Dealing with the heat: Assessing heat stress in an Arctic seabird using 3D-printed thermal models

IF 2.1 3区生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Comparative Biochemistry and Physiology A-Molecular & Integrative Physiology Pub Date : 2025-05-18 DOI:10.1016/j.cbpa.2025.111880

Fred Tremblay , Emily S. Choy , David A. Fifield , Glenn J. Tattersall , François Vézina , Ryan O'Connor , Oliver P. Love , Grant H. Gilchrist , Kyle H. Elliott

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引用次数: 0

Abstract

The Arctic is warming at four times the global average rate and most studies have focused on the indirect (e.g., changes in food web) rather than the direct effects of climate change. However, as Arctic animals often have low capacity to dissipate heat, the direct effect of warming could impact them significantly (heat stress). To study heat stress, biophysical models have been used in many species to estimate operative temperature (Te, integrated temperature of the thermal environment experienced by an individual). Here, we developed biophysical models of an Arctic seabird, the thick-billed murre (Uria lomvia). We demonstrated that 3D-printed painted models perform similarly to the more traditionally used feather-covered models. We deployed our models on Coats Island, Nunavut, Canada to study heat stress, which occurs in murres when operative temperature is above 21.2 °C (the temperature at which evaporative water loss (EWL) rates increase to maintain a constant body temperatures). Murre operative temperatures ranged from 5.5 °C to 46.5 °C despite ambient temperatures never exceeding 24.7 °C (range: 3.4–24.7 °C), and murres experienced heat stress on 61 % of the days during the breeding season (range: 24–85 %). Using known equations of EWL as a function of temperature, we estimated that murres lost 3.79 % to 4.61 % of their body mass in water daily. Our study confirms the physiological challenges faced by Arctic seabirds during the breeding season, while also demonstrating the value of biophysical models as non-invasive tools to study the effects of heat stress on seabirds.

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处理热量：使用3d打印热模型评估北极海鸟的热应力。

北极的变暖速度是全球平均速度的四倍，大多数研究都集中在气候变化的间接影响上（例如，食物网的变化），而不是直接影响。然而，由于北极动物的散热能力通常较低，气候变暖的直接影响可能会对它们产生重大影响（热应激）。为了研究热应激，生物物理模型已在许多物种中用于估计工作温度（Te，个体所经历的热环境的综合温度）。在这里，我们开发了一种北极海鸟的生物物理模型，厚嘴murre （Uria lomvia）。我们证明了3d打印的彩绘模型与传统上使用的羽毛覆盖模型相似。我们在加拿大努纳武特的Coats岛部署了我们的模型来研究热应激，当工作温度高于21.2 °C（蒸发失水（EWL）速率增加以保持恒定体温的温度）时，murres会发生热应激。尽管环境温度从未超过24.7 °C（范围：3.4-24.7 °C），但Murre的工作温度范围为5.5 °C至46.5 °C， Murre在繁殖季节有61 %的天数经历热应激（范围：24-85 %）。使用已知的EWL方程作为温度的函数，我们估计murres每天在水中损失3.79 %至4.61 %的体重。我们的研究证实了北极海鸟在繁殖季节面临的生理挑战，同时也证明了生物物理模型作为研究热应激对海鸟影响的非侵入性工具的价值。

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

Comparative Biochemistry and Physiology A-Molecular & Integrative Physiology 生物-动物学

CiteScore

5.00

自引率

4.30%

发文量

155

审稿时长

3 months

期刊介绍： Part A: Molecular & Integrative Physiology of Comparative Biochemistry and Physiology. This journal covers molecular, cellular, integrative, and ecological physiology. Topics include bioenergetics, circulation, development, excretion, ion regulation, endocrinology, neurobiology, nutrition, respiration, and thermal biology. Study on regulatory mechanisms at any level of organization such as signal transduction and cellular interaction and control of behavior are also published.