通过大麻素(CB2)受体激活抑制豚鼠和人类感觉神经活动以及豚鼠的咳嗽反射。
Inhibition of guinea-pig and human sensory nerve activity and the cough reflex in guinea-pigs by cannabinoid (CB2) receptor activation.
作者信息
Patel Hema J, Birrell Mark A, Crispino Natascia, Hele David J, Venkatesan Priya, Barnes Peter J, Yacoub Magdi H, Belvisi Maria G
机构信息
Respiratory Pharmacology Group, Guy Scadding Building, The National Heart & Lung Institute, Faculty of Medicine, Imperial College London, Dovehouse Street, London SW3 6LY.
出版信息
Br J Pharmacol. 2003 Sep;140(2):261-8. doi: 10.1038/sj.bjp.0705435. Epub 2003 Aug 4.
Abstract
- There is considerable interest in novel therapies for cough, since currently used agents such as codeine have limited beneficial value due to the associated side effects. Sensory nerves in the airways mediate the cough reflex via activation of C-fibres and RARs. Evidence suggests that cannabinoids may inhibit sensory nerve-mediated responses. 2. We have investigated the inhibitory actions of cannabinoids on sensory nerve depolarisation mediated by capsaicin, hypertonic saline and PGE2 on isolated guinea-pig and human vagus nerve preparations, and the cough reflex in conscious guinea-pigs. 3. The non-selective cannabinoid (CB) receptor agonist, CP 55940, and the selective CB2 agonist, JWH 133 inhibited sensory nerve depolarisations of the guinea-pig vagus nerve induced by hypertonic saline, capsaicin and PGE2. These responses were abolished by the CB2 receptor antagonist SR144528, and unaffected by the CB1 antagonist SR141716A. Similarly, JWH 133 inhibited capsaicin-evoked nerve depolarisations in the human vagus nerve, and was prevented by SR144528. 4. Using a guinea-pig in vivo model of cough, JWH 133 (10 mg kg-1, i.p., 20 min) significantly reduced citric acid-induced cough in conscious guinea pigs compared to those treated with the vehicle control. 5. These data show that activation of the CB2 receptor subtype inhibits sensory nerve activation of guinea-pig and human vagus nerve, and the cough reflex in guinea-pigs, suggesting that the development of CB2 agonists, devoid of CB1-mediated central effects, will provide a new and safe antitussive treatment for chronic cough.
摘要
- 由于目前使用的药物如可待因存在副作用,其有益价值有限,因此人们对咳嗽的新型疗法兴趣浓厚。气道中的感觉神经通过C纤维和RARs的激活介导咳嗽反射。有证据表明,大麻素可能抑制感觉神经介导的反应。2. 我们研究了大麻素对辣椒素、高渗盐水和前列腺素E2介导的离体豚鼠和人迷走神经制剂感觉神经去极化的抑制作用,以及对清醒豚鼠咳嗽反射的抑制作用。3. 非选择性大麻素(CB)受体激动剂CP 55940和选择性CB2激动剂JWH 133抑制了高渗盐水、辣椒素和前列腺素E2诱导的豚鼠迷走神经感觉神经去极化。这些反应被CB2受体拮抗剂SR144528消除,而不受CB1拮抗剂SR141716A的影响。同样,JWH 133抑制了人迷走神经中辣椒素诱发的神经去极化,并被SR144528阻断。4. 使用豚鼠咳嗽的体内模型,与用载体对照处理的豚鼠相比,JWH 133(10 mg kg-1,腹腔注射,20分钟)显著减少了清醒豚鼠中柠檬酸诱导的咳嗽。5. 这些数据表明,CB2受体亚型的激活抑制了豚鼠和人迷走神经的感觉神经激活以及豚鼠的咳嗽反射,这表明开发无CB1介导的中枢效应的CB2激动剂将为慢性咳嗽提供一种新的安全的镇咳治疗方法。
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