Kant G J, Eggleston T, Landman-Roberts L, Kenion C C, Driver G C, Meyerhoff J L
Pharmacol Biochem Behav. 1985 Apr;22(4):631-4. doi: 10.1016/0091-3057(85)90286-2.
Rats were exposed to 15 min of restraint or footshock or forced running in an activity wheel once a day for 10 days. Control groups were handled only. On the 11th day, rats from each stressor group and controls were exposed to 15 min of one stressor in a crossed design such that all combinations of one chronic stressor and one acute stressor were performed. Rats were sacrificed immediately following removal from their home cage or after 15 min stressor exposure on the 11th day and plasma corticosterone and prolactin and pituitary cyclic AMP levels were determined. There were no measured differences in these stress indices among groups of rats sacrificed immediately upon removal from their home cage on day 11 regardless of previous history on days 1 through 10. Plasma corticosterone and plasma prolactin and pituitary cyclic AMP levels were elevated in all rats exposed to any of the three stressors immediately prior to sacrifice as compared to all rats not exposed to stress immediately before sacrifice. However, plasma prolactin and pituitary cyclic AMP responses to each of the 3 stressors were attenuated in rats which had previous exposure to that specific stressor as compared to rats which had previous experience with a different or no stressor. We conclude that habituation results from behavioral experience with a particular stressor rather than biochemical adaptation resulting from repeated challenge to hormonal and neurochemical systems responsive to stress.
大鼠每天接受一次15分钟的束缚、足部电击或在活动轮中强迫奔跑,持续10天。对照组仅进行抓握处理。在第11天,采用交叉设计,使每个应激源组和对照组的大鼠接受15分钟的一种应激源刺激,从而完成一种慢性应激源和一种急性应激源的所有组合。在第11天,将大鼠从其饲养笼中取出后立即处死,或在接受15分钟应激源刺激后处死,测定血浆皮质酮、催乳素和垂体环磷酸腺苷水平。在第11天从饲养笼中取出后立即处死的大鼠组中,无论第1天至第10天的既往经历如何,这些应激指标均未检测到差异。与所有在处死前未暴露于应激的大鼠相比,所有在处死前暴露于三种应激源中任何一种的大鼠,其血浆皮质酮、血浆催乳素和垂体环磷酸腺苷水平均升高。然而,与有不同应激经历或无应激经历的大鼠相比,先前暴露于特定应激源的大鼠对三种应激源中每种应激源的血浆催乳素和垂体环磷酸腺苷反应均减弱。我们得出结论,习惯化是由对特定应激源的行为体验导致的,而非对应激反应的激素和神经化学系统反复刺激所产生的生化适应。
