HOUSING TEMPERATURE ALTERS BURN INDUCED HYPERMETABOLISM IN MICE.

IF 2.7 3区医学 Q2 CRITICAL CARE MEDICINE

SHOCK Pub Date : 2024-10-18 DOI:10.1097/SHK.0000000000002476

Meagan Scott Kingren, Jaycelyn Starr Hall, Taylor Joseph Ross T, Mary Claire Barre, Abigail Barlow, Martin Morales, Lillie Danielle Treas L, Robert Todd Maxson, Esther Teo, Craig Porter

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引用次数: 0

Abstract

Abstract: Mice used in biomedical research are typically housed at ambient temperatures (22-24 °C) below thermoneutrality (26-31 °C). This chronic cold stress triggers a hypermetabolic response that may limit the utility of mice in modeling hypermetabolism in response to burns. To evaluate the effect of housing temperature on burn-induced hypermetabolism, mice were randomly assigned to receive sham, small, or large scald burns. Mice recovered for 21 days in metabolic phenotyping cages at 24 °C or 30 °C. Regardless of sex or sham/burn treatment, mice housed at 24 °C had greater total energy expenditure (TEE, P < 0.001), which was largely attributable to greater basal energy expenditure (BEE) when compared to mice housed at 30 °C (P < 0.001). Thermoneutral housing (30 °C) altered adipose tissue mass in a sex-dependent manner. Compared to sham and small burn groups, large burns resulted in greater water vapor loss, regardless of housing temperature (P < 0.01). Compared to sham, large burns resulted in greater BEE and TEE in mice housed at 24 °C, however, this hypermetabolic response to large burns was blunted in female mice housed at 30 °C, and absent in male mice housed at 30 °C. Locomotion was significantly reduced in mice with large burns compared to sham and small burn groups, irrespective of sex or housing temperature (P < 0.05). Housing at 30 °C revealed sexual dimorphism in terms of the impact of burns on body mass and composition, where males with large burns displayed marked cachexia, whereas females did not. Collectively, this study demonstrates a sex-dependent role for housing temperature in influencing energetics and body composition in a rodent model of burn trauma.

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居住温度会改变小鼠烧伤引起的高代谢。

摘要：生物医学研究中使用的小鼠通常饲养在低于恒温（26-31 °C）的环境温度（22-24 °C）下。这种慢性低温应激会引发高代谢反应，可能会限制小鼠在模拟烧伤时高代谢反应中的作用。为了评估饲养温度对烧伤诱导的高代谢的影响，小鼠被随机分配接受假烧伤、小烫伤或大烫伤。小鼠在24 °C或30 °C的代谢表型笼中恢复21天。无论性别或假烫伤/烫伤处理如何，24 °C饲养的小鼠总能量消耗（TEE，P < 0.001）更大，这主要归因于与30 °C饲养的小鼠相比基础能量消耗（BEE）更大（P < 0.001）。中温饲养（30 °C）以性别依赖的方式改变了脂肪组织的质量。与假烧伤组和小烧伤组相比，无论饲养温度如何，大面积烧伤都会导致更多的水蒸气损失（P < 0.01）。与假烧伤相比，大面积烧伤导致 24 °C饲养小鼠的 BEE 和 TEE 增加，但 30 °C饲养的雌性小鼠对大面积烧伤的这种高代谢反应减弱，而 30 °C饲养的雄性小鼠则没有这种反应。与假烧伤组和小烧伤组相比，大面积烧伤小鼠的运动明显减少，与性别或饲养温度无关（P < 0.05）。在30 °C的饲养条件下，烧伤对体重和组成的影响表现出性别二形性，大面积烧伤的雄性表现出明显的恶病质，而雌性则没有。总之，这项研究表明，在啮齿动物烧伤模型中，饲养温度对能量和身体成分的影响与性别有关。

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

SHOCK 医学-外科

CiteScore

6.20

自引率

3.20%

发文量

199

审稿时长

1 months

期刊介绍： SHOCK®: Injury, Inflammation, and Sepsis: Laboratory and Clinical Approaches includes studies of novel therapeutic approaches, such as immunomodulation, gene therapy, nutrition, and others. The mission of the Journal is to foster and promote multidisciplinary studies, both experimental and clinical in nature, that critically examine the etiology, mechanisms and novel therapeutics of shock-related pathophysiological conditions. Its purpose is to excel as a vehicle for timely publication in the areas of basic and clinical studies of shock, trauma, sepsis, inflammation, ischemia, and related pathobiological states, with particular emphasis on the biologic mechanisms that determine the response to such injury. Making such information available will ultimately facilitate improved care of the traumatized or septic individual.