后十字韧带股骨足底的特定纤维区域是抵抗胫骨后部移位的主要因素:生物力学机器人研究。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Adrian Deichsel, Thorben Briese, Wenke Liu, Michael J Raschke, Alina Albert, Christian Peez, Andreas Weiler, Christoph Kittl
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引用次数: 0

摘要

目的:与前交叉韧带类似,后交叉韧带(PCL)的股足底由不同的纤维区域组成,可能具有不同的生物力学功能。本研究的目的是确定 PCL 股足底不同纤维区域在抑制胫骨后移(PTT)中的作用:方法:利用六自由度机器人测试装置,对八个新鲜冷冻的人体膝关节标本进行了连续切割研究。PCL 的股骨附着处被分为 15 个区域,这些区域按随机顺序依次从骨头上切割下来。在确定原始膝关节运动学特性后,执行了位移控制协议,重放原始运动,同时不断测量力。根据叠加原理,限制力的减少显示了每个切口的贡献百分比:结果:发现 PCL 在 0°、30°、60° 和 90°时对限制 PTT 的贡献率分别为 29 ± 16%、51 ± 24%、60 ± 22%和 55 ± 18%。贡献最大的纤维区域位于 PCL 脚印的近端边界,远离软骨,直接毗邻内侧髁间嵴(P 结论):研究发现,股骨 PCL 基底近端和后部的区域能显著抑制胫骨后部的力量。根据该测试设置的数据,在确定的区域植入 PCL 可能最能模拟原生 PCL 的部分,该部分在抵抗 PTT 力时承受的负荷最大:无证据级别(实验室研究)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Specific fibre areas in the femoral footprint of the posterior cruciate ligament act as a major contributor in resisting posterior tibial displacement: A biomechanical robotic investigation.

Purpose: Similar to the anterior cruciate ligament, the femoral footprint of the posterior cruciate ligament (PCL) is composed of different fibre areas, possibly having distinct biomechanical functions. The aim of this study was to determine the role of different fibre areas of the femoral footprint of the PCL in restraining posterior tibial translation (PTT).

Methods: A sequential cutting study was performed on eight fresh-frozen human knee specimens, utilizing a six-degrees-of-freedom robotic test setup. The femoral attachment of the PCL was divided into 15 areas, which were sequentially cut from the bone in a randomized sequence. After determining the native knee kinematics, a displacement-controlled protocol was performed replaying the native motion, while constantly measuring the force. The reduction of the restraining force presented the percentage contribution of each cut, according to the principle of superposition.

Results: The PCL was found to contribute 29 ± 16% in 0°, 51 ± 24% in 30°, 60 ± 22% in 60° and 55 ± 18% in 90°, to restricting a PTT. The fibre areas contributing the most were located at the proximal border of the PCL footprint, away from the cartilage, and directly adjacent to the medial intercondylar ridge (p < 0.05). Of these, one fibre area showed the highest contribution at all flexion angles. This area was located at the posterior half of the medial intercondylar ridge. No clear assignment of the areas to either the anterolateral or posteromedial bundle was possible.

Conclusion: An area towards the proximal and posterior part of the femoral PCL footprint was found to significantly restrain a posterior tibial force. Based on the data of this testing setup, a PCL graft positioned at the identified area may best mimic the part of the native PCL, which bears the most load in resisting a PTT force.

Level of evidence: No evidence level (laboratory study).

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CiteScore
7.20
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