Orexin-A介导histamine能神经系统促进氯胺酮麻醉觉醒

目的:探索氯胺酮麻醉下,Orexin神经信号是否激活结节乳头体核(Tuberomammillary Nucleus,TMN)促进大鼠氯胺酮麻醉觉醒。方法:成年雄性SD大鼠(体重230-280 g),在10%水合氯醛麻醉下(1 ml/kg,i.p.)进行以下实验:1TMN核团埋置微注射外套管,回笼单独饲养7天后,大鼠随机分为三组,分别为对照组(NS)、orexin-A组与orexin-B组。TMN核团分别双侧微注射NS(0.3μL)、orexin-A(100 pmol/0.3μL)及orexin-B(100 pmol/0.3μL)观察氯胺酮麻醉下(100 mg/kg,腹腔注射)大鼠诱导时间与觉醒时间;2上述实验7天后,大鼠随机分为三组,分别为溶剂DMSO组、SB334867组与TCS-OX2-29组,TMN核团分别双侧微注射DMSO(0.3μL)、orexin 1型受体(the orexin type 1 receptor,OX1R)的拮抗剂SB334867(20μg/0.3μL)和orexin 2型受体(the orexin type 2 receptor,OX2R)的拮抗剂TCS-OX2-29(20μg/0.3μL)观察氯胺酮麻醉下大鼠诱导时间与觉醒时间。结果:1各组大鼠的诱导时间无统计学差异。2在TMN核团微注射orexin-A与对照组相比明显缩短了大鼠的觉醒时间(43.17±6.31 min vs51.17±4.45 min,P0.05),而微注射orexin-B与对照组相比并没有明显影响大鼠的觉醒时间(50.33±3.50 min vs 51.17±4.45min,P0.05)。3TMN核团微注射OX1R拮抗剂SB334867较溶剂DMSO组延长了麻醉觉醒时间(60.83±8.84 min vs 49.00±5.73 min,P0.05),OX2R拮抗剂TCS-OX2-29与溶剂DMSO组相比并没有明显影响大鼠的觉醒时间(50.83±4.79 min vs 49.00±5.73 min,P0.05)。结论:本研究实验证据证实在氯胺酮麻醉下,orexin神经信号可能通过激活TMN区组胺能神经系统促进麻醉向觉醒的转换。     

Molecular Biology of Background K Channels: Insights from K2P Knockout Mice

K_2P channels are a family of cellular proteins that are essential for electrical signaling throughout the body. There are six K_2P channel subfamilies, consisting of 15 distinct mammalian genes. K_2P channels display a remarkable range of regulation by cellular, physical and pharmacologic agents, including protein kinases, intracellular Ca²⁺, changes in internal and external pH, anesthetic agents, heat, stretch and membrane deformers. The molecular and cellular mechanisms underlying this regulation are complex and cooperate at many different levels. Recent research has provided strong evidence that the spatiotemporal-specific expression of K_2P channels are determinants of physiologic selectivity and specificity. In recent years, knockout mice have been generated with inactivated K_2P channel genes. These animals shed new light on the contribution of K_2P channels to normal and abnormal physiology. In this review, we summarize the published data on these mice to broaden the understanding of the role of K_2P channel activity.