和 ACL/Kaplan 纤维缺陷状态之间的胫骨前平移没有显著差异。
ALL 和 Kaplan 纤维限制 ACL 缺失膝关节的内旋。与切断 ALL 相比,在较高的屈曲角度(60°-90°)下,切断 Kaplan 纤维会导致更大的胫骨内旋。此外,ALL 和 Kaplan 纤维有助于限制 ACL 缺失膝关节的前抽屉试验和胫骨前平移。
本研究报告 ALL 和阔筋膜张肌远端髂胫束 Kaplan 纤维限制 ACL 缺失膝关节的胫骨前移、内旋和前抽屉试验。此外,与切断 ALL 相比,在较高的屈曲角度(60°-90°)下,切断 Kaplan 纤维会导致更大的胫骨内旋。这些结果表明,ACL 和前外侧关节外膝关节损伤会导致旋转膝关节松弛增加,这可能使外科医生能够优化对这种损伤模式患者的治疗。
