隐丹参酮对慢性皮质酮注射诱导抑郁小鼠的干预作用

Abstract
Figure/Table
References (27)
Related Citation (15)

Download: PDF (738 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract Objective To observe the intervention of cryptotanshinone on depression induced by chronic corticosterone (CORT) injection in mice. Methods Sixty male SPF KM mice were selected. According to random number table method, they were divided into cryptotanshinone low-dose group (10 mg/kg), cryptotanshinone medium-dose group (20 mg/kg), cryptotanshinone high-dose group (40 mg/kg), Fluoxetine group (20 mg/kg), normal control group (equal amount of normal saline), and model group (equal amount of normal saline), with ten mice in each group. Except for normal control group, the depression model was established by continuous injection of CORT (20 mg/kg) in other groups, and the model was established at the same time. After 21 days of continuous administration, the effects of cryptotanshinone on body weight gain, sugar water consumption ratio of mice were observed. Behavioral evaluation was conducted by forced swimming test, open field test and water maze test. Serum levels of CORT, adrenocorticotropic hormone (ACTH), and brain-derived neurotrophic factor (BDNF) in hippocampus and prefrontal cortex were determined. Results In model group, the weight gain, sugar water consumption ratio, and BDNF content were lower than those in normal control group, the immobility time, central lattice residence time, and escape latency were longer than those of the normal control group, the number of horizontal crossing lattice, upright times, and modification times were less than those of normal control group, the stay time of the target quadrant and the movement distance around the platform were shorter than those of the normal control group, the contents of CORT and ACTH were higher than those of normal control group, and the differences were statistically significant (P < 0.05 or P ＜ 0.01). In cryptotanshinone dose groups, the weight gain was higher than that of the model group, the central lattice residence time was shorter than that of model group, the number of horizontal crossing lattice and modification times were more than those of model group, and the levels of CORT and ACTH were lower than that of model group, the differences were statistically significant (P ＜ 0.05 or P ＜ 0.01). In cryptotanshinone medium-dose and high-dose groups, the sugar water consumption ratio was higher than that of model group, the immobility time was shorter than the model group, the center lattice residence time was shorter than the cryptotanshinone low-dose group, and the upright times were more than the model group and the cryptotanshinone low-dose group, the number of horizontal crossing lattice and the modifications times were more than those of cryptotanshinone low-dose group, the escape latency was shorter than that of the model group, the stay time of the target quadrant and the movement distance around the platform were longer than those of the model group, levels of CORT and ACTH were lower than those of cryptotanshinone low-dose group, and the content of BDNF was higher than that of the model group and the cryptotanshinone low-dose group, with statistical significances (P ＜ 0.05 or P ＜ 0.01). The escape latency in the cryptotanshinone high-dose group was shorter than that in the cryptotanshinone low and medium dose groups, the level of CORT was lower than that in the cryptotanshinone medium-dose group, and the content of BDNF in hippocampus was higher than that in the cryptotanshinone medium-dose group, with statistical significances (P ＜ 0.05 or P ＜ 0.01). Conclusion Cryptotanshinone can improve the depression-like behavior of CORT-induced mice, and the effect is more obvious in the medium-dose and high-dose groups. The mechanism may be related to the regulation of hypothalamic-pituitary-adrenal axis function and the up-regulation of BDNF expression level in brain.

Key words： Cryptotanshinone Depression Corticosterone Adrenocorticotropic hormone Brain-derived neurotrophic factor

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	CHEN Mingzhu LIAO Wanting HUANG Youxia

Cite this article:

CHEN Mingzhu LIAO Wanting HUANG Youxia. Intervention of cryptotanshinone on depression induced by chronic corticosterone injection in mice#br#[J]. 中国医药导报, 2021, 18(35): 23-27.

URL:

https://www.yiyaodaobao.com.cn/EN/ OR https://www.yiyaodaobao.com.cn/EN/Y2021/V18/I35/23

[1] Rehm J，Shield KD. Global Burden of Disease and the Impact of Mental and Addictive Disorders [J]. Curr Psychiatry Rep，2019，21（2）：10.
[2] 崔妍，王若男，吴九如，等.酸枣仁和合欢花水提取物对焦虑性抑郁症模型大鼠HPA轴及炎症因子的影响[J].吉林大学学报：医学版，2019，45（3）：539-545.
[3] Cristina OM，Serra VM，Francisco AP，et al. Neuroprotective and Antioxidant Effects of Riparin Ⅰ in a Model of Depression Induced by Corticosterone in Female Mice [J]. Neuropsychobiolo，2021：1-11.
[4] 黄巧玲，吴华丽，蔡旻煊，等.皮质酮与慢性不可预见性应激诱导的两种抑郁症模型比较[J].解剖学报，2017，48（3）：273-281.
[5] 朱翠玲，朱明军，杜明远，等.基于复杂网络分析的中医药治疗冠心病合并抑郁用药规律[J].中医杂志，2020，61（7）：626-631.
[6] 张忠东，曹莉，程灶火.丹参酮的抗抑郁作用研究[J].中国药房，2012，23（47）：4436-4438.
[7] Gao GY，Wang XH，Li KK，et al. Neuroprotective effects of cryptotanshinone and 1，2-dihydrotanshinone Ⅰ against MPTP induced mouse model of Parkinson’s disease [J]. Phytochem Lett，2018，26：68-73.
[8] 王霖，王睿，魏广义，等.隐丹参酮改善小鼠化疗性肠黏膜炎的作用及机制研究[J].药学学报，2020，55（8）：1801-1811.
[9] Li XP，Li W，Yang P，et al. Anticancer effects of Cryptotanshinone against lung cancer cells through ferroptosis [J]. Arab J Chem，2021：103177.
[10] Zhou XM，Liu CY，Liu YY，et al. Xiaoyaosan Alleviates Hippocampal Glutamate-Induced Toxicity in the CUMS Rats via NR2B and PI3K/Akt Signaling Pathway [J]. Front Pharmacol，2021，12：586788.
[11] Zsolt G，Farkas S，Albert A，et al. Effects of Chronic Cannabidiol Treatment in the Rat Chronic Unpredictable Mild Stress Model of Depression [J]. Biomole，2020，10（5）：801.
[12] 王雪蕊，郭玉红，赵京霞，等.参附黄配方对脓毒症小鼠认知功能和突触可塑性的影响[J].北京中医药大学学报，2020，43（11）：935-940.
[13] Lebedeva KA，Caruncho HJ，Kalynchuk LE. Cyclical corticosterone administration sensitizes depression-like behavior in rats [J]. Neurosci Lett，2017，650：45-51.
[14] 赵洪庆，王宇红，孟盼，等.百合疏肝安神汤及其拆方对焦虑性抑郁症大鼠HPA轴和单胺神经递质的影响[J].中药药理与临床，2021，37（1）：160-166.
[15] 张磊阳，贺敏，陈文文，等.五合天参枣汤抗抑郁作用的初步探究[J].中成药，2021，43（5）：1315-1319.
[16] 王爱芹，褚延乐，赵明军，等.舍曲林在抑郁症大鼠模型抗抑郁中的作用及大鼠海马凋亡信号通路相关蛋白的差异性表达[J].河南大学学报：医学版，2021，40（1）：1-6.
[17] 张铭珈，倪慧，朱艳芳，等.四逆散、应激血清/脑脊液对皮质酮损伤的海马神经元生存率的影响[J].时珍国医国药，2019，30（7）：1563-1565.
[18] 葛渴敏，薛文达，王薇.越鞠甘麦大枣汤对皮质酮诱导损伤的HT22细胞的神经保护作用[J].时珍国医国药，2018，29（10）：2334-2337.
[19] 菊轩，时雯雯，陈松，等.睡眠剥夺联合氟西汀对抑郁模型大鼠行为及血清促肾上腺皮质激素、皮质酮的影响[J].中国现代医生，2021，59（16）：43-47，51.
[20] 曹亚飞，张延红，芦晔，等.荷梗水提物对慢性应激所致抑郁小鼠学习记忆及蛋白激酶C表达的影响[J].中国新药杂志，2021，30（7）：633-638.
[21] Chernyuk DP，Bol Shakova AV，Vlasova OL，et al. Possibilities and Prospects of the Behavioral Test“Morris Water Maze”[J]. J Evo Biochem Phys，2021，57（2）：289-303.
[22] Fernandes BS，Molendijk ML，Kohler CA，et al. Peripheral brain-derived neurotrophic factor（BDNF） as a biomarker in bipolar disorder：a meta-analysis of 52 studies [J]. BMC Med，2015，13（1）：289.
[23] 刘新黎，陈家俊，胡浩宇，等.帕罗西汀片对抑郁症大鼠模型抑郁行为的改善效果及相关作用机制分析[J].中国现代医生，2020，58（19）：33-36，193.
[24] Ronald SD，Satoshi D，Viar FM，et al. Role of BDNF in the pathophysiology and treatment of depression：Activity-dependent effects distinguish rapid-acting antidepressants [J]. Eur J Neurosci，2021，53（1）：126-139.
[25] Bus BAA，Molendijk ML，Tendolkar I，et al. Chronic depression is associated with a pronounced decrease in serum brain-derived neurotrophic factor over time [J]. Mol Psychiatr，2015，20（5）：602-608.
[26] 王含彦，郭冬梅，唐珍.舒肝解郁胶囊对抑郁模型大鼠脑内脑源性神经营养因子的影响[J].中国医药导报，2019，16（20）：21-24.
[27] 任荔，陶伟伟，柴毅，等.栀子石油醚有效部位的快速抗抑郁潜力与BDNF、p-eEF2表达上调相关[J].中国药理学通报，2016，32（9）：1224-1230.