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基于广义生物电阻抗的方程低估了运动员的体液量。

Generalized bioelectric impedance-based equations underestimate body fluids in athletes.

机构信息

Department of Biomedical Sciences for Health, Università degli Studi di Milano, Milan, Italy.

Department for Life Quality Studies, Università degli Studi di Bologna, Rimini, Italy.

出版信息

Scand J Med Sci Sports. 2021 Nov;31(11):2123-2132. doi: 10.1111/sms.14033. Epub 2021 Aug 19.

Abstract

The current study aimed: (i) to external validate total body water (TBW) and extracellular water (ECW) derived from athlete and non-athlete predictive equations using radioisotope dilution techniques as a reference criterion in male and female athletes; (ii) in a larger sample, to determine the agreement between specific and generalized equations when estimating body fluids in male and female athletes practicing different sports. A total of 1371 athletes (men: n = 921, age 23.9 ± 1.4 y; women: n = 450, age 27.3 ± 6.8 y) participated in this study. All athletes underwent bioelectrical impedance analyses, while TBW and ECW were assessed with dilution techniques in a subgroup of 185 participants (men: n = 132, age 21.7 ± 5.1 y; women: n = 53, age 20.3 ± 4.5 y). Two specific and eight generalized predictive equations were tested. Compared to the criterion methods, no mean bias was observed using the athlete-specific equations for TBW and ECW (-0.32 to 0.05, p > 0.05) and the coefficient of determination ranged from R  = 0.83 to 0.94. The majority of the generalized predictive equations underestimated TBW and ECW (p < 0.05); R ranged from 0.66 to 0.89. In the larger sample, all the generalized equations showed lower TBW and ECW values (ranging from -6.58 to -0.19, p < 0.05) than specific predictive equations; except for TBW in female power/velocity (one equation) athletes and team sport (two equations). The use of generalized BIA-based equations leads to an underestimation of TBW, and ECW compared to athlete-specific predictive equations. Additionally, the larger sample indicates that generalized equations overall provided lower TBW and ECW compared to the athlete-specific equations.

摘要

本研究旨在

(i) 使用放射性同位素稀释技术作为参考标准,在男性和女性运动员中验证源自运动员和非运动员预测方程的总体水(TBW)和细胞外液(ECW);(ii) 在更大的样本中,确定在估计不同运动项目的男性和女性运动员体液时,特定和通用方程之间的一致性。共有 1371 名运动员(男性:n=921,年龄 23.9±1.4 岁;女性:n=450,年龄 27.3±6.8 岁)参与了这项研究。所有运动员均接受了生物电阻抗分析,而在 185 名参与者的亚组中使用稀释技术评估了 TBW 和 ECW(男性:n=132,年龄 21.7±5.1 岁;女性:n=53,年龄 20.3±4.5 岁)。测试了两种特定和八种通用预测方程。与参考方法相比,使用 TBW 和 ECW 的运动员特定方程没有观察到平均偏差(-0.32 至 0.05,p>0.05),决定系数范围为 R=0.83 至 0.94。大多数通用预测方程低估了 TBW 和 ECW(p<0.05);R 值范围为 0.66 至 0.89。在更大的样本中,所有通用方程均显示 TBW 和 ECW 值较低(范围为-6.58 至-0.19,p<0.05),低于特定预测方程;女性力量/速度(一种方程)和团队运动(两种方程)运动员的 TBW 除外。与运动员特定预测方程相比,使用基于广义 BIA 的方程会导致 TBW 和 ECW 被低估。此外,更大的样本表明,与运动员特定方程相比,通用方程总体上提供了更低的 TBW 和 ECW。

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