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主动躯干僵硬度随共同收缩而增加。

Active trunk stiffness increases with co-contraction.

作者信息

Lee Patrick J, Rogers Ellen L, Granata Kevin P

机构信息

Musculoskeletal Biomechanics Laboratories, Department of Engineering Science and Mechanics, School of Biomedical Engineering and Science, Virginia Polytechnic Institute and State University, 219 Norris Hall, 0219, Blacksburg, VA 24061, USA.

出版信息

J Electromyogr Kinesiol. 2006 Feb;16(1):51-7. doi: 10.1016/j.jelekin.2005.06.006. Epub 2005 Aug 15.

DOI:10.1016/j.jelekin.2005.06.006
PMID:16099678
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1635026/
Abstract

Trunk dynamics, including stiffness, mass and damping were quantified during trunk extension exertions with and without voluntary recruitment of antagonistic co-contraction. The objective of this study was to empirically evaluate the influence of co-activation on trunk stiffness. Muscle activity associated with voluntary co-contraction has been shown to increase joint stiffness in the ankle and elbow. Although biomechanical models assume co-active recruitment causes increase trunk stiffness it has never been empirically demonstrated. Small trunk displacements invoked by pseudorandom force disturbances during trunk extension exertions were recorded from 17 subjects at two co-contraction conditions (minimal and maximal voluntary co-contraction recruitment). EMG data were recorded from eight trunk muscles as a baseline measure of co-activation. Increased EMG activity confirms that muscle recruitment patterns were different between the two co-contraction conditions. Trunk stiffness was determined from analyses of impulse response functions (IRFs) of trunk dynamics wherein the kinematics were represented as a second-order behavior. Trunk stiffness increased 37.8% (p < 0.004) from minimal to maximal co-activation. Results support the assumption used in published models of spine biomechanics that recruitment of trunk muscle co-contraction increases trunk stiffness thereby supporting conclusions from those models that co-contraction may contribute to spinal stability.

摘要

在有和没有主动募集拮抗肌协同收缩的情况下,对躯干伸展运动过程中的躯干动力学进行了量化,包括刚度、质量和阻尼。本研究的目的是通过实验评估协同激活对躯干刚度的影响。与主动协同收缩相关的肌肉活动已被证明会增加踝关节和肘关节的关节刚度。尽管生物力学模型假设协同激活募集会导致躯干刚度增加,但从未有过实证证明。在两种协同收缩条件下(最小和最大主动协同收缩募集),记录了17名受试者在躯干伸展运动过程中由伪随机力干扰引起的小躯干位移。记录了八块躯干肌肉的肌电图数据,作为协同激活的基线测量。肌电图活动增加证实了两种协同收缩条件下的肌肉募集模式不同。通过对躯干动力学的脉冲响应函数(IRF)分析确定躯干刚度,其中运动学表现为二阶行为。从最小协同激活到最大协同激活,躯干刚度增加了37.8%(p < 0.004)。结果支持已发表的脊柱生物力学模型中使用的假设,即躯干肌肉协同收缩的募集会增加躯干刚度,从而支持这些模型得出的协同收缩可能有助于脊柱稳定性的结论。

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