蜂胶乙醇提取物(EEP)对豚鼠胸主动脉的舒张作用

目的:探讨蜂胶水提物(WEP)和乙醇提物(EEP)的血管舒张作用。方法:以离体豚鼠胸主动脉环为材料,采用离体实验方法记录血管收缩张力。结果:对于PE(PE,1μM)和KC1(60mM)预收缩的主动脉环,EEP可以剂量依赖地使其舒张。去除内皮后舒张作用减弱,所以这种作用是内皮依赖性的;使用NO合酶抑制剂N-硝基-L-精氨酸(L-NNA,10μM)、鸟苷酸环化酶抑制剂(methylene blue,10μM)或者前列腺素合成酶抑制剂(indomethacin,10μM)预处理,血管舒张作用也减弱。这提示EEP的作用可能与血管内皮释放的一氧化氮和前列腺素有关;K~ 通道通用抑制剂TEA(tetraethylammonium chloride,1 mM)的处理对EEP的舒血管作用没有影响,显示EEP对豚鼠动脉环的舒张作用与K~ 通道无关;另外,EEP能使CaCl_2的量效曲线下移,说明EEP可以抑制细胞外Ca~(2 )的内流,同时EEP还可以抑制细胞内Ca~(2 )的释放。结论:蜂胶乙醇提取物EEP能剂量依赖地引起离体豚鼠动脉环舒张。这种舒张作用与K~ 通道无关,但受内皮NO-鸟苷酸环化酶途径和前列腺素调控,最终通过降低细胞内Ca~(2 )的浓度舒张血管。     

一氧化氮的释放对海马脑片CAl区痫样放电的影响

用自制的一氧化氮（NO）敏感电极──Nation-壳聚糖合镍修饰铂电极（Nation-CTS（Ni）-Pt）连续测定了青霉素致痫海马脑片CAl区锥体层神经元NO的释放,并同时观察了NO合酶抑制剂7-nitro-indaole（7-NI）及Nω-nitro-L-arginine（L-NNA）对诱发痫波及NO释放量的影响。研究观察到：（1）在青霉素致痫脑片模型上,诱发的痫波随青霉素浓度的增加而增多,与此同时,NO释放量亦增加并存在剂量反应关系;（2）NO合酶抑制剂7-NI及L-NNA抑制海马脑片CAl区NO的产生的同时,可部分翻转青霉素的致痫作用;（3）NO敏感电极检测线性范围为4．5×10－4～1．0×10－8mol／L,可用于生物组织如脑片的NO释放量测定。结果提示,NO可能有致痫作用;L-NNA及7-NI对癫痫有抑制作用;NO敏感电极的应用为生物体NO的连续实时测定提供了有效的实验工具。     

延髓腹外侧区微量注射L－NNA和SNP对大鼠血压、心率和肾交感神经活动的影响

在麻醉大鼠观察了向延髓腹外侧区微量注射ＮＯ合成酶抑制剂Ｎ－硝基左旋精氨酸（ＬＮＮＡ）和硝普钢（ＳＮＰ）对血压、心率和肾交感神经活动的影响,旨在探讨中枢左旋精氨酸－ＮＯ通路在动脉血压调节中的作用及其机制。实验结果如下：（１）向延髓腹外侧头端区（ＲＶＬＭ）注射Ｌ－ＮＮＡ后,平均动脉压（ＭＡＰ）升高,肾交感神经活动（ＲＳＮＡ）增强;心率（ＨＲ）减慢,但无统计学意义。ＭＡＰ和ＲＳＮＡ的变化持续３０ｍｉｎ以上;此效应可被预先静注左旋精氨酸所逆转。（２）向ＲＶＬＭ微量注射ＳＮＰ,ＭＡＰ降低,ＲＳＮＡ减弱;但ＨＲ的变化无统计学意义。（３）向延髓腹外侧尾端区（ＣＶＬＭ）注射Ｌ－ＮＮＡ,ＭＡＰ降低,ＨＲ减慢,ＲＳＮＡ减弱。（４）向ＣＶＬＭ微量注射ＳＮＰ,ＭＡＰ升高,ＲＳＮＡ增强,而心率无明显变化。以上结果表明,中枢左旋精氨酸－ＮＯ通路对延髓腹外侧部的神经元活动有调变作用。     

L－NNA及NO供体对延髓腹外侧头端区神经元自发放电的影响

在麻醉大鼠观察了静注ＮＯ合成酶抑制剂Ｎ－硝基左旋精氨酸（Ｌ－ＮＮＡ）和ＮＯ供体──硝普钠（ＳＮＰ）和ＳＩＮ－Ｉ对血压、心率和延髓腹外侧头端区（ＲＶＬＭ）神经元自发放电活动的影响,旨在探讨Ｌ－ａｒｇ：ＮＯ通路对动脉血压调节的中枢作用部位。所得结果如下：（１）静注Ｌ－ＮＮＡ后,平均动脉压（ＭＡＰ）升高,心率（ＨＲ）加快,１１个ＲＶＬＭ神经元自发放电频率增加。这些变化发生于给药后５ｍｉｎ,持续时间达３０ｍｉｎ以上。（２）静注ＳＮＰ后,ＭＡＰ降低,ＨＲ加快,２３个ＲＶＬＭ神经元自发放电频率降低,且有剂量依赖性。ＳＮＰ作用发生快,持续时间短。为了排除脑缺血的影响,还特意向一侧颈动脉内注射相同剂量ＳＮＰ,结果引起ＭＡＰ轻度降低,而ＨＲ无明显改变,但ＲＶＬＭ神经元自发放电频率仍显著降低。（３）静注另一ＮＯ供体ＳＩＮ－Ｉ后,ＭＡＰ降低,１１个ＲＶＬＭ神经元自发放电频率降低．与ＳＮＰ的效应基本一致。以上结果提示,ＲＶＬＭ是Ｌ－ａｒｇ：ＮＯ通路实现动脉血压调节的一个中枢作用部位。     

N-亚硝基左旋精氨酸的心血管效应及其对肾交感神经活动的影响

在麻醉大鼠观察了新型NO合成抑制剂N-亚硝基左旋精氨酸(L-NNA)的血流动力学效应及其对肾交感神经活动的影响,旨在阐明NO在全身动脉血压调节中的可能作用及其作用机制。实验结果如下:(1)静注L-NNA(15 mg/kg)后,平均动脉压(MAP)由9.87±0.80升至14.67±0.53kPa(P<0.001),心率(HR)由317±13减至303±14 bpm(P<0.05),心指数(CI)由9.79±0.83降至7.04±0.41ml/min·100g~(-1)(P<0.05),总外周阻力指数(TPRI)由1.04±0.10升至2.15±0.18 u/100 g(P<0.001),持续30min以上;此效应可被预先注射左旋精氨酸(200 mg/kg)所逆转。(2)在缓冲神经切断的大鼠,i.v.L-NNA时,MAP,CI和TPRI的变化依然存在,而HR则加快,表明神经完整大鼠的HR减慢系压力感受器反射所致。(3)在缓冲神经完整大鼠i.v.L-NNA后,MAP升高,HR减慢,而肾交感神经活动(RSNA)无明显改变。(4)切断缓冲神经后,再i.v.L-NNA时,MAP,HR和RSNA分别增加55.6％、5.1％和34.3％,提示L-NNA可能兴奋交感中枢,而压力感受器反射可掩盖其对RSNA的影响;预先注射左旋精氨酸则可抑制L-NNA的上述效应。根据以上结果似可认为,NO合成抑制剂的血流动力学效应,由两种机制所介导:一是L-NNA抑制外周部位NO的基础性释放,致使血管紧张度增加,进而血压升高;另一是L-NNA兴奋交感中枢,从而引     

Cobalt protoporphyrin inhibition of lipopolysaccharide or lipoteichoic acid-induced nitric oxide production via blocking c-Jun N-terminal kinase activation and nitric oxide enzyme activity

In the present study, low doses (0.5, 1, and 2 μM) of cobalt protoporphyrin (CoPP), but not ferric protoporphyrin (FePP) or tin protoporphyrin (SnPP), significantly inhibited lipopolysaccharide (LPS) or lipoteichoic acid (LTA)-induced inducible nitric oxide (iNOS) and nitric oxide (NO) production with an increase in heme oxygenase 1 (HO-1) protein in RAW264.7 macrophages under serum-free conditions. IC₅₀ values of CoPP inhibition of NO and iNOS protein individually induced by LPS and LTA were around 0.25 and 1.7 μM, respectively. This suggests that CoPP is more sensitive at inhibiting NO production than iNOS protein in response to separate LPS and LTA stimulation. NO inhibition and HO-1 induction by CoPP were blocked by the separate addition of fetal bovine serum (FBS) and bovine serum albumin (BSA). Decreasing iNOS/NO production and increasing HO-1 protein by CoPP were observed with CoPP pretreatment, CoPP co-treatment, and CoPP post-treatment with LPS and LTA stimulation. LPS- and LTA-induced NOS/NO productions were significantly suppressed by the JNK inhibitor, SP600125, but not by the ERK inhibitor, PD98059, through a reduction in JNK protein phosphorylation. Transfection of a dominant negative JNK plasmid inhibited LPS- and LTA-induced iNOS/NO production and JNK protein phosphorylation, suggesting that JNK activation is involved in LPS- and LTA-induced iNOS/NO production. Additionally, CoPP inhibition of LPS- and LTA-induced JNK, but not ERK, protein phosphorylation was identified in RAW264.7 cells. Furthermore, CoPP significantly reduced NO production in a cell-mediated, but not cell-free, iNOS enzyme activity assay accompanied by HO-1 induction. However, attenuation of HO-1 protein stimulated by CoPP via transfection of HO-1 siRNA did not affect NO's inhibition of CoPP against LPS stimulation. CoPP effectively suppressing LPS- and LTA-induced iNOS/NO production through blocking JNK activation and iNOS enzyme activity via a HO-1 independent manner is first demonstrated herein.