嫁Qi神经系统结构的初步研究

嫁Ｑｉ神经系统包括一对脑神经节,一对足神经节,一对侧神经节和一个脏神经节,左右脑神经节间有较长的神经联合,脑一足,脑一侧神经节间有较长的连索存在,各神经节均由三部分组成：神经节鞘膜,胞体区和神经纤维网。脑神经节相同类型神经元胞体聚集分布,其余神经神经元未见有明显分区和分层现象,神经元胞体直径一般不超过２０μｍ,这些特征与已确定的前鳃亚钢种类显著不同,可能与该种螺类处于系统演化中较低等地位有关。     

中华蜜蜂咽下神经节的结构和胚后发育

咽下神经节是昆虫腹神经索的第一个复合神经节, 主要调节口器附肢的活动。本研究通过形态解剖、 BrdU免疫组织化学等技术, 对中华蜜蜂Apis cerana cerana咽下神经节的组织结构和胚后发育过程进行了比较研究。结果表明： 中华蜜蜂的咽下神经节由上颚、 下颚和下唇3个神经节组成。在胚后发育过程中, 细胞增殖的活跃期主要集中在预蛹和蛹发育的第1天, 增殖活动一直持续到蛹发育的第4天结束。根据神经胶质细胞的位置和形态, 咽下神经节中的神经胶质可分为3种类型--表面神经胶质、 皮层神经胶质和神经纤维网神经胶质。本研究为蜜蜂神经系统的发育和功能研究提供了理论基础。     

嫁神经系统结构的初步研究

嫁神经系统包括一对脑神经节、一对足神经节、一对侧神经节和一个脏神经节。左右脑神经节间有较长的神经联合,脑—足、脑—侧神经节间有较长的连索存在。各神经节均由三部分组成：神经节鞘膜、胞体区和神经纤维网。脑神经节相同类型神经元胞体聚集分布,其余神经节神经元未见有明显分区和分层现象。神经元胞体直径一般不超过２０μｍ,这些特征与已研究的前鳃亚纲种类显著不同,可能与该种螺类处于系统演化中较低等地位有关。     

嫁（虫戚）神经系统结构的初步研究

嫁虫戚神经系统包括一对脑神经节、一对足神经节、一对侧神经节和一个脏神经节.左右脑神经节间有较长的神经联合,脑-足、脑-侧神经节间有较长的连索存在.各神经节均由三部分组成:神经节鞘膜、胞体区和神经纤维网.脑神经节相同类型神经元胞体聚集分布,其余神经节神经元未见有明显分区和分层现象.神经元胞体直径一般不超过20μm,这些特征与已研究的前鳃亚纲种类显著不同,可能与该种螺类处于系统演化中较低等地位有关.     

棉铃虫幼虫脑和咽下神经节的三维结构构建

【目的】解剖棉铃虫Helicoverpa armigera (Hübner) 5龄幼虫脑和咽下神经节及其内部神经髓形态结构,并分析和构建幼虫脑和咽下神经节以及各神经髓的三维结构模型。【方法】采用免疫组织化学方法解剖脑和咽下神经节的内部神经髓结构,利用激光共聚焦显微镜获取脑和咽下神经节扫描图像,然后利用AMIRA 三维图像分析软件进行图像分析,从而构建脑和咽下神经节的三维结构模型,并测量脑和咽下神经节以及内部各神经髓的体积,并分析了相对比例。【结果】 棉铃虫5龄幼虫脑和咽下神经节由围咽神经索连接在一起。脑主要由前脑、中脑和后脑3部分组成。前脑内包括视叶、蕈形体和中央体等形态结构较明显的神经髓。此外,前脑还包括其他位于脑的左右两侧以及背侧和腹侧大量神经髓区域,约占脑总神经髓的59.65%。这些神经髓区域边界不明显。中脑主要包括1对触角叶;后脑位于脑的腹侧和触角叶的下方,体积较小。咽下神经节由3个神经节融合构成,从前到后分别为上颚神经节、下颚神经节和下唇神经节,由于融合的紧密程度高,3个神经节间的边界不明显。【结论】阐明了棉铃虫5龄幼虫脑和咽下神经节的神经髓形态结构,构建了脑和咽下神经节以及内部神经髓的三维结构模型。三维模型可以任意旋转,能从任何角度观察脑、咽下神经节和内部不同神经髓的结构及其它们之间的空间关系。本研究结果对研究棉铃虫脑和咽下神经节信息接收、处理及调控行为的机制奠定了解剖学基础。     

绿盲蝽腹神经节的解剖结构

【目的】揭示绿盲蝽Apolygus lucorum腹神经节的组成结构。【方法】采用免疫组织化学染色方法,利用突触蛋白抗体对绿盲蝽成虫的腹神经节进行免疫标记,激光共聚焦扫描显微镜扫描照相获得原始数据,用图像分析软件进行标记,构建三维结构模型。【结果】绿盲蝽成虫腹神经节位于腹神经索的末端,与其前方的后胸神经节和中胸神经节紧密融合,形成后部神经节。与脑和胸神经节类似,腹神经节由周围的细胞体和内部的神经髓构成。腹神经节的神经纤维束主要包括位于腹侧的两条纵向神经连索和向两侧发出的9束神经纤维。9束神经纤维连接着9个神经原节,即富含突触联系的神经髓。这些神经原节紧密融合,无明显的边界,最后两节形成膨大的末端腹神经节。两侧的神经原节由横向的神经连锁连接起来。腹神经节外周的细胞体数量较多,排列紧密,大小一致,仅在前端背侧中间和后端腹侧中间位置分别有2个和5个体积较大的细胞体。【结论】本研究结果明确了绿盲蝽腹神经节的结构,为进一步研究昆虫的行为调控及神经系统发育和演化奠定一定的形态学基础。     

三疣梭子蟹胚胎期中枢神经系统的发生和发育

应用组织学方法研究三疣梭子蟹胚胎期中枢神经系统的发生和发育,光学显微镜下镜检切片,在第二期卵内无节幼体阶段开始观察到脑;第二期卵内状幼体阶段,前脑由视神经层、侧原脑和中央原脑组成,与位于食道两侧的中脑和后脑形成完整的脑。三疣梭子蟹胚胎期腹神经链由1对大颚、2对小颚和2对颚足所对应的神经节以及腹部神经链组成。光镜下大颚神经节可于第二期卵内无节幼体阶段观察到,2对小颚和2对颚足神经节则在第二期卵内状幼体阶段观察到;腹部神经链则在第三期卵内状幼体阶段观察到。三疣梭子蟹胚胎期中枢神经系统由脑和腹神经链组成,脑由前脑、中脑和后脑组成,脑位于背部,通过2条围食道神经与腹神经链相连。中枢神经系统的不同部分的形成在胚胎发育过程中具有阶段性差异。     

两种软体动物神经系统一氧化氮合酶的组织化学定位

运用一氧化氮合酶(NOS)组织化学方法研究了软体动物门双壳纲种类中国蛤蜊和腹足纲种类嫁Qi神经系统中NOS阳性细胞以及阳性纤维的分布。结果表明：在蛤蜊脑神经节腹内侧,每侧约有10-15个细胞呈强NOS阳性反应,其突起也呈强阳性反应,并经脑足神经节进入足神经节的中央纤维网中;足神经节内只有2个细胞呈弱阳性反应,其突起较短,进入足神经节中央纤维网中,但足神经节中,来自脑神经节阳性细胞和外周神经系统的纤维大多呈NOS阳性反应;脏神经节的前内侧部和后外侧部各有一个阳性细胞团,其突起分别进入后闭壳肌水管后外套膜神经和脑脏神经索。脏神经节背侧小细胞层以及联系两侧小细胞层的纤维也呈NOS阳性反应。嫁Qi中枢神经系统各神经节中没有发现NOS阳性胞体存在;脑神经节、足神经节、侧神经节以及脑—侧、脑—足、侧—脏连索中均有反应程度不同的NOS阳性纤维,这些纤维均源于外周神经。与已研究的软体动物比较,嫁Qi和前鳃亚纲其它种类一样,神经系统中NO作为信息分子可能主要存在于感觉神经。而中国蛤蜊的神经系统中一氧化氮作为信息分子则可能参与更广泛的神经调节过程。     

盾盘亚纲二种盾盘吸虫Aspidogaster conchicola和Lophotaspis orientalis神经系统结构差异的研究

采用乙酰胆碱组织化学定位方法,分别对盾盘亚纲两种吸虫Aspidogaster conchicola和Lophotaspis orientalis的神经系统进行染色观察.经比较,两种吸虫的腩神经节及神经联合的位置郁位于咽前部;由脑神经节向前发出的神经干最终会合于围口神经环;脑神经节向后发出3对神经干,其中后腹神经干最为粗大,它通过多对神经与腹吸盘相连.二者存在的差别在于:第一,体前神经干的分支数目及分布位置不同;第二,腹吸盘部神经分布形式不同;第三,Aspidogaster conchicola的两侧排泄管均有明显着色,并显示螺纹状结构.     

河北环毛蚓神经系统 一氧化氮合酶的组织化学定位

用依赖还原型辅酶Ⅱ的黄酶组织化学方法,研究了环节动物门寡毛纲种类河北环毛蚓（Pheretima tschiliensis)神经系统k 一氧化氮合酶(NOS)阳性细胞及阳性纤维的分布,结果表明,河北环毛蚓神经系统中脑神经节背侧有大量细胞呈现NO强阳性反应,胞体和突起染色明显。咽下神经中偶尔能见少数染色较浅的神经元。在脑神经节腹内侧、围咽神经、 咽下神经节外侧部及腹神经链中都有一氧化氮合酶阳性纤维存在脸染色很深,实验结果表明,在环节动物中作为信息分子的一氧化氮已广泛存在于神经系统中。     

Hyalomma dromedarii (Acari: Ixodoidea: Ixodidae): Central and peripheral nervous system anatomy

TheHyalommadromedarii central nervous system, the synganglion, is an integrated nerve mass concentrated around the esophagus and formed by fusion of a small anterodorsal supraesophageal part an a large posteroventral subesophageal part. The supraesophageal part consists of the protocerebrum including a pair of optic ganglia, a pair of cheliceral ganglia, a pair of pedipalpal ganglia, and the stomodeal pons. The subesophageal part includes four paired pedal ganglia and the complex opisthosomatic ganglion. The peripheral nervous system includes the following pairs of nerves: optic, cheliceral, pedipalpal, primary and accessory (histologically traced); also unpaired pharyngeal and recurrent nerves, four pairs of pedal nerve trunks, each with a hemal branch, and two pairs of opisthosomatic nerves. Each peripheral nerve is traced distally to the innervation site. The salivary glands are innervated anteriorly by branches of the pedipalpal nerve and medially by branches of the hemal nerves associated with the third pedal nerves.Reprint request should be sent to: Medical Zoology Department, NAMRU-3, Fleet Post Office, New York 09527, U.S.A.     

日本血吸虫胆碱酯酶的组织化学定位

血吸虫的胆碱酯酶(ChE)与血吸虫神经介质的传递、肌肉活动以及与其它物质代谢均有密切关系,也是抗血吸虫药物作用的靶子之一。1959年沈美玲等进行了药物对日本血吸虫乙酰胆碱酯酶(AChE)活力的研究。最近,姚民一等(1981)采用等电聚焦电泳分离出日本血吸虫胆碱酯酶的同功酶。然而有关血吸虫胆碱酯酶的组织化学定位研究主要限于曼氏血吸虫(Pepler,1958;Lewert等,1965;Fripp,1967;Bueding等,1967;Bruckner等,1974;Diconza等,1975)除Bueding简单述及日本血吸虫成虫的AChE外,迄今国内外尚无日本血吸虫CbE的组化资料,而且日本血吸虫的神经系统也未被专门观察。由于ChE的组化定位能细致地显示出血吸虫的神经系统构造,并能进一步提     

氚—烟酰苯胺在钉螺体内分布示踪的研究

本文应用氚－烟酰苯胺标记湖北钉螺，示踪观察不同时间烟酰苯胺进入螺体组织和脏器内的分布和进入途径。结果显示，钉螺接触药物从２２分钟开始检测出组织、脏器内氚含量，以后逐渐增高，至１４４０分钟达最高峰；合计不同时间各组织和脏器中药物含量由高至低排列次序为外套膜、胃肠、肝脏、肠内粪梗、睾丸、卵巢、鳃、神经节、心脏；转换氚含量为烟酰苯胺剂量，证实了烟酰苯胺杀螺的低用量与高效性；由单位重量组织和脏器中药物含量排位，反映出药物在螺体分布动态变化，以及药物通过消化系统、呼吸系统、外套膜表皮三条途径进入。     

日本血吸虫毛蚴对钉螺的钻穿及在螺体内的分布和移行

采自安徽省池的钉螺每粒感染５０只湖南株日本血吸虫毛后的组织学观察说明：毛蚴钻穿钉螺有从螺鳃部、头足总后有皮以及实质组织（外套膜、触角和阴茎）等三方面途径,其中以前二者尤为重要;毛蚴进入螺鳃丝后直接进入血液循环系统,从头足表皮进入的毛蚴,除了少数在钻穿部位附近滞留外,多数继续向头足部深层的肌肉和窦状组织间隙移行,以前头足窦、直肠和消化道外的组织间隙以及肾脏为主要的移行部位;从外套膜、触角、阴茎等部位     

DIVALENT CATION SPECIFICITY OF THE CALCIUM REQUIREMENT FOR FAST TRANSPORT OF PROTEINS IN AXONS OF DESHEATHED NERVES

The presence of a requirement for calcium during the fast transport of [³H]protein in axons was assessed in desheathed spinal nerves of bullfrog. The nerves were desheathed locally along 4 mm of their length, and desheathing was judged effective on the basis of an enhanced uptake of [³H]leucine into that region of nerve trunk. Desheathing per se had a slight inhibitory effect on transport. Incubation of desheathed nerve trunks in calcium-free medium reduced transport by 60-80% relative to that in desheathed nerves incubated in normal medium. Addition of Mg²⁺ or Sr²⁺ to the calcium-free medium allowed transport to proceed normally. Addition of Co²⁺ or Mn²⁺ to normal medium did not affect transport in desheathed isolated nerve trunks. When ganglia and nerve trunks were both incubated in medium containing 0.18 mM-CoCl₂, transport was depressed to a similar extent proximal and distal to the desheathed region. This again indicates that Co²⁺ does not inhibit transport in desheathed nerves, whereas it does inhibit transport in the ganglia. Additive inhibitory effects were observed when ganglia were incubated in medium containing 0.018 mM-CoCl₂, and desheathed nerves were incubated in calcium-free medium. Differences in the divalent cation specificities of the axonal and ganglionic calcium requirements suggest that calcium supports transport in nerves in a manner distinct from its role in maintaining transport in spinal ganglia. It is concluded that the ganglionic calcium requirement involves initiation of axonal transport in the soma rather than translocation in the intraganglionic region of axon.     

Retroperitoneal paraganglia and the peripheral autonomic nervous system in the human fetus

By means of the AChE in toto staining method retroperitoneal paraganglia and the peripheral autonomic nervous system in human fetuses have been investigated. Many small retroperitoneal paraganglia are present near the sympathetic trunks close to the sympathetic trunk ganglia. In the thoracic region small paraganglia are present in the intercostal spaces. Small splanchnic nerves entering small paraganglia have been described. In the lower sacral region no paraganglia are present. The major splanchnic nerve arises at various levels from the sympathetic trunks as well as many smaller thoracic splanchnic nerves. Intermediate ganglia are present in the major splanchnic nerve, the smaller splanchnic nerves and the communicating rami. In the sympathetic trunks many ganglia are fused. In the human fetus there exists a large variability in number and diameter of the communicating rami. Interconnecting bundles of nerve fibers between the left and right sympathetic trunks are present at all levels, but most numerous at the sacral level.     

Structure and anatomical relationships of the synganglion in the American dog tick,Dermacentor variabilis (Acari: Ixodiadae)

The synganglion of Dermacentor variabilis Say is a single nerve mass, condensed around the esophagus and within the periganglionic sinus of the ciculatory system. Protocerebral, cheliceral (including stomodeal bridge), and pedipalpal ganglia lie in the pre-esophageal portion of the nerve mass and bear optic, cheliceral, and pedipalpal nerves respectively. The unpaired stomodeal and the recurrent nerve which forms the hyper-esophageal ganglion arise from the stomodeal bridge. Paired primary and accessory nerves to the retrocerebral organ complex have mixed protocerebral-cheliceral origins. Pedal ganglia (including ventral olfactory lobes of pedal ganglia I) and composite opisthosomal ganglion lie in the post-esophageal nerve mass and bear pedal nerve trunks and two pairs of opisthosomal nerves respectively. Internally, the synganglion consists of cellular rind and fibrous core. A welldefined neurilemma with a laminar matrix covers nerve mass and peripheral nerves. The rind contains the somata of ganglionic neurons and ensheathing glial cells and is restricted to the synganglion mass. It is limited by two specialized glial layers, the external perineurium and internal subperineurium. Discrete glomerular formations are present within the protocerebrum and olfactory lobes. Olfactory glomeruli located in pedal ganglia I are associated with a pair of globuli cell groups. Possible physiological relationships between anatomical specializations of the synganglion, extraneural sinuses and circulating hemocytes are considered. The evolutionary significances of condensation in the stomatogastric neuropile regions and throughout the synganglion, together with the simplification and loss of glomerular formations, are discussed.     

植物颗粒剂对钉螺毒杀效果的研究

将3种药用植物材料分别粉碎后与淀粉、明胶配合制成直径2～3mm的植物颗粒剂用于灭钉螺试验,结果表明,钉螺取食3种颗粒剂后,24h死亡率分别达到92.5％～100％.其毒杀效果明显优于相同植物的其它灭螺方法,对钉螺的致死时间比氯硝柳胺化学灭螺剂(1×10-3g·L-1)提前12～24h.用3种植物颗粒灭螺剂进行野外灭螺实验,钉螺死亡率最高可达61.5％.     

小地老虎雄性外生殖器的肌肉系统及神经分布

小地老虎Agrotis ypsilon Rott.雄性外生殖器由第8腹节的5对肌肉支持,它具有充分功能的抱器(clasper)和第9腹节的侧骨片,具有8对外生殖器特有的肌肉。具有一对由第9,10,11节原始腹部神经节的侧神经组成的成对的粗大神经干9+10+11,神经干的神经分支分布神经到外生殖器。     

The stomatogastric nervous system of the house cricket Acheta domesticus L. I. The anatomy of the system and the innervation of the gut

The distribution of the ganglia and nerves of the stomatogastric nervous system and the innervation of the extrinsic and intrinsic muscles are described. Median unpaired frontal and hypocerebral ganglia and paired ingluvial ganglia are present. The anterior pharynx is innervated by branches of the frontal nerve and by the anterior and posterior pharyngeal nerves, originating from the frontal ganglion. The posterior pharyngeal nerves are linked to nerves innervating the posterior part of the pharynx which have their origin in the hypocerebral ganglion, the anterior portion of which has previously been regarded as part of the recurrent nerve. Paired esophageal nerves run the length of the esophagus and crop between the hypocerebral and and ingluvial ganglia, innervating the muscularis by serial side branches. From each ingluvial ganglion runs an ingluvial nerve which innervates the gizzard and a cecal nerve which innervates the midgut and its ceca. At the posterior end of the midgut there is a poorly developed nerve ring. Nerves running posteriorly from this nerve ring link the stomatogastric nervous system with the proctodeal innervation from the terminal abdominal ganglion. Multipolar peripheral neurons are present on the muscularis of the whole of the foregut, rather randomly distributed on the crop and gizzard but forming fairly definite groupings at some points on the pharynx. Though of varied appearance, these cells could not be divided into discrete morphological categories. Peripheral neurons on the midgut are of different and characteristic morphology, though a few cells of the same appearance as those of the foregut occur at the midgut-hindgut boundary. Nerve fibers on the gut almost invariably terminate on the fibers of the muscularis.