使用解释性生物电阻抗模型估算健康受试者和肌肉减少症患者的局部 lean 肌肉量。

Lean regional muscle volume estimates using explanatory bioelectrical models in healthy subjects and patients with muscle wasting.

机构信息

Institute of Myology, Neuromuscular Investigation Center, Neuromuscular Physiology and Evaluation Laboratory, Paris, France.

Institute of Myology, Neuromuscular Investigation Center, NMR Laboratory, Paris, France.

出版信息

J Cachexia Sarcopenia Muscle. 2021 Feb;12(1):39-51. doi: 10.1002/jcsm.12656. Epub 2020 Dec 29.

DOI:10.1002/jcsm.12656

PMID:33377299

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7890267/

Abstract

BACKGROUND

The availability of non-invasive, accessible, and reliable methods for estimating regional skeletal muscle volume is paramount in conditions involving primary and/or secondary muscle wasting. This work aimed at (i) optimizing serial bioelectrical impedance analysis (S ) by computing a conductivity constant based on quantitative magnetic resonance imaging (MRI) data and (ii) investigating the potential of S for estimating lean regional thigh muscle volume in patients with severe muscle disorders.

METHODS

Twenty healthy participants with variable body mass index and 20 patients with idiopathic inflammatory myopathies underwent quantitative MRI. Anatomical images and fat fraction maps were acquired in thighs. After manual muscle segmentation, lean thigh muscle volume (lV ) was computed. Subsequently, multifrequency (50 to 350 kHz) serial resistance profiles were acquired between current skin electrodes (i.e. ankle and hand) and voltage electrodes placed on the anterior thigh. In vivo values of the muscle electrical conductivity constant were computed using data from S and MRI gathered in the right thigh of 10 healthy participants. Lean muscle volume (lV ) was derived from S measurements using this newly computed constant. Between-day reproducibility of lV was studied in six healthy participants.

RESULTS

Electrical conductivity constant values ranged from 0.82 S/m at 50 kHz to 1.16 S/m at 350 kHz. The absolute percentage difference between lV and lV was greater at frequencies >270 kHz (P < 0.0001). The standard error of measurement and the intra-class correlation coefficient for lV computed from measurements performed at 155 kHz (i.e. frequency with minimal difference) against lV were 6.1% and 0.95 in healthy participants and 9.4% and 0.93 in patients, respectively. Between-day reproducibility of lV was as follows: standard error of measurement = 4.6% (95% confidence interval [3.2, 7.8] %), intra-class correlation coefficient = 0.98 (95% confidence interval [0.95, 0.99]).

CONCLUSIONS

These findings demonstrate a strong agreement of lean muscle volume estimated using S against quantitative MRI in humans, including in patients with severe muscle wasting and fatty degeneration. S shows promises for non-invasive, fast, and accessible estimation and follow-up of lean regional skeletal muscle volume for transversal and longitudinal studies.

摘要

背景

在原发性和/或继发性肌肉减少症中，寻找无创、可及且可靠的方法来评估区域性骨骼肌容积至关重要。本研究旨在（i）通过基于定量磁共振成像（MRI）数据计算电导率常数来优化串联生物电阻抗分析（S ），（ii）研究 S 用于估计严重肌肉疾病患者的大腿瘦肌肉区域容积的潜力。

方法

20 名健康志愿者（BMI 不同）和 20 名特发性炎症性肌病患者接受定量 MRI 检查。大腿采集解剖图像和脂肪分数图。手动肌肉分割后，计算出瘦大腿肌肉体积（lV ）。随后，在电流皮肤电极（即脚踝和手部）和放置在前大腿上的电压电极之间获取多频（50 至 350 kHz）串联电阻曲线。使用 10 名健康参与者右侧大腿的 S 和 MRI 数据，计算出肌肉电导率常数的体内值。使用新计算出的常数，从 S 测量值中推导出瘦肌肉体积（lV ）。在 6 名健康参与者中研究了 lV 的日内重复性。

结果

电导率常数值范围为 50 kHz 时为 0.82 S/m，350 kHz 时为 1.16 S/m。lV 和 lV 之间的绝对百分比差异在>270 kHz 时更大（P < 0.0001）。在健康参与者中，使用 155 kHz（即差异最小的频率）测量的 lV 与 lV 计算的测量误差和组内相关系数分别为 6.1%和 0.95，在患者中分别为 9.4%和 0.93。lV 的日内重复性如下：测量误差标准误差=4.6%（95%置信区间[3.2，7.8]%），组内相关系数=0.98（95%置信区间[0.95，0.99]）。

结论

这些发现表明，在人类中，使用 S 估计的瘦肌肉体积与定量 MRI 具有很强的一致性，包括在严重肌肉减少和脂肪变性的患者中。S 有望用于非侵入性、快速和可及的估计和随访横断和纵向研究中的瘦区域性骨骼肌体积。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8641/7890267/a144891f941f/JCSM-12-39-g001.jpg

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使用解释性生物电阻抗模型估算健康受试者和肌肉减少症患者的局部 lean 肌肉量。

Lean regional muscle volume estimates using explanatory bioelectrical models in healthy subjects and patients with muscle wasting.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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