A preliminary exploration of establishing a mice model of hypoxic training.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-01-04 DOI:10.1038/s41598-024-84371-7

Minglu Li, Zhijie Chen, Ziyang He, Xinjuan Zhang, Yanqiu Liu, Hui Zhou, Hang Yang, Tao Liu, Xiaochuan Wang, Ran Zhang, Jiaxing Zhang

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Abstract

Altitude training has been widely adopted. This study aimed to establish a mice model to determine the time point for achieving the best endurance at the lowland. C57BL/6 and BALB/c male mice were used to establish a mice model of hypoxic training with normoxic training mice, hypoxic mice, and normoxic mice as controls. All hypoxic mice were placed in a chamber filled with 16% O₂ and N₂, and hypoxic training mice were trained for two weeks. Then mice were removed from the chamber and tested at normoxic conditions weekly at the beginning of the experiment and the second, third, fourth, and sixth weeks. The tests for endurance ability include maximal aerobic speed (MAS), Rota-rod, and grip strength. In addition, the open field, visual cliff, and Y maze were used to test cognitive abilities. Body composition and lactic acid tolerance level were also measured. For BALB/c but not C57BL/6 mice were evaluated for effectively training. Based on the average MAS of all mice, mice successfully passed the training according to the procedure: the first week (32%MAS/10min, 48%MAS/10min, and 64%MAS/10min) and second week (40%MAS/10min, 56%MAS/10min, and 72%MAS/10min). Hypoxic training mice reached peak rotarod performance on the 7th day post-training (Test 3), with significant improvements compared to Test 1, 2, 4, and 5. At Test 3, their rotarod scores significantly differed from both H and N groups, and showing a trend towards difference from NT group. Meanwhile, hypoxic mice showed significant cognitive impairment, anxiety, depression, muscle loss, and fat gain compared with hypoxic training mice after hypoxia intervation. Two consecutive weeks of 16% O2 training followed by one week of reoxygenation may be the best for endurance competition. Thus, we think a mouse model for hypoxic training was built, with Rota-rod testing as a detection indicator. Moreover, hypoxic training may alleviate the damage of hypoxia to the body.

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建立小鼠缺氧训练模型的初步探讨。

高原训练已被广泛采用。本研究旨在建立小鼠模型，以确定在低地达到最佳耐力的时间点。采用C57BL/6和BALB/c雄性小鼠建立小鼠缺氧训练模型，以常氧训练小鼠、低氧小鼠和常氧小鼠为对照。将缺氧小鼠置于充满16% O2和N2的室内，进行为期两周的缺氧训练。然后在实验开始和第二、第三、第四、第六周，每周将小鼠从室中取出，在常温条件下进行测试。耐力测试包括最大有氧速度（MAS）、Rota-rod和握力。此外，还采用开阔场地、视觉悬崖和Y型迷宫测试大鼠的认知能力。测定体成分和乳酸耐受水平。对BALB/c小鼠而非C57BL/6小鼠进行有效训练评价。根据所有小鼠的平均MAS，小鼠按照第一周（32%MAS/10min、48%MAS/10min、64%MAS/10min）和第二周（40%MAS/10min、56%MAS/10min、72%MAS/10min）的程序顺利通过训练。低氧训练小鼠在训练后第7天（测试3）达到了旋转杆性能的峰值，与测试1、2、4和5相比有显著改善。在测试3中，他们的旋转杆得分与H组和N组均有显著差异，并呈现与NT组差异的趋势。同时，与缺氧训练小鼠相比，缺氧小鼠在缺氧干预后表现出明显的认知障碍、焦虑、抑郁、肌肉损失和脂肪增加。连续两周进行16%的氧气训练，然后进行一周的再氧训练，这可能是耐力比赛的最佳选择。因此，我们认为建立小鼠缺氧训练模型，以Rota-rod测试作为检测指标。此外，低氧训练可以减轻缺氧对身体的伤害。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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