东莨菪碱注射小鼠的辣椒素神经药理学研究

Sakshi Tyagi, Ajit Kumar Thakur
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引用次数: 0

摘要

目的:评估辣椒素对东莨菪碱诱导的小鼠认知功能障碍、线粒体损伤和氧化损伤的潜在有益作用:背景:辣椒素是红辣椒中的主要酚类成分,是其辛辣味的主要来源。它影响痛觉神经元中的 TRPV1 通道,存在于啮齿类动物和人类大脑的海马和下丘脑中:主要目的是研究辣椒素在减轻东莨菪碱诱导的小鼠认知功能障碍、线粒体损伤和氧化损伤方面的有效作用,并探讨其可行机制:方法:给小鼠注射东莨菪碱后,每天口服不同剂量的辣椒素(5、10 和 20 毫克/千克),连续 7 天。对小鼠大脑不同区域的各种行为测试(运动协调性、运动计数、孔板测试)和生化检测(细胞因子、过氧化氢酶、脂质过氧化反应、亚硝酸盐、还原型谷胱甘肽和超氧化物歧化酶)、线粒体复合体(I、II、III和IV)酶活性以及线粒体通透性转换进行了评估:结果:东莨菪碱处理的小鼠在高架加迷宫的光区和开放臂中的进入次数和持续时间大大减少。有趣的是,不同剂量的辣椒素能逆转东莨菪碱的焦虑、抑郁样行为以及学习和记忆损伤效应。与正常对照组相比,服用东莨菪碱的小鼠体内细胞因子水平大幅升高,线粒体酶复合物活性受损,氧化损伤加剧。辣椒素治疗恢复了脂质过氧化还原、一氧化氮、过氧化氢酶、超氧化物歧化酶、还原型谷胱甘肽的活性,减少了促炎细胞因子,恢复了线粒体复合酶活性(I、II、III 和 IV)以及线粒体通透性。此外,只需服用一定剂量的辣椒素(10 毫克和 20 毫克/千克),IL-1β 水平就能得到恢复。辣椒素降低了东莨菪碱诱导的乙酰胆碱酯酶活性,从而提高了小鼠海马组织中的乙酰胆碱浓度。在组织学研究中,辣椒素还证实了对神经细胞形态的保护作用。从上述实验结果来看,辣椒素 10 毫克/千克,口服连续七次是最有效的剂量:结论:辣椒素通过恢复线粒体功能、抗氧化作用和调节细胞因子而产生的神经保护作用,使其成为通过临床设置进行进一步药物开发的有希望的候选药物。
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Neuropharmacological Study on Capsaicin in Scopolamine-injected Mice.

Aim: To evaluate the potential beneficial role of Capsaicin in cognitive dysfunction, mitochondrial impairment, and oxidative damage induced by scopolamine in mice.

Background: Capsaicin is the chief phenolic component present in red chili and is responsible for its pungent and spicy flavor. It affects TRPV1 channels in nociceptive sensory neurons and is present in the hippocampus, and hypothalamus of the brains of rodents and humans.

Objective: The main objective is to investigate the effective role of capsaicin in attenuating cognitive dysfunction, mitochondrial impairment, and oxidative damage induced by scopolamine in mice and examine the feasible mechanisms.

Methods: Various doses of capsaicin (5, 10, and 20 mg/kg) were given orally to mice daily for 7 consecutive days after the administration of scopolamine. Various behavioral tests (motor coordination, locomotor counts, hole board test) and biochemical assay (Pro-inflammatory cytokines, catalase, lipid peroxidation, nitrite, reduced glutathione, and superoxide dismutase), mitochondrial complex (I, II, III, and IV) enzyme activities, and mitochondrial permeability transition were evaluated in the distinct regions of the brain.

Results: Scopolamine-treated mice showed a considerable reduction in the entries and duration in the light zone as well as in open arms of the elevated plus maze. Interestingly, capsaicin at different doses reversed the anxiety, depressive-like behaviors, and learning and memory impairment effects of scopolamine. Scopolamine-administered mice demonstrated substantially increased pro-inflammatory cytokines levels, impaired mitochondrial enzyme complex activities, and increased oxidative damage compared to the normal control group. Capsaicin treatment reinstated the reduced lipid peroxidation, nitric oxide, catalase, superoxide dismutase, reduced glutathione activity, decreasing pro-inflammatory cytokines and restoring mitochondrial complex enzyme activities (I, II, III, and IV) as well as mitochondrial permeability. Moreover, the IL-1β level was restored at a dose of capsaicin (10 and 20 mg/kg) only. Capsaicin reduced the scopolamine-induced acetylcholinesterase activity, thereby raising the acetylcholine concentration in the hippocampal tissues of mice. Preservation of neuronal cell morphology was also confirmed by capsaicin in histological studies. From the above experimental results, capsaicin at a dose of 10 mg/kg, p.o. for seven consecutive days was found to be the most effective dose.

Conclusion: The experiential neuroprotective effect of capsaicin through the restoration of mitochondrial functions, antioxidant effects, and modulation of pro-inflammatory cytokines makes it a promising candidate for further drug development through clinical setup.

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