Prediction of Core Body Temperature from Multiple Variables.

Annals of Occupational Hygiene Pub Date : 2015-11-01 Epub Date: 2015-08-12 DOI:10.1093/annhyg/mev054
Victoria L Richmond, Sarah Davey, Katy Griggs, George Havenith
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引用次数: 48

Abstract

This paper aims to improve the prediction of rectal temperature (T re) from insulated skin temperature (T is) and micro-climate temperature (T mc) previously reported (Richmond et al., Insulated skin temperature as a measure of core body temperature for individuals wearing CBRN protective clothing. Physiol Meas 2013; 34:1531-43.) using additional physiological and/or environmental variables, under several clothing and climatic conditions. Twelve male (25.8±5.1 years; 73.6±11.5kg; 178±6cm) and nine female (24.2±5.1 years; 62.4±11.5kg; 169±3cm) volunteers completed six trials, each consisting of two 40-min periods of treadmill walking separated by a 20-min rest, wearing permeable or impermeable clothing, under neutral (25°C, 50%), moderate (35°C, 35%), and hot (40°C, 25%) conditions, with and without solar radiation (600W m(-2)). Participants were measured for heart rate (HR) (Polar, Finland), skin temperature (T s) at 11 sites, T is (Grant, Cambridge, UK), and breathing rate (f) (Hidalgo, Cambridge, UK). T mc and relative humidity were measured within the clothing. T re was monitored as the 'gold standard' measure of T c for industrial or military applications using a 10cm flexible probe (Grant, Cambridge, UK). A stepwise multiple regression analysis was run to determine which of 30 variables (T is, T s at 11 sites, HR, f, T mc, temperature, and humidity inside the clothing front and back, body mass, age, body fat, sex, clothing, Thermal comfort, sensation and perception, and sweat rate) were the strongest on which to base the model. Using a bootstrap methodology to develop the equation, the best model in terms of practicality and validity included T is, T mc, HR, and 'work' (0 = rest; 1 = exercise), predicting T re with a standard error of the estimate of 0.27°C and adjusted r (2) of 0.86. The sensitivity and specificity for predicting individuals who reached 39°C was 97 and 85%, respectively. Insulated skin temperature was the most important individual parameter for the prediction of T re. This paper provides novel information about the viability of predicting T c under a wide range of conditions, using predictors which can practically be measured in a field environment.

多变量预测核心体温。
本文旨在改进先前报道的(Richmond等人)通过绝缘皮肤温度(T is)和微气候温度(T mc)对直肠温度(T re)的预测,将绝缘皮肤温度作为穿着CBRN防护服个体的核心体温的度量。物理学报,2013;34:1531-43.),在不同的服装和气候条件下,使用额外的生理和/或环境变量。男性12例(25.8±5.1岁);73.6±11.5公斤;178±6cm),女性9例(24.2±5.1岁);62.4±11.5公斤;169±3cm)的志愿者完成了六项试验,每项试验包括两次40分钟的跑步机行走,间隔20分钟的休息,穿着透水或不透水的衣服,在中性(25°C, 50%)、中等(35°C, 35%)和高温(40°C, 25%)条件下,有和没有太阳辐射(600W m(-2))。研究人员测量了参与者的心率(HR) (Polar,芬兰)、11个部位的皮肤温度(T s)、T is (Grant, Cambridge, UK)和呼吸频率(f) (Hidalgo, Cambridge, UK)。测量衣物内的温度和相对湿度。在工业或军事应用中,使用10cm柔性探针监测tre,作为tc的“黄金标准”测量(Grant, Cambridge, UK)。采用逐步多元回归分析确定30个变量(T is, 11个部位的T s, HR, f, T mc,衣服前后的温度和湿度,体重,年龄,体脂,性别,衣服,热舒适,感觉和知觉,出汗率)中哪一个是最强的模型基础。使用bootstrap方法开发方程,就实用性和有效性而言,最佳模型包括T is, T mc, HR和'work' (0 = rest;1 = exercise),预测tre的估计标准误差为0.27°C,调整后的r(2)为0.86。预测个体达到39°C的敏感性和特异性分别为97%和85%。隔热皮肤温度是预测温度的最重要的单个参数。本文提供了关于在广泛条件下预测温度可行性的新信息,使用可以在现场环境中实际测量的预测器。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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