A novel approach to predict core temperature during heat stress among firefighters

Q2 Health Professions Smart Health Pub Date : 2024-10-01 DOI:10.1016/j.smhl.2024.100518

Cory J. Coehoorn, Jonathan Teran, Patrick St Martin, Hannah Cowart, Kylie Dufrene

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Abstract

This study aimed to create a novel, non-invasive approach to predict core temperature (Tc) during heat stress among firefighters.

Background

The direct measure of Tc is typically performed through invasive techniques (rectal, esophageal, or intestinal). Existing predictive methods involve complex systems with multiple pieces of impractical equipment or are otherwise unsuitable for the work environment. Here, we hypothesized that a novel, non-invasive algorithm using variables collected from a single piece of commercially available equipment could effectively predict Tc.

Methods

The participants performed a steady-state exercise protocol in an environmental chamber (35 °C, 45% humidity) while donning firefighter personal protective equipment. The variables collected were skin temperature (Tsk), heart rate (HR), time, respiratory rate (RR), and rate of skin temperature acquisition per minute (Tsk/min).

Results

Of the variables collected, all contributed to the multiple regression model, except HR. Tsk/min was calculated using Tsk and time. The initial model created in this study predicted Tc with a standard error of the estimate (SEE) of 0.23 °C and an adjusted R² of 0.897. Following a "leave-one-out" bootstrap method, a robust equation was created using mean coefficients. This robust equation predicted Tc with a SEE of 0.23 and an R² of 0.902.

Discussion

This paper provides a practical, non-invasive model to predict Tc with minimal resources. This method has the potential to provide continuous monitoring of firefighters in the field and can be used as a metric to withdraw firefighters when under detrimental physiological stress. Ultimately, this could improve the health and longevity of firefighters.

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预测消防员热应激时核心体温的新方法

本研究旨在创建一种新颖的非侵入性方法，用于预测消防员在热应激期间的核心体温（Tc）。背景Tc的直接测量通常通过侵入性技术（直肠、食道或肠道）进行。现有的预测方法涉及复杂的系统和多个不实用的设备，或者不适合工作环境。在此，我们假设一种新颖的非侵入式算法，利用从单件市售设备收集的变量，可以有效预测 Tc。方法参与者穿戴消防员个人防护装备，在环境舱（35 °C，45% 湿度）中执行稳态运动方案。收集的变量包括皮肤温度（Tsk）、心率（HR）、时间、呼吸频率（RR）和每分钟皮肤温度采集率（Tsk/min）。Tsk/min 是通过 Tsk 和时间计算得出的。本研究创建的初始模型预测 Tc 的估计标准误差 (SEE) 为 0.23 °C，调整后的 R2 为 0.897。按照 "留一 "自举法，利用平均系数创建了一个稳健方程。该稳健方程预测 Tc 的 SEE 为 0.23，R2 为 0.902。这种方法有可能在现场对消防员进行连续监测，并可在消防员面临不利的生理压力时作为撤出消防员的指标。最终，这将改善消防员的健康状况并延长其寿命。

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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来源期刊

Smart Health Computer Science-Computer Science Applications

CiteScore

6.50

自引率

0.00%

发文量