prepro-orexin 细胞及其神经纤维在致痫模型大鼠中的变化

目的:研究癫痫模型大鼠中prepro-orexin及其神经纤维在不同时间点的变化情况,以阐明prepro-orexin在癫痫发生中的作用,深化癫痫的发病机制。方法:本研究采用海人酸腹腔注射诱发大鼠癫痫发作,并分别于癫痫终止后8小时、1、3、7天和慢性复发时间点行免疫组化方法检测prepro-orexin免疫反应阳性细胞数及其神经纤维的变化情况。结果:prepro-orexin免疫阳性细胞的分布主要在外侧下丘脑和穹窿周围核,在海马、大脑皮层及其他大脑组织中并未检测到,各组之间prepro-orexin阳性细胞数进行方差分析表明其差异并不显著,P>0.05;而其免疫阳性神经纤维主要分布在下丘脑、丘脑室旁核及海马,数量稀少;结论:大鼠致痫后,随着时间的推移,prepro-orexin免疫阳性细胞总体减少,但未具有统计学意义,但并不能完全认为其与癫痫发作无关;而其免疫反应神经纤维稀少。     

癫痫大鼠海马内COX-2表达的时间过程

目的：观察癫痫大鼠海马内环氧化酶-2（COX-2）表达的时间过程。方法：采用匹罗卡品（pilocarpine,30mg·kg^-1）诱导大鼠癫痫发作后,分别于不同时间点取脑和海马组织,通过Western blot分析、免疫组织化学方法检测COX-2的表达。结果：pilocarpine诱导大鼠癫痫发作后,海马内COX-2表达6h开始明显增加,24h达到最高水平,2d开始有所下降,4d时恢复到正常水平。结论：癫痫大鼠海马内COX-2表达有一定时间过程,在癫痫发作24h达到高峰。     

CCK-8对癫痫发作大鼠脑内SOD和MDA的影响

目的和方法：采用核团微量注射、光化学分析等实验方法,观察大鼠脑内ＳＯＤ和ＭＤＡ在ＣＣＫ－８调节癫痫发作中的变化。结果：①与下沉大鼠比较,遗传性听源性癫痫易感大鼠皮层、海马、下丘脑及垂体内ＳＯＤＦ活性、ＭＤＡ含量无显著差异（Ｐ＞０．０５）;②大鼠癫痫发作后,上述区域内ＳＯＤ活性明显降低（Ｐ＜０．０５）,而ＭＤＡ含量明显增加（Ｐ＜０．０５）,若癫痫发作次数增加,该变化愈显著（Ｐ＜０．０１）;③大鼠海马     

氨甲酰胆碱引起的促钠排泄与下丘脑TH—IR神经元活性的变化

目的：我们最近的实验发现大鼠侧脑室注射氨甲酰胆碱引起显著的促钠排泄作用,本工作同时还观察了下丘脑内不同脑区的儿茶酚胺能神经元活性的变化。方法和结果：氨甲酰胆碱注射后４０ｍｉｎ,下丘脑室旁核的腹侧和内侧小细胞部、内侧视前区、尾核、苍白球的酪氨酸羟化酶免疫反应（ｔｈｙｒｏｓｉｎｅｈｙｄｒｏｘｙｌａｓｅｉｍｍｕｎｏｒｅａｃｔｉｖｉｔｙ,ＴＨＩＲ）阳性细胞数减少,免疫反应染色强度降低;下丘脑室旁核的后部,下丘脑前区的后部、下丘脑室周核、弓状核、下丘脑外侧区的ＴＨＩＲ阳性细胞数增多,免疫反应染色强度增强。结论：侧脑室注射氨甲酰胆碱对脑内不同脑区的内源性儿茶酚胺能神经元分别有兴奋或抑制作用,其与促钠排泄的关系将在本文中讨论     

杏仁核注射红藻氨酸诱导大鼠边缘叶癫痫发作时海马中Smac和XIAP蛋白的表达

应用红藻氨酸(kainic acid,KA)诱导的大鼠边缘叶癫痫发作模型,检测第二个线粒体源的半胱天冬蛋白酶激活物,直接与凋亡抑制蛋白结合的低等电点蛋白(second mitochondrial activator of caspases／direct inhibitor of apoptosis protein-binding protein of low isoelectric point[PI],Smac／DIABLO)和X染色体连锁的凋亡抑制蛋白(X-chromosome-linked inhibitor of apoptosis protein,XIAP)在癫痫大鼠海马神经元表达。单侧杏仁核内注射KA诱导癫痫发作,1h后用安定终止发作,然后分别用TUNEL染色和cresyl violet染色观察海马神经元存活和凋亡的变化,用免疫荧光和Western blot检测海马Smac／DIABLO、XIAP和半胱天冬蛋白酶-9(caspase-9)的表达。结果表明,发作终止2h时KA注射同侧海马CA3区细胞浆内Smac／DIABLO蛋白表达增加,4h时caspase-9出现裂解片断,8h时出现TUNEL阳性细胞,24h时达高峰。脑室内注射caspase-9抑制剂z-LEHD-fluoromethyl ketone(z-LEHD-fmk)可减少TUNEL阳性细胞,增加存活神经元。发作后KA注射同侧海马CA3区神经元caspase-9免疫反应性增强,Smac／DIABLO和XIAP弥散于整个神经元内。对侧海马未检测到TUNEL阳性细胞及Smac／DIABLO和XIAP蛋白的上述变化。以上结果提示,癫痫发作可诱导Smac／DIABLO蛋白从线粒体向细胞浆的移位、XIAP亚细胞分布改变和caspase-9的激活,Smac／DIABLO、XIAP和caspase-9可能参与了癫痫神经元损伤的病理生理机制,caspase-9可能是潜在的治疗靶点。     

褪黑素对马桑内酯致痫大鼠海马内SP水平的影响

目的探讨褪黑素（melatonin,MT）对马桑内酯致痫大鼠海马内P物质水平的影响,以探讨褪黑素的抑痫作用机制。方法随机将健康成年雄性SD大鼠40只分为A、B、C、D 4组,每组10只。A组：生理盐水组;B组：马桑内酯组;C组：褪黑素＋马桑内酯组;D组：Luzindole＋褪黑素＋马桑内酯组。观察并记录行为学变化,然后分别采用免疫组织化学方法进行SP免疫组织化学染色,实时荧光定量PCR方法检测海马内SP mRNA含量变化。结果B组和D组大鼠均有不同程度的癫痫发作,而C组大鼠癫痫发作不明显,A组几乎均无发作;免疫组化结果显示,四组大鼠海马各区均有SP免疫反应阳性神经元,B组、D组与A组、C组比海马内SP免疫阳性反应明显增强（P〈0.05）,而A组与C组比无明显差异（P〉0.05）;RT-PCR结果提示,B组、D组与A组、C组相比,大鼠海马内SP mRNA明显升高（P〈0.05）,而A组与C组比无明显差异（P〉0.05）。结论MT能通过下调海马内SP水平抑制癫痫发作。     

马桑内酯激活的星形胶质细胞条件培养液对正常大鼠脑内谷氨酸和GABA的影响

目的探讨星形胶质细胞对大鼠脑内谷氨酸(Glu)和γ-氨基丁酸(GABA)的影响及其在癫痫发病中的作用。方法将马桑内酯激活的星形胶质细胞条件培养液(astrocyte-conditioned medium,ACM)注射入正常SD大鼠侧脑室,观察大鼠的行为变化,运用免疫组织化学及HPLC的方法,观察大鼠大脑皮质、海马内Glu和GABA免疫反应的变化及脑组织匀浆、脑脊液内Glu和GABA含量的变化。结果ACM组大鼠在注射ACM后30min出现癫痫行为,2h恢复正常。免疫组织化学显示:ACM作用后2h,大鼠大脑皮质及海马内Glu免疫反应阳性神经元数和平均光密度值明显增高,4h达高峰(P<0.05),12h恢复正常水平;ACM作用后2h,大鼠大脑皮质及海马GABA免疫反应阳性神经元数和平均光密度值明显减弱(P<0.05),12h恢复正常水平。HPLC方法显示:ACM作用后2h大鼠大脑皮质、海马及脑脊液中Glu含量均开始增加,4h达高峰(P<0.05);ACM作用后2h大脑皮质、海马及脑脊液中GABA含量均开始降低,4h达最低(P<0.05)。结论马桑内酯激活的星形胶质细胞条件培养液可影响大鼠脑内Glu和GABA的表达,并导致动物痫性发作。     

蝎毒对癫痫敏感性和海马GFAP释放的影响

目的和方法 :本工作用海人酸癫痫模型 ,通过对癫痫大鼠蝎毒治疗后行为变化及脑内胶质原纤维酸性蛋白(GFAP)免疫反应活性的检测 ,对蝎毒抗癫痫反复发作的相关脑区及其机制做以初步探讨。结果 :癫痫大鼠蝎毒治疗三周后 ,能明显减少癫痫发作的例数 ,减轻癫痫发作的程度 ,使发作的潜伏期延长 (P <0 .0 5 )。免疫细胞化学的实验显示 ,蝎毒抗癫痫反复发作的相关脑区是海马。 8例蝎毒治疗的大鼠与实验对照组相比 ,有 6例背侧海马GFAP免疫染色明显减轻 ,未见星形胶质细胞增生 ;CA1区无明显神经元缺失 ;而且与空白对照组相比无显著差异。结论 :癫痫大鼠蝎毒治疗三周后 ,能明显减轻癫痫发作的行为 ,抑制海马星形胶质细胞的增生肥大 ,减轻海马神经元受损的程度。蝎毒抑制海马星形胶质细胞增生很可能是蝎毒抗癫痫反复发作的重要机制之一。     

蝎毒诱导红藻氨酸癫痫大鼠海马内GABA释放的免疫组化观察

本工作用红藻氨酸癫痫模型,经蝎毒处理后观察大鼠癫痫发作的行为变化并检测大鼠海马内ＧＡＢＡ免疫反应样物质对国产钳蝎粗毒抗癫痫反复发作的细胞机制进行初步探讨。ＫＡ癫痫大鼠经蝎毒处理３周后,与实验对照组相比,能明显减轻发作行为。ＧＡＢＡ免疫组化的实验显示,用ＫＡ３周后,实验对照组大鼠与空白对照组腹侧海马尤其是海马门区ＧＡＢＡ免疫反应阳性神经元数目明显减少,免疫染色强度明显降低。实验给药组大鼠８例中,有６     

戊四氮致痫大鼠皮质和海马内GFAP、cyclinD1及脑和脑脊液17β-雌二醇和孕酮浓度变化

目的研究癫痫发作后脑和脑脊液中17β-雌二醇和孕酮含量的变化.方法将雌性SD大鼠随机分为戊四氮(PTZ)致痫组和生理盐水对照组.(1)用免疫组织化学方法观察大鼠大脑皮质和海马星形胶质细胞胶质原纤维酸性蛋白(GFAP)含量的变化;(2)用Western blot方法检测大鼠大脑皮质和海马细胞周期素D1(cyclin D1)表达的变化;(3)采用放免法测定大鼠大脑皮质和海马组织匀浆及脑脊液中17β-雌二醇和孕酮含量的变化.结果免疫组织化学染色结果显示癫痫发作4h后在海马CA3区、CA1区和皮质内GFAP免疫反应明显增强(P<0.05);Western blot结果显示癫痫发作2h后cyclin D1的表达在皮质和海马均较对照组明显增强(P<0.05);放射免疫分析结果显示,癫痫发作后,皮质、海马和脑脊液的17β-雌二醇的浓度有不同程度增高,致痫8h后恢复正常,孕酮的浓度在皮质和脑脊液则呈下降趋势.结论戊四氮致痫时皮质及海马内星形胶质细胞激活、增殖,内源性雌激素合成增多,同时孕酮浓度降低,说明雌性激素在癫痫的形成和维持中发挥作用.     

Distribution of gastrin and CCK-like peptides in rat brain

Summary The distribution of gastrin and CCK-like peptides in the rat brain was studied by immunocytochemistry using an antiserum reacting equally well with both groups of peptides. Immunoreactive nerve cell bodies were detected in all cortical areas, in the hippocampus where they were particularly numerous, in the mesencephalic central gray and in the medulla oblongata. After colchicine treatment immunoreactive material appeared also in cell bodies of the magnocellular hypothalamic system. Immunoreactive nerve fibers were widely distributed in the brain. Particularly dense accumulations were seen in the hippocampus near the ventral surface of the brain, in the caudate nucleus, in the interpeduncular nucleus, the parabrachial nucleus, the dorsal part of the medulla oblongata and in the dorsal horn of the spinal cord. In the hypothalamus immunoreactive nerve fibers were observed in all nuclei, being most frequent in the ventromedial, dorsal and lateral hypothalamic nuclei. A rich supply of nerve fibers was seen in the outer zone of the median eminence and in the neurohypophysis. From previous immunochemical analysis it appears that the peptide demonstrated in most parts of the brain is identical with CCK-8. In the neurosecretory cell bodies of the hypothalamus, the median eminence and the neurohypophysis, however, the immunoreactive material is probably identical with gastrin.     

Localization of the CB1 cannabinoid receptor in the rat brain. An immunohistochemical study

The presence of central cannabinoid receptor (CB1), involving the N-terminal 14 amino acid peptide, was demonstrated in the rat brain by immunohistochemistry. Intensely stained neurons were observed in the principal neurons of the hippocampus, striatum, substantia nigra, cerebellar cortex, including the Purkinje cells. Moderate CB1-IR cell bodies and fibers were present in the olfactory bulb, cingulate, entorhinal and piriform cortical areas, amygdala and nucleus accumbens. The perivascular glial fibers have shown moderate to high density CB1-IR in olfactory and limbic structures. Low density was detected in the thalamus and hypothalamus and area postrema. The CB1 receptor was widely distributed in the forebrain and sparsely in the hindbrain. These new data support the view that the endogenous cannabinoids play an important role in different neuronal functions as neuromodulators or neurotransmitters.     

Localization of avian LHRH-immunoreactive neurons in the hypothalamus of the domestic fowl,Gallus domesticus,and the Japanese quail,Coturnix coturnix

The localization of LHRH-containing perikarya and nerve fibers in the hypothalami of the domestic fowl and Japanese quail was investigated by means of the specific immunoperoxidase ABC method, using antisera against chicken LHRH-I ([Gln8]-LHRH), chicken GnRH-II ([His5-Trp7-Tyr8]-LHRH[2-10]) and mammalian LHRH ([Arg8]-LHRH). Chicken LHRH-I-immunoreactive perikarya were sparsely scattered in the nucleus preopticus periventricularis (POP), nucleus filiformis (FIL) and nucleus septalis medialis (SM), and in bilateral bands extending from these nuclei into the septal area in both species. A few reactive perikarya were also observed in the nucleus accumbens (Ac) and lobus parolfactorius (LPO). Numerous cLHRH-I-immunoreactive fibers were widely scattered in the preoptic, septal and tuberal areas, and were densely concentrated in the external layer of the median eminence and in organum vasculosum of the lamina terminalis (OVLT) in both species. Anti-mammalian LHRH serum cross-reacted weakly with perikarya and fibers immunoreactive to anti-cLHRH-I serum in normal chicken and quail. Anti-cGnRH-II[2-10] serum immunoreacted with magnocellular neurons distributed in the rostral end of the mesencephalon along the midline close to the nervus oculomotorius (N III). These perikarya were apparently different from cLHRH-I immunoreactive neurons. No immunoreactive cells and fibers against anti-cGnRH-II[2-10] were observed in the hypothalamus and median eminence of the chicken or quail. Anti-cGnRH-II[2-10] bound specifically with cGnRH-II.(ABSTRACT TRUNCATED AT 250 WORDS)     

CGRP-immunoreactive sensory nerve fibers in the submandibular gland of the rat

Summary Indirect immunofluorescence technique was used to study the occurrence and distribution of CGRP immunoreactivity in the submandibular gland of normal rats and after unilateral sensory and sympathetic denervations. In normal rats, CGRP-immunoreactive nerve fibers and nerve trunks were seen around or in close contact with interlobular salivary ducts as well as around small blood vessels of the gland. Occasionally, CGRP-immunoreactive nerve fibers were also detected between or around the acini of the gland.The submandibular ganglia contained CGRP-immunoreactive nerve fibers, but the ganglion cells were not immunoreactive for CGRP. The trigeminal ganglion contained a population of CGRP-immunoreactive, mainly small sized ganglion cells and nerve fibers distributed throughout the ganglion. Unilateral electrocoagulation of the trigeminal nerve caused a significant reduction in the number of immunoreactive nerve fibers in the gland, although some fibers still were present in the ipsilateral glandular tissue. Unilateral superior cervical ganglionectomy caused no detectable effect on the number of CGRP-immunoreactive nerve fibers in the gland.The present results suggest that the rat submandibular gland contains CGRP-immunoreactive nerve fibers both around blood vessels and in glandular secretory elements. Denervation experiments support the view that the majority, but perhaps not all of them originate from the trigeminal ganglion.     

Thyrotropin-releasing hormone (TRH)-immunoreactive structures in the brain of the domestic mallard

Summary The distribution of immunoreactive thyrotropin-releasing hormone (TRH) in the central nervous system of the domestic mallard was studied by means of the peroxidase-antiperoxidase technique. After colchicine pretreatment, the highest number of TRH-immunoreactive perikarya was found in the parvocellular subdivision of the paraventricular nucleus and in the preoptic region; a smaller number of immunostained perikarya was observed in the lateral hypothalamic area and in the posterior medial hypothalamic nucleus. TRH-immunoreactive nerve fibers were detected throughout the hypothalamus, forming a dense network in the periventricular area, paraventricular nucleus, preoptic-suprachiasmatic region, and baso-lateral hypothalamic area. TRH-containing nerve fibers and terminals occurred in the organon vasculosum of the lamina terminalis and in the external zone of the median eminence in juxtaposition with hypophyseal portal vessels. Scattered fibers were also seen in the internal zone of the median eminence and in the rostral portion of the neural lobe. Numerous TRH-immunoreactive fibers were detected in extra-hypothalamic brain regions: the highest number of immunoreactive nerve fibers was found in the lateral septum, nucleus accumbens, olfactory tubercle, and parolfactory lobe. Moderate numbers of fibers were located in the basal forebrain, dorsomedial thalamic nuclei, hippocampus, interpeduncular nucleus, and the central gray of the mesencephalon. The present findings suggest that TRH may be involved in hypophysiotropic regulatory mechanisms and, in addition, may also act as neuromodulator or neurotransmitter in other regions of the avian brain.     

CGRP-immunoreactive sensory nerve fibers in the submandibular gland of the rat

Indirect immunofluorescence technique was used to study the occurrence and distribution of CGRP immunoreactivity in the submandibular gland of normal rats and after unilateral sensory and sympathetic denervations. In normal rats, CGRP-immunoreactive nerve fibers and nerve trunks were seen around or in close contact with interlobular salivary ducts as well as around small blood vessels of the gland. Occasionally, CGRP-immunoreactive nerve fibers were also detected between or around the acini of the gland. The submandibular ganglia contained CGRP-immunoreactive nerve fibers, but the ganglion cells were not immunoreactive for CGRP. The trigeminal ganglion contained a population of CGRP-immunoreactive, mainly small sized ganglion cells and nerve fibers distributed throughout the ganglion. Unilateral electrocoagulation of the trigeminal nerve caused a significant reduction in the number of immunoreactive nerve fibers in the gland, although some fibers still were present in the ipsilateral glandular tissue. Unilateral superior cervical ganglionectomy caused no detectable effect on the number of CGRP-immunoreactive nerve fibers in the gland. The present results suggest that the rat submandibular gland contains CGRP-immunoreactive nerve fibers both around blood vessels and in glandular secretory elements. Denervation experiments support the view that the majority, but perhaps not all of them originate from the trigeminal ganglion.     

Immunohistochemical and immunocytochemical localization of γ-melanocyte stimulating hormone (γ-MSH)-like immunoreactivity in human and rat hypothalamus

Immunohistochemical localization of γ-MSH was studied in human and rat hypothalamus by peroxidase-labeled antibody method both at light and electron microscopic levels. Human and rat hypothalamus contained immunoreactive γ-MSH neurons and varicose nerve fibers. The distribution of γ-MSH-positive nerve fibers was similar to that of β-endorphin previously reported. By our “re-staining method,” γ-MSH and ACTH were localized in the same neurons and nerve fibers. In the rat, the immunologic staining of γ-MSH in hypothalamic neurons and nerve fibers was not diminished after hypophysectomy. These findings strongly suggest the possibility of actual precursor production in the hypothalamus which is similar to that in the anterior pituitary. The presence of γ-MSH at the synapse-like structure of the nerve terminal may indicate that γ-MSH could function as a neurotransmitter or a neuromodulator.     

Presence and distribution of serotonin immunoreactivity in the cyprids of the barnacle Balanus amphitrite

In this work, the presence and distribution of serotonin in the cyprid of the barnacle Balanus amphitrite were investigated by immunohistochemical methods. Serotonin-like immuno-reactive neuronal cell bodies were detected in the central nervous system only. Various clusters of immunoreactive neuronal cell bodies are distributed in the brain (protocerebrum, deutocerebrum, optical lobes), and at least, four pairs of neuronal cell bodies were detected in the centrally positioned neuropil of the posterior ganglion. Rich plexuses of immunoreactive nerve fibers in the neuropil area were also observed. Furthermore, bundles of strongly immunoreactive nerve fibers surrounding the gut wall were localized, and immunoreactive nerve terminals in the antennules and compound eyes were observed. These data demonstrate the presence of a serotonin-like immunoreactive substance in the barnacle cyprids; furthermore, its immunolocalization in the cephalic nerve terminals allows us to postulate the involvement of this bioactive molecule in substrate recognition during the settlement process.     

Corticotropin-releasing hormone in the human hypothalamus. Free-floating immunostaining method

We have clearly demonstrated corticotropin-releasing hormone (CRH) immunoreactive cell bodies and nerve fibers in the human hypothalamus by immunocytochemistry using free-floating sections instead of paraffin-embedded sections. Human hypothalami were obtained at autopsy, fixed and cryostat-sectioned at 40 microns. Free-floating sections were immunostained with antibody to CRH using the Vector ABC system. Most of CRH immunoreactive nerve fibers from the paraventricular nucleus pass under the fornix, while some CRH immunoreactive nerve fibers pass beyond the fornix and some through the fornix. Then the CRH immunoreactive nerve fibers run downward, medially to the supraoptic nucleus and toward the pituitary stalk. This method of immunocytochemistry is a very sensitive and suitable means for immunocytochemical studies of neuropeptides in the human brain.