一氧化氮对犬小肠环形肌的作用。
Effect of nitric oxide on circular muscle of the canine small intestine.
作者信息
Stark M E, Bauer A J, Szurszewski J H
机构信息
Department of Physiology and Biophysics, Mayo Medical School, Rochester, MN 55905.
出版信息
J Physiol. 1991 Dec;444:743-61. doi: 10.1113/jphysiol.1991.sp018904.
Abstract
- Experiments were designed to determine in circular muscle of the canine jejunum whether exogenous nitric oxide (NO) mimics the non-adrenergic, non-cholinergic inhibitory junction potential (NANC IJP), and whether changes in the availability of endogenous NO affects IJP amplitude. 2. Mechanical and intracellular electrical activity were recorded simultaneously from circular muscle of the canine jejunum. Electrical field stimulation evoked NANC IJPs and inhibited spontaneous contractions. 3. Infusions of NO solutions evoked immediate dose-dependent and transient hyperpolarizations and transiently inhibited spontaneous contractions. NO-evoked hyperpolarizations were unaffected by atropine, propranolol, phentolamine and tetrodotoxin. 4. The maximum IJP amplitude and the maximum amplitude of NO-evoked hyperpolarization were similar. 5. NG-Mono-methyl-L-arginine (L-NMMA), which inhibits synthesis of NO from L-arginine, reduced IJP amplitudes but did not reduce the response to exogenous NO. L-Arginine, but not D-arginine, reversed the effect of L-NMMA on IJP amplitude. 6. Oxyhaemoglobin, which binds and inactivates NO, reduced IJP amplitude and abolished the response to exogenous NO. 7. Exogenous NO mimicked the effects of NANC inhibitory input. Reducing the availability of endogenous NO reduced NANC inhibitory input. 8. It was concluded that NO mediates NANC neural inhibition and may act as a NANC inhibitory neurotransmitter in the canine jejunum.
摘要
- 设计实验以确定在犬空肠环形肌中外源性一氧化氮(NO)是否模拟非肾上腺素能、非胆碱能抑制性接头电位(NANC IJP),以及内源性NO可用性的变化是否影响IJP幅度。2. 同时记录犬空肠环形肌的机械和细胞内电活动。电场刺激诱发NANC IJPs并抑制自发收缩。3. 输注NO溶液诱发即刻剂量依赖性和短暂性超极化,并短暂抑制自发收缩。NO诱发的超极化不受阿托品、普萘洛尔、酚妥拉明和河豚毒素的影响。4. 最大IJP幅度和NO诱发超极化的最大幅度相似。5. NG-单甲基-L-精氨酸(L-NMMA)抑制L-精氨酸合成NO,降低IJP幅度,但不降低对外源性NO的反应。L-精氨酸而非D-精氨酸可逆转L-NMMA对IJP幅度的作用。6. 氧合血红蛋白结合并使NO失活,降低IJP幅度并消除对外源性NO的反应。7. 外源性NO模拟NANC抑制性输入的作用。降低内源性NO的可用性会降低NANC抑制性输入。8. 得出结论:NO介导NANC神经抑制,可能作为犬空肠中的NANC抑制性神经递质发挥作用。
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