扬子鳄中脑视叶NOS、AChE阳性神经元的分布

目的观察扬子鳄中脑视叶一氧化氮合酶(nitric oxide synthase,NOS)和乙酰胆碱酯酶(acetylcholinesterase,AChE)阳性神经元的形态和分布,为扬子鳄脑的比较解剖学积累资料,为其机能研究提供形态学依据。方法采用还原型尼克酰胺腺嘌呤二核苷酸黄递酶(NADPH-d)法和亚铁氰化酮法观察扬子鳄中脑视叶NOS和AChE阳性神经元的分布和特征,并作统计学处理。结果扬子鳄中脑视叶有NOS和AChE阳性神经元分布,为大、中、小型细胞,以中、小型细胞为主,胞体呈椭圆形、三角形、圆形和梭形。结论扬子鳄中脑视叶有NOS和AChE阳性神经元分布。     

北草蜥中脑视叶组织学结构观察

用光学显微镜对北草蜥(Takydromus septentrionalis)中脑视叶组织学结构进行了观察。视叶分为背侧的顶盖和腹侧的被盖,两者无明显界限。顶盖处灰质和白质交替排列。由表及里,可分为分子层、外灰质层、浅白质层、中灰质层、中白质层、深灰质层、深白质层和室管膜层。被盖处细胞层次不明显。在视叶的前部有横行的纤维将左右视叶联系起来。左右视叶室与中脑水管以及两视叶间的纵沟在视叶的中、后部相通。同时将北草蜥的中脑与其它低等脊椎动物进行了比较,推测北草蜥在进化上处于较低等地位。     

中华鳖眼睛发育的形态及组织学观察

在孵化基质沙粒径为0.3～0.6mm、孵化温度为(33.0±0.5)℃、孵化基质的湿度为7%～10%、相对湿度为70%～85%的条件下孵化中华鳖(Trionyx sinensis)卵,孵化周期35～36 d.破壳取不同发育时期的胚胎并制作切片,观察眼睛发育的形态学和组织学特征.孵化第4 d头部两侧出现眼泡的突起;第6d眼睛开始出现色素,第14 d色素由褐色变为黑色;第7 d瞳孔出现,透过瞳孔可见晶状体;虹膜于第14d出现,第18、19 d瞳孔周围呈放射状;巩膜突自第19 d出现,第21 d增至最多,第23 d消失;上、下眼睑分别在第19 d和22 d出现,第32 d眼睑可覆盖瞳孔,眼睛形态与成体眼睛相似.表皮外胚层于第3 d形成角膜原基和晶体泡,第32 d角膜发育完成;第34 d晶状体发育完成;神经外胚层于44～48 h由前脑的两侧分化形成视泡,第3 d由视泡分化形成视杯,并逐步分化形成视网膜;第23 d视网膜的八层结构基本形成;第34 d视网膜发育完成.     

河川沙塘鳢视觉器官的发育及其与摄食的关系

利用光学显微镜观察了河川沙塘鳢(Odontobutis potamophila)视觉器官的发育,并对其发育与摄食的关系进行了研究。河川沙塘鳢的眼囊起源于神经外胚层。当胚胎发育至心跳期时,眼囊内陷形成视杯;之后,视杯内表面的外胚层形成晶状体而与视杯分离,视杯进一步发育形成视网膜。随着胚胎的进一步发育,晶状体的直径增加,结构逐步发育完善。胚胎发育至眼黑色素出现期时,视网膜分化为6层,其中,外核层、内核层和神经节细胞层3个核层明显;胚胎发育至孵化前期时,视网膜已分化为10层。孵出后1d的仔鱼,其视网膜已能行使功能,仔鱼逐渐开口摄食。随着稚、幼鱼的发育,视网膜厚度进一步增加,结构发育完善。视网膜的结构和视觉特性显示河川沙塘鳢是要求光照条件好、白昼活动并具有较好视觉功能的鱼类。     

扬子鳄胚胎喉的组织发生

观察了２０例扬子鳄胚胎的喉发生过程。孵育第６天出现喉气管憩室,第８天出现喉原基。孵育１０￣２０天,原始喉腔上皮细胞分裂增殖加快,喉腔侧壁中部的上皮向两侧中胚层不断突出,喉腔渐扩大。第３０￣４８天,喉腔的背室及左右腹室逐渐明显。喉肌及喉软骨于第３４天开始分化,第４８天,喉肌发育成横纹肌,喉软骨化基本完善。固有膜及粘膜下层于第４０天开始出现,第４８￣６２天,其中的血管分布渐增多。孵育第４０天,喉上皮表     

蟋蟀脑的解剖结构与生理机能

蟋蟀脑由前脑、中脑和后脑三部分组成。前脑由1对蕈形体、中央复合体和视叶构成;每个蕈形体由2个冠、柄及与柄相连的α叶和β叶组成,是信息联络整合部位;中央复合体由中央体和脑桥组成,主要参与感觉信息的加工过程;视叶由神经节层、外髓和内髓组成,是视觉系统的中心。中脑由主要组成成分为嗅觉纤维球的嗅叶组成,是嗅觉系统的中心。后脑向后与食道下神经节相连。     

扬子鳄胚胎胰腺内分泌细胞发生的免疫组织化学研究

目的 研究13种特异性激素在扬子鳄胚胎胰腺早期发育中的表达。方法 应用免疫组织化学方法。结果 显示生长抑素（SS）,5-羟色胺（5-HT）,胰高血糖素（GLU）,表皮生长因子（EGF）,胰多肽（PP）免疫反应性（IR）细胞出现于第8天,P物质（SP）IR细胞出现于第18天,P53,胃泌素,睾酮,嗜铬素A,血管活性肠肽,上皮膜抗原,胰岛素在各期扬子鳄胚胎胰腺中均未发现。结论 表明SS、5-HT,GLU,EGF、PP和S害扬子鳄胚胎胰腺形成的分化的不同阶段发挥着重要作用。     

宽体沙鳅脑组织学研究

为探究鱼类脑结构及其与生态习性的相关性, 采用HE及Nissl染色法对健康性成熟宽体沙鳅脑组织结构进行观察。结果显示: 宽体沙鳅脑由端脑、间脑、中脑、小脑、延脑五部分组成。嗅叶为典型的“鲤型”嗅叶; 大脑视前核呈索状排列, 未见视前核大、小细胞群; 间脑乳头体及副错位核清晰可见, 血管囊及下叶发达; 中脑视盖由5层构成; 小脑发达, 由3层构成; 延脑分化出面叶和发达的迷叶。这表明, 宽体沙鳅视觉稍有退化, 嗅觉、听觉、触觉、味觉及运动中枢发达, 生活中主要依靠嗅觉、听觉、触觉、味觉觅食及逃避敌害。     

中华蟾蜍中脑组织学研究

采用HE染色和Holmes银染法对蟾蜍中脑的显微结构进行了研究.中脑背侧,视叶可分为顶盖和被盖,顶盖从外侧到内侧依次分为:带状层、外灰质层、浅白质层、中灰质层、中白质层、深灰质层、深白质层和中央灰质.被盖前端分层与顶盖相同,后端分层不明显.中脑腹侧包括被盖和大脑脚,HE染色和Holmes银染法显示,大脑脚从外向内颜色由浅变深,存在大量纵向神经纤维束,两脚底分界处有横向交错的神经纤维.被盖外侧细胞不分层,聚集形成核团.被盖内侧,细胞和纤维以中脑水管为中心,呈同心圆环分8层.通过比较蟾蜍中脑背腹差异程度,了解背腹功能不同.同时对中华蟾蜍中脑同其他脊椎动物的进行了比较.     

鸡肾发生的组织学观察

采用组织学方法和电镜技术,对9个不同发育时期的鸡(Callus domestiaus)胚胎进行了观察.通过对鸡胚胎肾组织发生过程的观察,探讨鸡胚中肾的发生与退化,后肾的发生、分化规律和特点.结果表明,孵育到第16期在中肾前端附近出现一些中肾小泡.孵育到第18期形成中肾小管.孵育到第26期,中肾小管的盲端内陷,原始的肾小囊和肾血管球形成,中肾小管显著伸长并迂回曲折.孵育到第33～37期,体前后部中肾组织均已形成完整的肾单位.第37～46期体前部至后部的中肾组织依次退化.孵育到第26期从泄殖腔附近发出的输尿管芽向生后肾组织侵入生长,生后.肾组织产生许多生后肾小泡.第33期出现肾小囊和肾小管,肾小管伸长并发生折叠,出现集合小管、近端小管和远端小管的形态分化.第37～46期肾小体逐渐发育成熟,肾小管继续分化出现细段.鸡的中肾具有排泄功能.鸡后肾的发生与分化存在明显的时间差异.肾单位的分化中,同一胚龄肾组织内可存在不同发育阶段的肾小体,集合小管分化较早,诱导近端小管和远端小管分化,细段分化较迟.     

扬子鳄胚胎背腺的发生及退化

本文在１４例扬子鳄Ａｌｌｉｇａｔｏｒｓｉｎｅｎｓｉｓ胚胎中观察了背腺的发生及退化过程。孵化第２８天,背中线左右两侧第二行鳞片处的表皮内陷形成实心的背腺腺芽;第３８天,背腺腺泡明显,腺上皮为复层上皮;从第４６天开始,腺上皮出现明显的退化,大量增殖的腺管上皮细胞逐渐堵塞腺管及腺孔。扫描电镜观察表明,孵化第３２—３６天的胚胎背部第二行鳞的各列鳞片表面均有背腺腺孔,以后逐渐出现少数不规则的退化,孵化第５８天以后,绝大多数背腺腺孔消失。对扬子鳄背腺的发生及退化现象作了讨论。     

Neuropeptide Y-immunoreactive neuronal system and colocalization with FMRFamide in the optic lobe and peduncle complex of the octopus (Octopus vulgaris)

The distribution of neuropeptide Y (NPY)-like immunoreactivity and its colocalization with FMRFamide were investigated in the optic lobe and peduncle complex of the octopus ( Octopus vulgaris) by using immunohistochemical techniques. In the optic lobe cortex, NPY-immunoreactive (NPY-IR) fibers were observed in the plexiform layer, although no NPY-IR somata were observed in the outer or inner granular cell layers. In the optic lobe medulla, NPY-IR somata were seen in the cell islands, and abundant NPY-IR varicose fibers were observed in the neuropil. Most of the NPY-IR structures in the medulla showed FMRFamide-like immunoreactivity. In the peduncle lobe, abundant NPY-IR and FMRFamide-IR (NPY/FMRF-IR) varicose fibers were seen in the basal zone neuropil of the peduncle lobe. In the olfactory lobe, NPY/FMRF-IR varicose fibers were also abundant in the neuropil of the three lobules. NPY/FMRF-IR somata, with processes running to various neuropils, were scattered in the median and posterior lobules. In the optic gland, many NPY/FMRF-IR varicose fibers formed a honeycomb pattern. These observations suggest that NPY/FMRF-IR neurons in the optic lobes participate in the modulation of visual information and that those in the optic gland are involved in the regulation of endocrine function.     

Cytodifferentiation of the adenohypophysis of the domestic fowl

Summary In the chick embryo the first membrane-bound secretory granules occur in the cytoplasm of occasional cells in the cephalic lobe of pars distalis at the 7th day of incubation. On the 8th day most of the cells in both the cephalic and caudal lobes contain secretory granules that are variable in size, form and density.On the 9th day at least two types of glandular cells are distinguishable in the cephalic and in the caudal lobes; however, these cells are not comparable with those of the adult gland. Differentiation of acidophils and basophils occurs, apparently simultaneously, in 11-day embryos.The cells of the cephalic and caudal lobes are morphologically distinct from their first appearance. Thus it is concluded that these two lobes develop independently and differently from an early stage of ontogenesis.The secretory granules are formed in the Golgi area of the hypophysial cells after the 8th day of incubation. However, secretory material may be synthesized also by a process not involving the Golgi apparatus.Nerve fibers containing granules first appear in the superficial layer of the median eminence on the 8th embryonic day and by the 12th day three types of granules and two types of clear vesicles are identifiable.The investigation reported herein was supported by grant from Japan-U.S. Cooperative Science Program of Japan Association for Science Promotion to Professor Mikami and by U.S.-Japan Cooperative Science Program Grant No. GF-33334 to Professor Farner.     

Postembryonic changes in the optic primordia and optic bud in the flesh fly Sarcophaga ruficornis fabr. (Diptera: Sarcophagidae)

Differentiation of the optic lobe anlagen begin in the brain of second instar. Each is an elongated disc of cortical cells placed on the dorsolateral border of each protocerebrum. In the late second instar the disc elongates and its two ends bend inwards which gradually separate from the central region, thus giving three imaginal discs. The protocerebral neuropile extends into these discs and medulla interna and externa are formed. The rudiments of compound eyes (cephalic complex) appear in the early laid larva. These are attached with the brain and pharyngeal wall separately. The posterior portion of cephalic complex (optic bud), after establishing a nervous association with the central optic lobe anlage (lamina ganglionaris), forms the compound eye. Ech optic bud is attached to the brain by a non-nervous stalk. The epiblast cells of the optic bud do not migrate into the brain and the lamina is formed by the proliferation of the central imaginal disc. The reorientation of the optic lobe anlagen starts in the late third instar and the medulla interna divides into two unequal lobes. In 2 day pupa the nerve fibres from the lamina travel into the optic stalk and the optic nerve is formed. The epiblast cells of the optic bud differentiate to form a peripheral epithelial layer which becomes pigmented and gets apposed to the lateral boundary of the brain. The central epiblast cells of the optic bud form several ommatidia. The optic nerve degenerates gradually and various components of the compound eye are formed by the epiblast cells. Chiasm internum is present but chiasm externum is absent.     

Ultrastructural differentiation of glandular stomach (proventriculus) in chick embryo

Cytochemical characterization of mucosubstances of chick glanular stomach (proventriculus) changes from 15 days of development to postnatal and adult stages was studied. To corroborate these data cytochemical, ultrastructural and ultracytochemical study of chick embryo proventriculus from 7 to 20 days of development was performed. At the 7th day several layers of undifferentiated cells formed an epithelium which covered the walls of the glandular stomach. Mocosubstances were not found. Between the 9th and 5th day a single layer of cylindrical cells was encountered forming invaginations which originated deep glands. Three types of cells were separated from the above mentioned layer, dark, clear and undifferentiated. The dark cells had organelles which are involved in protein synthesis and the clear ones were rich in mitochondria. Argentaffine cells appeared at 15th day instead mucosubstances formed a thin coat on the epithelium at 9th day which increased at the end of development in the apical cytoplasm and gland cells. These observations demonstrate that proventriculus of chick embryo has ultrastructurally differentiated cells involved with enzymatic and hydrochloric acid secretion after the 9th day. These progressive events are correlated with the digestion process of yolk during embryogenesis. At the end of development the proventriculus has completely organized the glandular layer.     

Early patterns of neuronal degeneration in the retina of the goldfish after optic nerve sectioning

The early patterns of retinal degeneration were studied in the goldfish after optic nerve sectioning by l.m. and e.m. Beginning on the 2nd postsurgical day there was an initial degeneration of neurons in the ganglion cell and inner nuclear layers of the central retina. Massive ganglion cell degeneration in the whole retina (60%) as well as degeneration of neurons in inner and outer nuclear layer of the peripheral retina was evident around the 7th postsurgical day. The early degenerating cells appeared to be cones and cone bipolars.     

胭脂鱼眼早期形态发生研究

采用组织学方法观察了胭脂鱼(Myxocyprinus asiaticus) 眼的发生过程, 结果显示: 胭脂鱼眼的发育经历了眼原基形成期、眼囊形成期、视杯形成期、晶体板形成期、晶体囊形成期、角膜原基形成期、角膜上皮形成期、视网膜细胞增殖期、晶状体成熟期、眼色素形成期以及眼成型期等11个时期。视网膜发育最早, 起始于眼原基的形成, 直至眼成型期分化完成, 形成了厚度不一的8层细胞, 由内向外依次为神经纤维层、神经细胞层、内网层、内核层、外网层、外核层、视杆视锥层和色素上皮层, 且发育历时最长, 约264h。晶状体的发育在视网膜之后, 始于晶体板的形成, 于出膜前期成熟, 发育历时最短, 约74h。角膜发育最晚, 始于角膜原基的形成, 出膜1 d分化为透明的成熟角膜, 发育历时约96h。出膜4 d仔鱼眼色素沉积明显, 视网膜各层分化明显, 晶状体内部完全纤维化, 眼的形态结构基本发育完全。