行走过程中膝关节处的肌肉、韧带及关节接触力。

Muscle, ligament, and joint-contact forces at the knee during walking.

作者信息

Shelburne Kevin B, Torry Michael R, Pandy Marcus G

机构信息

Steadman-Hawkins Research Foundation, Biomechanics Research Laboratory, Vail, CO 81657, USA.

出版信息

Med Sci Sports Exerc. 2005 Nov;37(11):1948-56. doi: 10.1249/01.mss.0000180404.86078.ff.

DOI:10.1249/01.mss.0000180404.86078.ff

PMID:16286866

Abstract

PURPOSE

In vivo measurement of the forces and strains in human tissues is currently impracticable. Computer modeling and simulation allows estimates of these quantities to be obtained noninvasively. This paper reviews our recent work on muscle, ligament, and joint loading at the knee during gait.

METHODS

Muscle and ground-reaction forces obtained from a sophisticated computer simulation of walking were input into a detailed model of the lower limb to obtain ligament and joint-contact loading at the knee for one full cycle of gait.

RESULTS

Peak anterior cruciate ligament (ACL) force occurred in early stance and was mainly determined by the anterior pull of the patellar tendon on the tibia. The medial collateral ligament was the primary restraint to anterior tibial translation (ATT) in the ACL-deficient knee. ATT in the ACL-deficient knee can be reduced to the level calculated for the intact knee by increasing hamstrings muscle force. Reducing quadriceps force was insufficient to restore ATT to the level calculated for the intact knee. For both normal and ACL-deficient walking, the resultant force acting between the femur and tibia remained mainly on the medial side of the knee. The knee adductor moment was resisted by a combination of muscle and ligament forces.

CONCLUSION

Knee-ligament loading during the stance phase of gait is explained by the pattern of anterior shear force applied to the leg. The distribution of force at the tibiofemoral joint is determined by the variation in the external adductor moment applied at the knee. The forces acting at the tibiofemoral and patellofemoral joints are similar during normal and ACL-deficient gait. Hamstrings facilitation is more effective than quadriceps avoidance in reducing ATT during ACL-deficient gait.

摘要

目的

目前，对人体组织中的力和应变进行体内测量是不切实际的。计算机建模与模拟使得能够通过非侵入性方式获得这些量的估计值。本文回顾了我们最近关于步态期间膝关节处肌肉、韧带和关节负荷的研究工作。

方法

将从复杂的步行计算机模拟中获得的肌肉力和地面反作用力输入到下肢的详细模型中，以获取一个完整步态周期中膝关节处的韧带和关节接触负荷。

结果

前交叉韧带（ACL）的峰值力出现在站立初期，主要由髌腱对胫骨的前向拉力决定。在ACL缺失的膝关节中，内侧副韧带是限制胫骨前移（ATT）的主要结构。通过增加绳肌力量，ACL缺失膝关节的ATT可降低至完整膝关节计算出的水平。降低股四头肌力量不足以将ATT恢复到完整膝关节计算出的水平。对于正常和ACL缺失的步行，作用于股骨和胫骨之间的合力主要仍位于膝关节内侧。膝关节内收力矩由肌肉和韧带力共同抵抗。

结论

步态站立期膝关节韧带负荷可通过施加于腿部的前向剪切力模式来解释。胫股关节处的力分布由膝关节处施加的外部内收力矩变化决定。在正常和ACL缺失的步态中，作用于胫股关节和髌股关节的力相似。在ACL缺失的步态中，促进绳肌比避免股四头肌发力在降低ATT方面更有效。

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行走过程中膝关节处的肌肉、韧带及关节接触力。

Muscle, ligament, and joint-contact forces at the knee during walking.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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