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胃运动影响的探讨

目的 :研究下丘脑室旁核 (paraventricularnucleus,PVN)胃动素对胃运动调节的参与作用及机制。 方法 :应用免疫组织化学的方法检测室旁核内胃动素神经元的表达情况及室旁核与延髓迷走复合体 (dorsalvagalcomplex ,DVC)间的神经联系 ,应用室旁核内微量注入胃动素的方法观察清醒大鼠胃运动的变化。结果 :①下丘脑室旁核有胃动素免疫阳性细胞 ,在饥饿组和十二指肠灌酸组 ,阳性细胞数有明显增加 (P <0 .0 1)。②迷走背核注入辣根过氧化物酶 (horseradishperoxidase ,HRP) ,在室旁核发现HRP标记细胞 ,证实室旁核与DVC间的纤维联系。③清醒大鼠室旁核内微量注射胃动素可使胃运动的幅度和频率明显增加 (P <0 .0 5 ) ,切断双侧膈下迷走神经后 ,胃动素对胃运动的作用消失。结论 :下丘脑室旁核内胃动素可增强胃运动 ,其作用可能是通过下丘脑 延髓迷走复合体 迷走神经实现的     

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。     

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     

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。     

下丘脑室旁核orexin-A对大鼠摄食和胃动力影响及调控机制

目的:探讨下丘脑室旁核orexin-A对大鼠摄食和胃动力影响及调控机制。方法:采用免疫组化观察下丘脑室旁核(paraventricular nucleus,PVN)orexin受体表达情况;PVN注射orexin-A观察大鼠摄食、胃运动、胃酸分泌和胃排空的改变。结果:免疫组化实验显示大鼠PVN中存在orexin受体免疫阳性细胞。PVN注射orexin-A后,大鼠前三小时摄食增加,6 h和24 h摄食无显著改变。PVN微量注射orexin-A后,大鼠胃运动幅度和频率增加、胃排空增快并且胃酸分泌增多。[D-Lys-3]-GHRP-6可部分阻断orexin-A对摄食、胃运动、胃排空和胃酸分泌的促进作用,SB334867可完全阻断orexin-A对胃运动、胃排空和胃酸分泌的促进作用。结论:下丘脑室旁核orexin-A可能通过生长激素促泌素GHSR受体信号通路调控大鼠摄食及胃功能。     

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.     

弧束核参与剌激下丘脑室旁核的镇痛作用

This study was undertaken to evaluate the analgesic effect of paraventricular nucleus (PVN) stimulation with tail stimulation-vocalization test. The mechanism of this analgesia was analysed with nuclear lesion and microinjection technique. The main results were as follows: (1) Electrical stimulation of the PVN could significantly enhance the pain threshold and increase the content of AVP in brainstem measured by radioimmunoassay. (2) Solitary tract nucleus (STN) lesion could eliminate the analgesic effect induced by PVN stimulation. (3) Intranuclear microinjection of AVP-antagonist and AVP-antiserum into the STN could block the analgesic effect of PVN stimulation. (4) Intranuclear microinjection of AVP into the STN could mimick the analgesic effect similar to that of PVN stimulation. These results suggest that electrical stimulation of the PVN could produce an analgesic effect. This effect might be mediated by the activation of VP-ergic neurons in PVN and upon releasing VP from the descending fibers, the activities of neurons in the STN are influenced.     

大鼠下丘脑室旁核神经元对电刺激迷走神经的反应

用玻璃微电极记录了93只大鼠的1059个PVH单位的电活动,观察了电刺激颈部迷走神经对PVH单位自发放电的效应和所引起的PVH单位的诱发反应。电刺激迷走神经分别使46个及10个PVH单位呈诱发兴奋和抑制反应。给予迷走神经以不同强度的刺激时,发现PVH神经元对激活A和C两类纤维的强刺激反应,而对仅激活A类纤维的弱刺激则不反应。PVH单位对电刺激坐骨神经或迷走神经的反应有以下几种:对迷走神经和坐骨神经刺激均作出兴奋或抑制反应;仅对迷走刺激作出兴奋或兴奋-抑制反应,而对坐骨神经刺激不反应;对坐骨神经刺激作出兴奋反应,而对迷走神经刺激不反应。讨论了迷走神经到室旁核的中枢传导特点以及内脏传入和躯体传入信息在PVH单位会聚的可能意义。     

刺激和损毁下丘脑室旁核对针刺镇痛的影响

本文采用脑刺激和损毁法,探讨了大鼠下丘脑室旁核(PVH)在针刺镇痛中的作用。结果表明:电刺激PVH及PVH内微量注射谷氨酸钠均可增强“足三里”的针刺镇痛效果,呈量效关系;电解损毁PVH则削弱针刺镇痛效果;去除脑下垂体不能抑制PVH内注射谷氨酸钠的作用。     

Nuclear inclusions in paraventricular nucleus neurons of the rat hypothalamus

Summary This paper deals with the ultrastructure of two types of intranuclear inclusions, microfilamentous spindle-shaped and crystalloid, present in paraventricular nucleus neurons of adult normal rats. These inclusions appear occasionally in some non-secretory neurons of the parvocellular system, but have never been seen in neurosecretory cells of the magnocellular system. The microfilamentous spindle-shaped inclusions show a close spatial relationship with the granulofibrillar body and interchromatin granules.The distribution and functional significance of such structures are discussed in the light of recent ultrastructural and biochemical studies on nuclear inclusions.     

Ultrastructural characteristics of vasopressin-containing neurons in the paraventricular nucleus of the hypothalamus

Summary Vasopressin-containing neurons, identified by immunocytochemistry, are located predominantly in the posterior magnocellular division of the paraventricular nucleus of the rat hypothalamus. By electron microscopy, the immunoreaction product is seen within the cell bodies and neuronal processes. In the perikarya and dendritic processes, the immunoreactive material is associated primarily with neurosecretory granules. Axonal processes, identified by their content of microtubules and accumulation of neurosecretory granules, show the immunoreaction product in association with both of these organelles. Afferent axo-dendritic, axo-somatic and putative axo-axonic synapses with immunostained vasopressinergic neurons can be identified. The presynaptic profiles do not contain immunoreactive material. This study contributes to the ultrastructural characterization of vasopressinergic neurons in the paraventricular nucleus and of their afferent synaptic input.Supported by NIH Grants HD-12956 and 2SO7RR05403     

Hypoxia activates nucleus tractus solitarii neurons projecting to the paraventricular nucleus of the hypothalamus

Peripheral chemoreceptor afferent information is sent to the nucleus tractus solitarii (nTS), integrated, and relayed to other brain regions to alter cardiorespiratory function. The nTS projects to the hypothalamic paraventricular nucleus (PVN), but activation and phenotype of these projections during chemoreflex stimulation is unknown. We hypothesized that activation of PVN-projecting nTS neurons occurs primarily at high intensities of hypoxia. We assessed ventilation and cardiovascular parameters in response to increasing severities of hypoxia. Retrograde tracers were used to label nTS PVN-projecting neurons and, in some rats, rostral ventrolateral medulla (RVLM)-projecting neurons. Immunohistochemistry was performed to identify nTS cells that were activated (Fos-immunoreactive, Fos-IR), catecholaminergic, and GABAergic following hypoxia. Conscious rats underwent 3 h normoxia (n = 4, 21% O(2)) or acute hypoxia (12, 10, or 8% O(2); n = 5 each). Hypoxia increased ventilation and the number of Fos-IR nTS cells (21%, 13 ± 2; 12%, 58 ± 4; 10%, 166 ± 22; 8%, 186 ± 6). Fos expression after 10% O(2) was similar whether arterial pressure was allowed to decrease (-13 ± 1 mmHg) or was held constant. The percentage of PVN-projecting cells activated was intensity dependent, but contrary to our hypothesis, PVN-projecting nTS cells exhibiting Fos-IR were found at all hypoxic intensities. Notably, at all intensities of hypoxia, ～75% of the activated PVN-projecting nTS neurons were catecholaminergic. Compared with RVLM-projecting cells, a greater percentage of PVN-projecting nTS cells was activated by 10% O(2). Data suggest that increasing hypoxic intensity activates nTS PVN-projecting cells, especially catecholaminergic, PVN-projecting neurons. The nTS to PVN catecholaminergic pathway may be critical even at lower levels of chemoreflex activation and more important to cardiorespiratory responses than previously considered.     

Injection of muscimol in dorsomedial hypothalamus and stress-induced Fos expression in paraventricular nucleus

Prior microinjection of the GABA(A)-receptor agonist muscimol into the dorsomedial hypothalamus (DMH) in conscious rats attenuates the increases in heart rate, blood pressure, and circulating adrenocorticotrophic hormone seen in air stress. Here, we examined the effect of similar treatment on air stress- or hemorrhage-induced Fos expression in the paraventricular nucleus (PVN). Muscimol (80 pmol/100 nl per side) or saline (100 nl per side) was microinjected bilaterally into the DMH in conscious rats before either air stress, an emotional or neurogenic stressor, or graded hemorrhage, a physiological stressor. Each stressor evoked a characteristic pattern of Fos expression in the parvocellular and magnocellular PVN after saline. Injection of muscimol into the DMH suppressed Fos expression in the PVN associated with air stress but not with hemorrhage. Injection of muscimol at sites anterior to the DMH and closer to the PVN had no effect on Fos expression in the PVN after air stress. Thus activation of neurons in the DMH is necessary for excitation of neurons in the PVN during air stress but not during hemorrhage.     

Injection of neuropeptide W into paraventricular nucleus of hypothalamus increases food intake

Neuropeptide W (NPW) is an endogenous ligand for G protein-coupled receptor 7 (GPR7). There are two forms of the peptide, designated as neuropeptide W-23 (NPW23) and neuropeptide W-30 (NPW30). In the current study we found that intracerebroventricular administration of NPW23 increased c-Fos immunoreactivity (IR) in a variety of brain sites, many of which are involved in the regulation of feeding. In particular, we noted that c-Fos IR levels were increased in hypocretin-expressing neurons in the perifornical region of the lateral hypothalamus (LH). We then studied whether injection of NPW23 into the paraventricular nucleus of the hypothalamus (PVN) and the LH increased food intake over a 24-h time period. Intra-PVN injection of NPW23 at doses ranging from 0.1 to 3 nmol increased feeding for up to 4 h, and doses ranging from 0.3 to 3 nmol increased feeding for up to 24 h. In contrast, only the 3-nmol dose of NPW23 increased feeding after administration into the LH. Together, these data suggest a modulatory role for NPW in the control of food intake.     

Relationship of CRF-immunostained cells and magnocellular neurons in the paraventricular nucleus of rat hypothalamus

The distribution of corticotropin-releasing factor (CRF), vasopressin (VP) and oxytocin (OXY) containing neurons within the magnocellular and parvocellular divisions in the paraventricular nucleus (PVN) of rat hypothalamus is described in brains from normal untreated, colchicine treated and adrenalectomized animals. Double immunostained preparations using glucose oxidase-antiglucose oxidase (GAG) complex combined with PAP complex to visualize two antigens with contrasting colors in the same tissue sections were employed. Separate and distinct populations of cells containing the immunoreactive (ir) elements were seen. Immunostained CRF neurons present in the ventral medial portion of the posterior magnocellular division were juxtaposed to oxytocin-ir perikarya in colchicine treated and adrenalectomized animals. CRF-ir cells were for the most part concentrated in the medial parvocellular component of PVN. An intimate anatomical proximity between CRF-ir and VP-ir perikarya was evident in this medial parvocellular division in brains of adrenalectomized animals; this area is normally VP-ir poor except in the adrenalectomized rats. This extension of VP-ir cells into this CRF rich region and the very close approximation between the two cell bodies suggests potential cell to cell communication following perturbation of the brain-pituitary-adrenal axis. No evidence for the co-existence of two peptidergic systems in the same neuron was apparent in the present study.     

Metabolic effects of galanin injections into the paraventricular nucleus of the hypothalamus.

The metabolic effects of single injections of galanin into the paraventricular nucleus of the hypothalamus (PVN) were investigated in an open-circuit calorimeter. Wistar rats were tested, with no food available during the tests. In the dose range of 0.03-0.3 nmol, galanin produced a very short-latency (approximately 2 minutes) and short-lasting (approximately 15 minutes) reduction in energy expenditure. Since the same doses had no effect on respiratory quotient or locomotor activity, the metabolic effect is not secondary to changes in energy substrate utilization or locomotor activity. This antithermogenic effect complements the eating stimulatory action of PVN galanin, and together these phenomena suggest a role for galanin as an anabolic neuropeptide. The similarity of galanin's effects to those of norepinephrine, with which it coexists in PVN nerve endings, further suggests the involvement of this amine and the PVN alpha2-noradrenergic system in galanin's mechanism of action.     

Developmental switch in neuropeptide Y and melanocortin effects in the paraventricular nucleus of the hypothalamus

Homeostatic regulation of energy balance in rodents changes dramatically during the first 3 postnatal weeks. Neuropeptide Y (NPY) and melanocortin neurons in the arcuate nucleus, a primary energy homeostatic center in adults, do not fully innervate the paraventricular nucleus (PVN) until the third postnatal week. We have identified two classes of PVN neurons responsive to these neuropeptides, tonically firing neurosecretory (NS) and burst-firing preautonomic (PA) cells. In neonates, NPY could inhibit GABAergic inputs to nearly all NS and PA neurons, while melanocortin regulation was minimal. However, there was a dramatic, age-dependent decrease in NPY responses specifically in the PA neurons, and a 3-fold increase in melanocortin responses in NS cells. These age-dependent changes were accompanied by changes in spontaneous GABAergic currents onto these neurons. This primarily NPYergic regulation in the neonates likely promotes the positive energy balance necessary for growth, while the developmental switch correlates with maturation of homeostatic regulation of energy balance.     

Regulation of thyrotropin-releasing hormone-expressing neurons in paraventricular nucleus of the hypothalamus by signals of adiposity

Fasting-induced suppression of thyroid hormone levels is an adaptive response to reduce energy expenditure in both humans and mice. This suppression is mediated by the hypothalamic-pituitary-thyroid axis through a reduction in TRH levels expressed in neurons of the paraventricular nucleus of the hypothalamus (PVN). TRH gene expression is positively regulated by leptin. Whereas decreased leptin levels during fasting lead to a reduction in TRH gene expression, the mechanisms underlying this process are still unclear. Indeed, evidence exists that TRH neurons in the PVN are targeted by leptin indirectly via the arcuate nucleus, whereas correlative evidence for a direct action exists as well. Here we provide both in vivo and in vitro evidence that the activity of hypothalamic-pituitary-thyroid axis is regulated by both direct and indirect leptin regulation. We show that both leptin and α-MSH induce significant neuronal activity mediated through a postsynaptic mechanism in TRH-expressing neurons of PVN. Furthermore, we provide in vivo evidence indicating the contribution of each pathway in maintaining serum levels of thyroid hormone.