A modified protocol for generating the simulated weightlessness rat model

doi:10.12047/j.cjap.5772.2019.041

Abstract

Abstract: Objective: To introduce a modified protocol for generating the simulated weightlessness rat model by hindlimb unloading. Methods: Ninety male adult SD rats were randomly divided into three groups: the control group, classical suspension group and modified suspension group (n=30/group). In the classical suspension group, a strip of medical adhesive tape was attached to the tail, with horizontal filament tape wrapping. A piece of gauze was wrapped around the tail at the outermost layer and the tail was suspended for hindlimb unloading. In the modified suspension group, a layer of plastic net was added between the horizontal filament tape and the gauze to reduce the squeeze on the tail as a buffer zone and ensure proper circulation of the tail. After 4 weeks of suspension, damage to the tail and sheath detachment were observed. Meanwhile the body weight and right soleus wet weight of rats were measured. Results: The ratio of right soleus wet weight to body weight was decreased significantly in both the classical suspension group and the modified suspension group compared with the control group, while there was no difference in body weight among the three different groups. Importantly, the incidence of tail ischemia and necrosis (13.3% vs 40.0% in the classical suspension group) and the incidence of sheath detachment from tail (3.3% vs 26.7% in the classical suspension group) were significantly lower whereas the success rates of model (33.3% vs 83.3% in classical suspension group) was significantly higher in the modified suspension group. Conclusion: The modified protocol decreases the incidence of tail necrosis and sheath detachment in the rat tail suspension and increases the success rate of the hindlimb unloading rat model, with improved simplicity and practicability.

Key words: weightlessness simulation, hindlimb unloading, tail suspension, rats

FU Zi-hao, WANG Zhen, WU Jie, YANG Hong-yan, ZHANG Xing, GAO Feng, LI Jia. A modified protocol for generating the simulated weightlessness rat model[J]. CJAP, 2019, 35(2): 189-192.

References

[1] Morey-Holton ER, Globus RK. Hindlimb unloading rodent model: technical aspects[J]. J Appl Physiol, 2002, 92(4): 1367-1377.
[2] Chowdhury P, Long A, Harris G, et al. Animal model of simulated microgravity: a comparative study of hindlimb unloading via tail versus pelvic suspension[J]. Physiol Rep, 2013, 1(1): e00012.
[3] 薛涛, 邬丽莎, 陈善广, 等. 模拟航天失重大鼠自发活动的改变[J]. 中国比较医学杂志, 2015, 25(1): 20-29.
[4] Wang Z, Bai Y, Yu J, et al. Caveolae regulate vasoconstriction of conduit arteries to angiotensin II in hindlimb unweighted rats[J]. J Physiol, 2015, 593(20): 4561-4574.
[5] Tuday EC, Nyhan D, Shoukas AA, et al. Simulated microgravity-induced aortic remodeling[J]. J Appl Physiol, 2009, 106(6): 2002-2008.
[6] 陈杰, 马进, 丁兆平, 等. 一种模拟长期失重影响的大鼠尾部悬吊模型[J]. 空间科学学报,1993, 13(2): 159-162.
[7] Globus RK, Morey-Holton E. Hindlimb unloading: rodent analog for microgravity[J]. J Appl Physiol, 2016,120(10): 1196-1206.
[8] 崔艳领, 刘甜, 孙晗,等. 川芎嗪对模拟失重大鼠颈动脉平滑肌Ca²⁺敏感性的影响[J]. 中国应用生理学杂志, 2016, 32(4): 361-364.
[9] 姜山峰, 高云芳. 模拟失重对大鼠情绪影响的初步研究[J]. 中国应用生理学杂志, 2012, 28(3): 205-208.
[10]董丽,王琼,刘新民,等. 地面模拟失重实验方法概况[J]. 中国实验动物学报, 2013, 21(5): 90-94.
[11]Cavanagh PR, Genc KO, Gopalakrishnan R, et al. Foot forces during typical days on the international space station[J]. J Biomech, 2010, 43(11): 2182-2188.
[12]Steffen JM, Musacchia XJ. Disuse atrophy, plasma corticosterone, and muscle glucocorticoid receptor levels[J]. Aviat Space Environ Med, 1987, 58(10): 996-1000.
[13]Halloran BP, Bikle DD, Cone CM, et al. Glucocorticoids and inhibition of bone formation induced by skeletal unloading[J]. Am J Physiol, 1988, 255(6 Pt 1): E875-879.
[14]Morey-Holton E, Globus RK, Kaplansky A, et al. The hindlimb unloading rat model: literature overview, technique update and comparison with space flight data[J]. Adv Space Biol Med, 2005, 10: 7-40.
[15]Hargens AR, Steskal J, Johansson C, et al. Tissue fluid shift, forelimb loading and tail tension in tail-suspended rats[J]. Physiologist, 1984, 27: S37-S38.
[16]孙联文, 杨肖, 谢添, 等. 尾吊模型中大鼠的前肢承重分布[J]. 医用生物力学, 2009, 24(S1): 29.