下丘脑室旁核胃动素对消化功能影响的研究

目的:研究下丘脑室旁核注入胃动素及其拮抗剂对大鼠消化功能和体重增长的研究。方法:将剂量为0.005-5nmol的motilin和GM109注入大鼠下丘脑室旁核,1小时后可观察到大鼠摄食量显著增加并持续到两小时后。进食量的计算是通过预先称量好的鼠粮和应用药物20分钟、1小时、两小时后剩余数量比较而得出。实验持续一周。将实验组和对照组的进食量和体重进行比较。结果:室旁核注入胃动素5nmol的实验组和合并应用GM1090.005nmol的实验组在应用药物后1小时和2小时,可观察到摄食量显著增加(p<0.01),一周后体重也增加(p>0.05),然而摄食量的增加有显著性差异,体重的增加并无显著性差异。其他实验组也没有观察到显著性差异。结论:胃动素有调节消化运动,促进胃肠排空,促进食欲的作用。可能由于胃肠排空是频繁的,没有充裕的时间消化吸收,从而体重增加无显著性差异。     

下丘脑室旁核胃动素对消化功能影响的研究

目的：研究下丘脑室旁核注入胃动素及其拮抗剂对大鼠消化功能和体重增长的研究。方法：将剂量为0.005-5nmol的motilin和GM109注入大鼠下丘脑室旁核,1小时后可观察到大鼠摄食量显著增加并持续到两小时后。进食量的计算是通过预先称量好的鼠粮和应用药物20分钟、1小时、两小时后剩余数量比较而得出。实验持续一周。将实验组和对照组的进食量和体重进行比较。结果：室旁核注入胃动素5nmol的实验组和合并应用GM1090.005nmol的实验组在应用药物后1小时和2小时,可观察到摄食量显著增加（p〈0.01）,一周后体重也增加（p〉0.05）,然而摄食量的增加有显著性差异,体重的增加并无显著性差异。其他实验组也没有观察到显著性差异。结论：胃动素有调节消化运动,促进胃肠排空,促进食欲的作用。可能由于胃肠排空是频繁的,没有充裕的时间消化吸收,从而体重增加无显著性差异。     

大鼠下丘脑室旁核与终纹床核及前额叶皮质间纤维联系的研究

分别注射辣根过氧化物酶（HRP）入大鼠的PVN和BNST,用组织化学的方法在确定注射部位准确的情况下,在PVN、BNST及PFC观察被标记的神经元或轴突末梢,探讨大鼠下丘脑室旁核（PVN）与终纹床核（BNST）及前额叶皮质间（PFC）之间是否存在投射通路;将HRP注射到PVN后,在同侧的BNST见标记的细胞体,在PFC未见标记的细胞体或轴突末梢;将HRP注射到BNST后,在同侧的PVN见标记的轴突末梢,在PFC未见标记的细胞体或轴突末梢。大鼠BNST有神经纤维投射到PVN,PFC与PVN及BNST之间没有直接的或只有极少量的纤维联系,在机体面临威胁性情境时,BNST可能激活HPA轴引发生理和行为反应,PFC是否通过与PVN或BNST的直接或间接的纤维投射实现其调节功能值得关注。     

束缚应激对大鼠下丘脑室旁核、视上核一氧化氮合酶活性的影响

目前已知下丘脑是应激反应的关键性调节中枢,下丘脑内一氧化氮是否参与应激反应尚未见报道。本文运用ＮＡＤＰＨ－ｄ酶组化技术和计算机图象分析方法,对束缚应激大鼠下丘脑室旁核（ＰＶＮ）和视上核（ＳＯＮ）一氧化氮合酶（ＮＯＳ）阳性神经元的相对切面面积和平均灰度进行了分析。结果显示,大鼠在急性束缚应激４小时后,其下丘脑ＰＶＮ和ＳＯＮ内的ＮＯＳ阳性神经元的平均灰度值与正常大鼠比较均明显降低（Ｐ＜０．００１）;ＳＯＮ的ＮＯＳ阳性神经元的相对切面面积明显大于正常大鼠（Ｐ＜０．００１）,但ＰＶＮ的ＮＯＳ阳性神经元的相对切面面积未见明显改变（Ｐ＞０．０５）。以上结果说明束缚应激使大鼠下丘脑ＰＶＮ和ＳＯＮ的ＮＯＳ活性增强     

糖皮质激素对大鼠下丘脑薄片室旁核神经元放电的影响

自60年代以来,许多整体电生理实验结果表明,糖皮质激素能对下丘脑、中脑、海马和脊髓等部位的神经元电活动产生快速而且短暂的影响。这类反应的潜伏期只有数秒到数分钟,因此糖皮质激素不可能通过基因机制起作用,它可能还存在着其他的作用方式。目前已有生化实验的资料证实,两栖类和哺乳类某些细胞的质膜上存在糖皮质激素的膜结合位点。本室以往的研究结果亦提示在豚鼠腹腔神经     

胃动素对大鼠下丘脑胃牵张敏感神经元和胃运动的影响(英文)

目的:研究胃动素对下丘脑弓状核胃牵张敏感神经元放电活动和胃运动的影响。方法:采用4管玻璃微电极细胞外记录胃动素对大鼠弓状核胃牵张敏感神经元活动,采用胃内置传感器观察胃动素对对清醒大鼠胃运动的影响。结果:65.5%的弓状核神经元为胃扩张敏感性神经元,其中55.6%为胃扩张兴奋性神经元,44.4%为抑制性神经元。胃扩张刺激后兴奋性神经元的放电频率显著增加(P<0.01),而抑制性神经元的放电频率显著降低(P<0.01)。弓状核内微量注射胃动素,70%的兴奋性神经元在胃扩张刺激后表现为兴奋作用,17.5%的神经元表现为抑制作用,并且放电频率显著增加(P<0.05)。同样,在抑制性神经元中,65.6%在注射胃动素后引起电活动增强,放电频率显著降低(P<0.05)。而胃动素受体拮抗剂GM-109可以完全阻断这种由胃动素诱导的兴奋作用,提示,胃动素在弓状核通过其特异性受体调控神经元活动。在胃运动实验中,弓状核微量注射胃动素后,胃运动的收缩频率和幅度都显著增加(P<0.05);同时,这种兴奋作用也可被GM-109阻断。结论:研究证实了弓状核胃动素神经元接收来自胃感受器的外周躯体感觉传入神经的冲动,并通过某些下级核团通路发挥...     

下丘脑室旁核的心血管调节功能研究进展

下丘脑室旁核 (PVN)是自主性和内分泌性反应的重要整合中枢 ,且在维持心血管活动的动态平衡中起着关键作用。本文简要归纳了PVN的形态结构、纤维联系 ,并详细叙述其对心血管活动的调节及与心血管疾病的关系。     

皮质酮对大鼠下丘脑薄片室旁核神经元自发电活动的影响

本实验应用离体大鼠下丘脑薄片技术,用玻璃微电极细胞外记录、观察了下丘脑室旁核神经元的自发电活动,以及皮质酮对自发电活动的影响。在36个下丘脑薄片上观察了104个室旁核神经元的自发电活动,其放电形式主要有三种:慢而不规则(50个,占48.1%)、快速连续(44个,占42.5%)和周期性放电(10个,9.4%)。在进行皮质酮灌流的实验中,这104个单位有25个在皮质酮(10~(-7),10~(-6)mol/L)作用后,自发放电明显减少,有8个单位出现兴奋效应;其余的没有观察到明显反应。上述33个产生反应的神经元其反应特点是:潜伏期短、反应的程度与皮质酮浓度有关、糖皮质激素胞液受体阻断剂 RU38486可以阻断这种反应。结果表明糖皮质激素可以快速影响下丘脑薄片内某些室旁核神经元的电活动,为甾体激素的快速非基因机制作用提供了新的证据,提示室旁核神经元膜上有糖皮质激素受体存在。     

中枢外源性胃动素对大鼠脑干胃相关神经元电活动及胃运动的影响

用核团或侧脑室微量注射、微电极细胞外单位放电记录及清醒动物胃运动记录等方法,观察了大鼠下丘脑腹内侧区（ｖｅｎｔｒａｌ ｍｅｄｉａｌ ｈｙｐｏｔｈａｌａｍｕｓ,ＶＭＨ）或侧脑室内（ｉｃｖ）微量注入胃动素（ｍｏｔｉｌｉｎ）对延髓迷走复合体（ｄｏｒｓａｌ ｖａｇａｌ ｃｏｍｐｌｅｘ,ＤＶＣ）神经元电活动和胃运动的影响。结果表明：（１）ＶＭＨ注入胃动素会改变ＤＶＣ胃相关神经元的电活动;（２）ＶＭＨ及侧脑室     

下丘脑室旁核加压素能神经元参与电针刺激对实验性...

It has been demonstrated in animal model of somatic pain that hypothalamic paraventricular nucleus (PVN) participates in acupuncture analgesia, probably by mediation of vasopressin release. The role of PVN in acupuncture analgesia for experimental visceral pain in rats was further investigated in the present study. Experimental results demonstrated that electroacupuncture could inhibit the writhing response, produced by intraperitoneal injection of antimonium potassium tartrate and this inhibitory effect could be enhanced by electrical stimulation of PVN, but decreased by electrolytical lesion of PVN, intracerebroventricular injection of vasopressin antiserum (14 microliters) or the vasopressin antagonist, d(CH2)5Tyr(Me)-AVP (500 ng/5 microliters). Intraperitoneal administration of the latter drug (10 micrograms/kg), however, was ineffective. The above experimental results suggest that vasopressinergic neurons in PVN also participate in the inhibition of visceral pain by electroacupuncture.     

大鼠下丘脑外侧区内微量注射胃动素对胃窦运动和迷走背核复合体神经元电活动的影响

采用清醒大鼠胃运动记录和玻璃微电极记录神经元活动的实验方法 ,研究下丘脑外侧区 (lateralhy pothalamicarea,LHA)微量注射胃动素 (motilin) ,对清醒大鼠胃窦运动和对麻醉大鼠迷走背核复合体 (dorsalvagalcomplex ,DVC)中胃扩张敏感神经元电活动的调节作用。LHA内微量注射胃动素 (0 37nmol/ 0 5 μl)可使胃窦运动增强 76 2 9± 4 0 9% (P <0 0 1)。DVC中 6 0个胃扩张 (gastricdistention ,GD)敏感神经元中 ,39(6 5 % )个GD刺激引起电活动增强 ,2 1(35 % )个电活动减弱 ,分别称之为GD兴奋型神经元和GD抑制型神经元。双侧LHA微量注射胃动素 0 37nmol/ 0 5 μl,14个GD抑制型神经元中有 12个单位放电频率增加 4 4 35± 7 89% (P <0 0 1) ;2 4个GD兴奋型神经元中有 15个单位放电频率减少 7 17± 7 89% (P <0 0 5 )。结果提示 ,中枢胃动素可能通过LHA-DVC-迷走神经实现对胃窦运动的调控     

胃动素受体激动剂红霉素对大鼠下丘脑葡萄糖反应神经元的作用

目的:通过观察胃动素受体激动剂红霉素对大鼠下丘脑中葡萄糖反应神经元电活动的影响,探讨中枢胃动素对摄食活动调控的机制.方法:应用细胞外记录神经元单位放电的方法,记录麻醉大鼠LHA及VMH的神经元电活动.左颈总动脉注射0.56 mol/L葡萄糖溶液0.2 ml鉴别GSNs及GRNs;侧脑室注射红霉素4 μg,观察其对葡萄糖反应神经元及非葡萄糖反应神经元自发放电频率的影响;侧脑室注射GM-109(胃动素受体拮抗剂)与红霉素的混合剂(1:50的比例配制),观察上述效应是否可重复出现.结果:在LHA,红霉素对GSNs有明显的兴奋作用,与其对该核团NGSNs的作用相比较,差别有统计学意义(P＜0.05);在VMH,红霉素对GRNs有明显的抑制作用,与其对该核团NGRNs的作用相比较,差别有统计学意义(P＜0.01).对红霉素有反应的神经元在给予GM-109和红霉素的混合剂后,神经元的放电频率无明显变化.结论:胃动素受体激动剂红霉素可兴奋LHA-GSNs同时抑制VMH-GRNs,这一途径可能是中枢胃动素促进摄食活动的神经调节机制之一.     

Development of the human hypothalamus

The hypothalamus has been claimed to be involved in a great number of physiological functions in development, such as sexual differentiation (gender, sexual orientation) and birth, as well as in various developmental disorders including mental retardation, sudden infant death syndrome (SIDS), Kallman's syndrome and Prader-Willi syndrome. In this review a number of hypothalamic nuclei have therefore been discussed with respect to their development in health and disease. The suprachiasmatic nucleus (SCN) is the clock of the brain and shows circadian, and seasonal fluctuations in vasopressin-expressing cell numbers. The SCN also seems to be involved in reproduction, adding interest to the sex differences in shape of the vasopressin-containing SCN subnucleus and in its VIP cell number. In addition, differences in relation to sexual orientation can be seen in this perspective. The vasopressin and VIP, neurons of the SCN develop mainly postnatally, but as premature children may have circadian temperature rhythms, a different SCN cell type is probably more mature at birth.Thesexually dimorphic nucleus (SDN, intermediate nucleus, INAH-1), is twice as large in young male adults as in young females. At the moment of birth only 20% of the SDN cell number is present. From birth until two to four years of age cell numbers increase equally rapidly in both sexes. After this age cell numbers start to decrease in girls, creating the sex difference. The size of the SDN does not show any relationship to sexual orientation in men. The large neurosecretory cells of thesupraoptic (SON) andparaventricular nucleus (PVN) project to the neurohypophysis, where they release vasopressin and oxytocin into the blood circulation. In the fetus these hormones play an active role in the birth process. Fetal oxytocin may initiate or accelerate the course of labor. Fetal vasopressin plays a role in the adaptation to stress—caused by the birth process—by redistribution of the fetal blood flow.Corticotropin-releasing hormone (CRH) neurons of the PVN play a central role in stress response. Thus fetal CRH neurons may play a role in the timing of the moment of birth. Recently, alterations have been described in peptidergic, aminergic and cholinergic transmitters in the hypothalamus in SIDS. Future research will have to establish whether these changes are part of the course of SIDS. A large proportion of the SON and PVN neurons also produce tyrosine hydroxylase (TH). In neonates the majority of TH-immunoreactive neurons colocalizes vasopressin, while in the adult the majority of TH-positive neurons colocalizes oxytocin. TH-expression might be a sign of hyperactivation, for example from perinatal hypoxia.Oxytocin neurons also project to the brain stem. These neurons have an inhibitory effect on eating. Interestingly, in the Prader-Willi syndrome, characterized for example by insatiable hunger, we have found that the number of oxytocin-expressing neurons is about half the normal value. It can be concluded that the various hypothalamic nuclei are involved in a great number of functions and show clear and differential changes in development with respect to sexual differentiation, birth and a number of diseases. I believe that only a small proportion of such changes has at present been revealed.Special issue dedicated to Dr. Robert Balázs     

清醒大鼠室旁核灌流谷氨酸受体阻断剂对压力感受性反射的影响

目的:探讨下丘脑室旁核(PVN)内谷氨酸参与压力感受性反射中枢调节的神经化学机制。方法:在清醒大鼠,用脑部微量透析法和高效液相色谱法观察静脉注射苯肾上腺素诱发压力感受性反射对PVN区谷氨酸含量的影响;NMDA受体阻断剂MK-801或非NMDA受体阻断剂CNQX直接灌流PVN区并诱发压力感受性反射,进一步探讨PVN区谷氨酸对压力感受性反射的作用。结果:①静脉注射苯肾上腺素诱发压力感受性反射时,PVN内的谷氨酸含量迅速升高到注射前的384.82%±91.77%(P<0.01)。②PVN区灌流谷氨酸受体阻断剂MK-801或CNQX,同时诱发压力感受性反射,其血压升值明显减少,心率降值明显增加(P<0.01),压力感受性反射的敏感性(△HR/△MAP)明显增加(P<0.01)。结论:PVN内的谷氨酸可能通过离子型谷氨酸受体参与压力感受性反射的中枢调节,而且此调节作用可能是抑制性的。     

杏仁中央核在躯体传入冲动抑制中枢性升压反应中的作用

目的:阐明电刺激腓深神经(DPN)对下丘脑室旁核(PVN)兴奋后的心血管反应的调节作用及杏仁中央核(CeA)在此作用中的地位。方法:电刺激SD大鼠中枢核团PVN,或用核团(CeA)内微量注射法注射L-谷氨酸钠(L-Glu)或红藻氨酸(KA)。同时记录大鼠股动脉血压、平均动脉压(MAP)、心电图及心率(HR)曲线。结果:电刺激一侧PVN后,MAP升高,HR变化不一,以下降为主。电刺激腓深神经对PVN兴奋诱发的升压反应有抑制作用。在同侧CeA微量注射0.02mol/L的KA100nl,10min后刺激PVN,血压升高(13.8±3.2)mmHg,较注射KA前削弱了(6.6±1.6)mmHg(P<0.05),DPN对刺激PVN的升压反应的抑制百分比也从51.5%降为32.0%。结论:杏仁中央核部分介导了PVN兴奋后引起的升压反应。DPN传入冲动对PVN中枢性升压反应有抑制作用,其机制可能与杏仁中央核有关。     

烫伤对大鼠下丘脑室旁核内皮素—1合成和分泌的影响

目的研究烫伤后下丘脑室旁核(PVH)内皮素-1(ET-1)的合成和分泌改变,探讨PVHET-1在烫伤中的病理生理学意义。方法用原位杂交和免疫组织化学方法观察了烫伤后PVHET-1合成和分泌的变化,并用通用图象颗粒分析法检测单位面积内ET-1mRNA阳性杂交信号的强度和ET-1样免疫反应物(ET-1-ir)免疫反应强度。结果烫伤后15minPVH神经元胞浆内ET-1mRNA阳性杂交信号与对照组相比未见明显差异,烫伤后60min和180minPVH神经元胞浆内ET-1mRNA阳性杂交信号较对照组(100％±25％)明显增多,强度明显增高,分别为138％±26％(P<0．05)和167％±18％(P<0.01);而烫伤后15minPVH神经元胞浆内ET-1阳性反应物明显减少,免疫反应物强度为6．3％±1．5％,显著低于对照组(P<0．01),烫伤后60min和180min逐渐回升,分别为23．1％±2．9％和44．1％±3．8％,但仍显著低于对照组(P＜0．01)。结论烫伤后PVHET-1合成和分泌增加。     

Colchicine Treatment Differently Affects Releasable Thyrotropin-Releasing Hormone (TRH) Pools in the Hypothalamic Paraventricular Nucleus (PVN) and the Median Eminence (ME)

1. Hypophysiotropic thyrotropin-releasing hormone (TRH) is synthesized in the hypothalamic paraventricular nucleus (PVN) and transported to the median eminence (ME) where it enters the hypophyseal portal blood. TRH in the ME is situated exclusively in nerve terminals, whereas TRH in the PVN and septum is of extrinsic (nerve terminals) as well as intrinsic (perikarya) origin. 2. To determine the source and possible differential regulation of TRH release from these structures, we blocked TRH axonal delivery by i.c.v. administration of colchicine into the lateral cerebral ventricle of euthyroid or hypothyroid rats in doses of 7.5 μg or 7.5, 75 and 100 μg, respectively, two days prior to the evaluation of the TRH secretion from the PVN, ME and the septum in vitro. 3. In euthyroid rats a low dose of colchicine did not significantly affect plasma TSH. The secretory response to both ethanol in an isosmolar medium and a high K⁺ in the ME as well as the PVN explants was well preserved. However, colchicine treatment resulted in the significant increase of basal secretion of TRH from the PVN. 4. Hypothyroidism induced by 200 mg/l methimazole in drinking water for two weeks resulted in growth arrest, elevated plasma thyrotropin and decreased TRH content in the PVN and the ME. Colchicine partially decreased elevated plasma thyrotropin and increased the TRH content in the PVN and its basal release in vitro which was independent of extracellular Ca²⁺. Interestingly, a TRH release from the PVN could not be further stimulated either by K⁺ membrane depolarization or by ethanol. TRH responsiveness to the stimulation remained unaffected in the ME. The effect of colchicine on the septal TRH secretion was intermediate between the effect observed in the PVN and the ME. 5. In conclusion, the absence of a TRH secretory response to stimuli in the PVN after colchicine disruption of the microtubules and Golgi system suggests that stimulated TRH release observed from the PVN explants in vitro occurs from nerve terminals projecting to the PVN from other brain regions. The independence from extracellular calcium implies that TRH released under the non-stimulating conditions occurs most likely via the constitutive secretory pathway from dendrites and/or perikarya. Regulation of septal TRH is markedly different from the hypophysiotropic one. An erratum to this article is available at .     

Role of alpha-1-adrenergic receptors in the regulation of corticotropin-releasing hormone mRNA in the paraventricular nucleus of the hypothalamus during stress

SUMMARY 1. The role of 1-adrenergic receptors on CRH mRNA levels in the PVN was studied in control and stressed rats receiving i.c.v. injections of the 1-adrenergic agonist, methoxamine, or the 1- antagonist, prazosin.2. Plasma ACTH increased significantly 60 min and 4 hr after a single injection of methoxamine (100 g, i.c.v.). No desensitization of this response was observed after repeated injections every 6 hr for 24 hr. Concomitantly, POMC mRNA in the anterior pituitary increased by 25% at 4 hr after a single injection and by 96% after repeated injections.3. CRH mRNA levels in the PVN increased by 131% after repeated injections for 24 hr, but were unchanged 4 hr after a single injection. Central 1-adrenergic blockade with prazosin did not prevent the increases in CRH mRNA following 4 hr of acute stress, but significantly reduced the increases observed 24 hr after an i.c.v. injection of 75 g of colchicine or after repeated i.p. hypertonic saline injections every 8 hr.4. These studies demonstrate that while 1-adrenergic receptors contribute to long-term increases of CRH mRNA levels in the PVN during prolonged stress, other factors are likely to be involved in the stimulation of CRH mRNA following acute stimulation.     

Altered pattern of vasopressin distribution in the hypothalamus of rats subjected to immobilization stress

Summary Generally, the CRF-like activity of vasopressin is studied in experiments involving adrenalectomy and corticosteroid replacement. In order to avoid this complex type of stress, male and female (diestrus, estrus) rats were exposed for 5min to immobilization stress and sacrificed 5, 15, and 30 min thereafter. After a survival period of 5 min the vasopressin-synthesizing part of the paraventricular nucleus exhibited an increased activity. Vasopressin-reactive axons in the pericapillary layer of the median eminence and among the solid cell clusters of the pars tuberalis became more conspicuous and increased in number. In this group of experimentally treated animals the prechiasmatic division of the supraoptic nucleus did not show any changes in immunoreactivity. The same holds true for the neurohypophyses in all experimental groups. In animals with increased survival times the supraoptic nucleus exhibited a slightly increased activity, whereas the staining intensity of the paraventricular nucleus decreases gradually. From these results it can be concluded that the paraventricular nucleus is involved in the first phase of the stress response. The problem of vasopressin or a very similar peptide synthesized in this nucleus and exerting a CRF-releasing function is discussed.The author wishes to express her sincere gratitude to Dr. A. Weindl, Munich, for supplying the antivasopressin and to Dr. L.A. Sternberger, Edgewood Arsenal for generously supplying the PAP-complex. The skillful technical assistance of Mrs. Helga Prien is thankfully acknowledgedDedicated to Prof. Dr. Helmut Leonhardt on the occasion of his 60th birthdaySupported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr569/1) and Stiftung Volkswagen-werk