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大鼠后肢卸载时的电阻抗变化。

Electrical impedance alterations in the rat hind limb with unloading.

作者信息

Li J, Spieker A J, Rosen G D, Rutkove S B

机构信息

Department of Neurology, Beth Israel Deaconess Medical Center, Harvard Medical School,USA.

出版信息

J Musculoskelet Neuronal Interact. 2013 Mar;13(1):37-44.

PMID:23445913
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3984464/
Abstract

OBJECTIVES

Methods are needed for quantifying muscle deconditioning due to immobilization, aging, or spaceflight. Electrical impedance myography (EIM) is one technique that may offer easy-to-follow metrics. Here, we evaluate the time course and character of the change in single- and multi-frequency EIM parameters in the hind-limb suspension model of muscle deconditioning in rats.

METHODS

Sixty-two rats were studied with EIM during a two-week period of hind limb unloading followed by a two-week recovery period. Random subsets of animals were sacrificed at one-week time intervals to measure muscle fiber size.

RESULTS

Significant alterations were observed in nearly all impedance parameters. The 50 kHz phase and multi-frequency phase-slope, created by taking the slope of a line fitted to the impedance values between 100-500 kHz, appeared most sensitive to disuse atrophy, the latter decreasing by over 33.0±6.6% (p<0.001), a change similar to the maximum reduction in muscle fiber size. Impedance alterations, however, lagged changes in muscle fiber size.

CONCLUSIONS

EIM is sensitive to disuse change in the rat, albeit with a delay relative to alterations in muscle fiber size. Given the rapidity and simplicity of EIM measurements, the technique could prove useful in providing a non-invasive approach to measuring disuse change in animal models and human subjects.

摘要

目的

需要有方法来量化因固定、衰老或太空飞行导致的肌肉失用性萎缩。电阻抗肌电图(EIM)是一种可能提供易于理解指标的技术。在此,我们评估大鼠肌肉失用性萎缩后肢悬吊模型中单频和多频EIM参数变化的时间进程和特征。

方法

62只大鼠在两周的后肢卸载期和随后两周的恢复期内接受EIM研究。以一周的时间间隔随机处死动物子集以测量肌纤维大小。

结果

几乎所有阻抗参数均观察到显著变化。50kHz相位和多频相位斜率(通过取拟合100 - 500kHz之间阻抗值的直线斜率得到)似乎对废用性萎缩最为敏感,后者下降超过33.0±6.6%(p<0.001),这一变化与肌纤维大小的最大减小相似。然而,阻抗变化滞后于肌纤维大小的变化。

结论

EIM对大鼠的废用性变化敏感,尽管相对于肌纤维大小的变化存在延迟。鉴于EIM测量的快速性和简便性,该技术可能在为测量动物模型和人类受试者的废用性变化提供一种非侵入性方法方面证明是有用的。

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