山溪鲵消化道粘膜上皮的扫描电镜研究

用扫描电镜观察了山溪鲵的咽、食管、胃、怕和大肠粘膜上皮表面细微结构及断面的结构特征。发现咽和食道上皮表面有比较宾微脊;胃粘膜上皮表面有微绒毛,周转的长 密集,顶部的短而稀少;胃粘膜上皮表面的微绒毛似苔葡状覆盖在细胞的表面;杯状细胞分布在上皮细胞之间。同时,还讨论了这些结构与机能的关系。     

刀鲚幼鱼消化系统的组织形态学结构

采用光镜和扫描电镜观察长江刀鲚(Coilia nasus)幼鱼消化系统组织形态学结构。结果显示,刀鲚体长,口裂大,含有犬齿状的颌齿和尖锥状的腭齿,具有5对鳃弓,鳃耙长度明显大于鳃丝且表面附着不规则绒毛状细齿;胃呈"Y"型,胃与肠连接处具有16～21个指状环形幽门盲囊;肠为直肠,较短,比肠长为0.241±0.080;肝分为两叶,胰为独立的器官。刀鲚口咽腔为复层鳞状上皮,含有腺体、大量椭圆形黏液细胞、少量杯状细胞及味蕾;胃黏膜都为典型的单层柱状上皮,含有较多由上皮凹陷形成的胃小凹和胃腺;幽门盲囊具有20～25个丰富的褶皱,占满大部分幽门盲囊腔,黏膜层具有微绒毛;中肠黏膜上皮最发达,形成的褶皱细长且连接成网状,单层柱状上皮与复层扁平上皮交替分布。观察结果表明,刀鲚消化系统具有典型肉食性鱼类特征。     

中华绒螯蟹消化道组织学及扫描电镜研究

对中华绒螯蟹成蟹消化道各段进行了光镜组织学结构的观察;应用扫描电镜技术,观察了中华绒螯蟹消化道各段黏膜上皮表面超微结构特征。结果表明：除中肠及后盲囊外,整个消化道黏膜上皮表面均有较厚的分泌物层和较发达的纤毛层。纤毛形态结构各异;以食道和后肠分布最密,胃和肠球次之。消化道各段黏膜上皮细胞表面均形成大小不一、形态各异的多级皱褶和嵴。仅中肠表面具典型微绒毛结构。各消化道段黏膜上皮表面均未见杯状细胞,上皮下基膜发达,黏膜下层明显,消化腺分布其间。整个消化道壁的肌层均为横纹肌,且排列疏松,外膜多为浆膜。     

花背蟾蜍蝌蚪胃的发育形态学观察

应用大体解剖、组织切片和扫描电镜3种形态学方法对花背蟾蜍(Bufo raddei)蝌蚪在生长发育和变态过程中胃的形态结构变化进行了观察。结果显示,在蝌蚪发育24期(即G24)消化道呈简单的管状结构,胃与小肠等区分不明显,胃壁由内层矮柱状黏膜上皮细胞和其外的扁平上皮细胞层构成;直到26期胃略膨大,呈短粗管状,与小肠和食道可明显区分,胃壁内层的黏膜上皮细胞呈高柱状,上皮细胞间出现少量杯状细胞;36期的胃管明显膨大,其壁已具有胃的4层基本组织结构,杯状细胞数量增加,黏膜上皮细胞游离面有细长的微绒毛交织成网状覆盖;42期胃发育呈"C"字形,胃壁具备了消化道典型的4层结构,有胃腺芽出现,黏膜细胞的微绒毛短而直立,仅极少数细胞有长的微绒毛;蝌蚪发育到46期,肠道缩短,胃呈"J"字状,占消化道大部分,胃体中胃腺发达。在临近肝一侧,黏膜上皮细胞的微绒毛较短,胃腺少而小;而在相反一侧,微绒毛较长,胃腺多而大。基于上述结果说明,花背蟾蜍蝌蚪胃在36期已经基本完成了组织结构的分化,在变态发育期间结构和功能得到进一步完善,以适应变态后陆地生活的食性变化。     

崇安草蜥舌的显微和超微结构

采用显微技术观察了崇安草蜥(Takydromus sylvaticus)舌的显微和超微结构.舌腹面黏膜光滑;背面黏膜粗糙,由丝状乳头和轮廓乳头组成.丝状乳头锥体形,数量较多,排列成行,分布于舌体背面两侧和侧翼的腹面.在舌的横切片上有3～7个轮廓乳头,其表面平整,周围有环形沟,舌腺开口于环形沟中.舌肌肉发达.超微结构显示,舌上皮细胞问具有紧密连接,舌乳头细胞表面具有丰富的微绒毛.舌腺为单管泡状腺,分泌管由单层柱状上皮构成.柱状上皮细胞有两种,一种为分泌细胞,一种为暗细胞.分泌细胞内有典型的分泌颗粒,可协助食物的吞咽.暗细胞内无分泌颗粒,是否与离子分泌以及渗透压调节有关,尚需进一步证实.     

黄斑篮子鱼和金钱鱼鳃的扫描电镜观察

对两种鲈形目鱼类黄斑篮子鱼(Siganus oramin)和金钱鱼(Scatophagus argus)的鳃结构进行扫描电镜观察。结果表明,黄斑篮子鱼和金钱鱼鳃的表面结构及微细结构与其他硬骨鱼类基本相似,鳃丝表面都具有规则或不规则分布的环形微嵴、沟、坑、孔等结构。黄斑篮子鱼的鳃片中部鳃丝表皮有大量凸起,而端部鳃丝表皮的凹凸程度明显较低,黄斑篮子鱼的鳃小片高度较金钱鱼鳃小片高。黄斑篮子鱼和金钱鱼鳃上皮的扁平上皮细胞、氯细胞和黏液细胞的形态结构及数量分布存在细微的差异。黄斑篮子鱼鳃片鳃丝的端部和中部表面有黏液细胞,金钱鱼鳃丝表面的黏液细胞很难观察到,与大多数淡水鱼类相似。黄斑篮子鱼鳃丝表面分布的氯细胞数量多于金钱鱼,这可能与两种鱼生活环境、生活习性的长期演变相关。     

黄鳝膀胱上皮表面结构的电镜观察

应用电子显微镜观察了黄鳝膀胱上皮表面结构。发现其膀胱上皮表面具有许多平行排列的黏膜纵褶和褶间沟,它们的表面具大量微嵴,这些微嵴排列成指纹状结构;微嵴分为边嵴和中央嵴,其断面呈短指状;上皮表层细胞的顶面形态为近六边形。它们的界限是边嵴;边嵴间存在着一些呈椭圆形的微孔;在微孔下方发现一类含许多松仁。     

中华鳖肠道黏膜免疫相关细胞的形态学研究

应用光镜和透射电镜技术,对中华鳖肠道黏膜免疫相关细胞的分布和结构进行了详细观察,并结合形态结构特点,对爬行动物黏膜免疫的特征进行了讨论。鳖肠道黏膜上皮细胞(尤其大肠段)排列较疏松,细胞间隙明显,上皮间隙内普遍分布着上皮内淋巴细胞(IEL)和浆细胞。IEL在上皮不同部位的分布比例为核下区∶核区∶核上区=4∶3∶3。核上区IEL以小淋巴细胞为主,而核区和核下区的IEI体积略大。淋巴细胞胞质内含有数个粗大的膜包颗粒。上皮内未见微皱褶细胞,IEL位于上皮细胞之间,并在上皮细胞之间伸出伪足。肠腔内有完整的游离淋巴细胞。肠道黏膜上皮间隙内的浆细胞一般位于核下区或核区,胞质内充满着扩张状态的粗面内质网。肠道固有膜散布着许多淋巴细胞(LPL)、浆细胞、巨噬细胞和一些白血细胞,以小肠段的分布最丰富。在有些肠绒毛内,LPL分布密集,几乎占据整个绒毛中心,但并未出现淋巴小结。固有膜浆细胞有两种形态:一种浆细胞的粗面内质网呈短的扩张状态,其数量占多数;另一种浆细胞的粗面内质网为板层状排列的扁囊状,数量较少。结果表明,参与中华鳖肠道黏膜免疫反应的细胞数量多,但黏膜上皮内缺乏微皱褶细胞(M细胞),固有膜中也不形成淋巴小结。提示爬行动物的黏膜免疫机理与哺乳动物和鸟类不尽相同。     

解脲支原体对兔输卵管黏膜上皮细胞致病性研究

目的：探讨解脲支原体(UU)对兔输卵管黏膜上皮细胞的粘附及其致病性。方法：采用雌性大白兔作为实验对象,用UU感染兔输卵管黏膜上皮细胞,经光学和电子显微镜观察UU对其粘附性和致病性。结果：UU感染后,兔输卵管管腔有较多渗出物,呈淡红染匀质状,黏膜层的上皮细胞轻度肿胀,黏膜下层有炎症细胞(以淋巴细胞为主)呈灶性浸润;在电镜下,UU粘附于输卵管黏膜上皮细胞上,同时上皮细胞游离面的纤毛互相粘连、倒状,纤毛细胞核膜欠完整．胞核染色质呈凝块状．胞浆内可见大量大小不等的空泡,无纤毛细胞顶面参差不齐,可见伪足样突出．微绒毛减少．胞浆内近细胞顶部有少量分泌颗粒和空泡变性,细胞间可见相嵌连接。结论：UU到达兔输卵管后可粘附于输卵管黏膜上皮细胞上并导致损伤。     

日本七鳃鳗消化系统显微与超微结构

采用光镜和电镜技术研究日本七鳃鳗(Lampetra japonica)消化系统的组织结构。结果显示,日本七鳃鳗食道褶皱处黏膜上皮为复层立方上皮,褶皱基部为变移上皮。由于生活方式的特化,其胃退化。前肠、中肠和后肠黏膜上皮均为单层柱状上皮,其中并未发现杯状细胞,有肠腺,肠上皮有密集的纤毛,上皮细胞内各种细胞器均较丰富,肌纤维斜行。肝小叶界限不清,肝内无胆管。内分泌性胰由若干个大小不等和形状不定的细胞团组成。口腔腺上皮细胞高柱状,游离端充满酶原颗粒和微管泡系,细胞间有分泌小管。日本七鳃鳗消化器官的组织结构特点与其特殊的取食方式和进化地位密切相关。     

The microscopic anatomy of the oesophagus, stomach and intestine of the channel catfish, Ictalurus punctatus

An anatomical study of the digestive tract of the channel catfish revealed that the oesophageal mucosa was longitudinally folded and that secondary folds were occasionally located on the primary longitudinal folds. The infoldings were more numerous near the stomach. The stratified squamous epithelium covering the folds was made up of a basal layer, large mucous cells and simple squamous cells on the surface. The epithelium on the side of the folds consisted primarily of mucous secreting cells. Taste buds were observed between mucous cells on the apical portion of the oesophageal folds and were more prevalent in the cranial part of the oesophagus. The remaining layers of the oesophagus were: a lamina propria-submucosa, tunica muscularis and adventitia or serosa.
The J-shaped stomach had two regions: a large sac-shaped region containing gastric glands and a smaller, nonglandular pyloric region. The large rugae of the stomach became gradually smaller near the pylorus. There was a well developed pyloric sphincter. The mucosa included a simple columnar epithelium, a lamina propria and adventitia or serosa.
The intestine could be differentiated into a thick ascending segment, a descending segment, a thin convoluted segment and a thicker terminal segment, the rectum. Many mucosal folds containing branched villi characterized the ascending segment of the intestine. The descending and convoluted segments contained fewer folds with shorter and less-branching villi and were smaller in diameter and thinner walled. Descending and convoluted segments were also mildly convoluted and accounted for 80% of the total length of the intestine. An intestinal valve with a sphincter marked the beginning of the rectum. There was an approximately four-fold increase in the thickness of the tunica muscularis of the terminal segment of the intestine.     

A study of the anatomy, histology and ultrastructure of the digestive tract of Orthrias angorae Steindachner, 1897

The anatomy, histology and ultrastructure of the digestive tract of Orthrias angorae (Steindachner, 1897) were investigated using light microscopy, scanning electron microscopy (SEM) and transmission electron microscopy (TEM). The histological structure consists of four layers: mucosa, submucosa, muscularis and serosa. The esophageal mucosa consists of undifferentiated basal epithelial cells, mucous cells and surface epithelial cells. It was observed that the J-shaped stomach had a meshwork of folds in the cardiac region, and longitudinal folds in the fundic and pyloric regions. A single layer of columnar cells, PAS positive only in their apical portions, forms the epithelium. The convoluted tube-shape intestine is lined by simple columnar epithelial cells, which have microvilli at the apical surface. The wall of the esophagus and stomach are thicker than that of the intestine because of the thick muscle layer. There were numerous goblet cells in the intestine. There were numerous gastric glands in the submucosa layer ofthe cardiac stomach, but none were present in the pyloric region of the stomach. There were no pyloric caeca between the stomach and intestine. The enterocytes with microvilli contained rough endoplasmic reticulum, ribosomes and rounded bodies, and the gastric cells contained a well-developed Golgi apparatus.     

Morphological and histochemical characterisation of the mucosa of the digestive tract in matrinxã Brycon amazonicus (Teleostei: Characiformes)

This study describes anatomical, histological and histochemical features of the digestive tract mucosal layer of the matrinxã Brycon amazonicus, an omnivorous freshwater fish endemic from the Amazon basin. This species presents short thick oesophagus with longitudinal folds, that allow the passage of large food items. The mucosa is lined with a stratified secretory epithelium rich in goblet cells that secrete neutral and acid mucins. The two mucin types provide different viscosity in anterior and posterior oesophagus related to the protective and lubricant functions, respectively. The stomach is a highly distensible Y-shaped saccular organ. Here, it is proposed that this anatomical shape plays an essential role in food storage when food availability is abundant. The stomach mucosa is composed of epithelial cells with intense neutral mucin secretion to protects against gastric juice. The intestine is slightly coiled and presents internally a complex pattern of transversal folds that increases the absorption surface and the retention time of food. Goblet cells in the intestine secrete acid and neutral mucins that lubricate the epithelium and aid in the digestive processes. In the rectum, an increase in goblet cells population occurs that may be related to better lubrication.     

Scanning electron microscopy of goldfish, Carassius auratus, intestinal mucosa

Scanning electron microscopy was used to examine the intestinal bulb and the caudal portion of the intestine proper of the goldfish, Carassius auratus . The observations made correlated well with previous light microscope studies by other investigators. The mucosal surface of the entire intestine of the goldfish is thrown up into folds, which are oriented along the long axis of the digestive tract in the intestinal bulb, but run more or less transversely in the caudal intestine. Tops of the folds were observed to be rounded or flattened, and the folds themselves formed wavy or zigzagging patterns in the mucosal surface. Numerous mucus-secreting goblet cells were seen, which were apparently more numerous or more active in the caudal intestine than in the intestinal bulb. The goblet cells are not uniformly distributed throughout the mucosa: they are more evident on the sides of the folds, although occasionally they appear to be located in clusters on the tips.
The goblet cells were observed to contain varying amounts of mucous material, and/or to be of different sizes. Although no histochemical tests were performed, the possibility that digestive enzymes known to be present in the intestine may be elaborated by the goblet cells was considered, based on their variable appearance.     

The digestive tract of the amberjack Seriola dumerili, Risso: a light and scanning electron microscope study

The histology of the digestive tract of the amberjack ( Seriola dumerili , Risso) was studied using light and scanning electron microscopy. The anterior oesophagus mucosa displays primary and secondary folds lined with a stratified squamous epithelium with fingerprint-like microridges which is substituted, on the top of the oesogaster folds, by a simple columnar epithelium with short microvilli. Only primary folds are present in the stomach. The anterior portion is rich in simple tubular glands, whereas the oesogaster and the pyloric region are devoid of them. Pyloric caeca and anterior and middle intestine mucosa display the same pattern of folding. The dominant cell type is the enterocyte, which exhibits larger and thinner microvilli in the caeca than in the intestine. The columnar epithelium of the rectum is replaced, in the anal sphincter, by a stratified flattened epithelium. Goblet cells are numerous throughout the whole length of the tract with the exception of the initial part of the oesophagus, the oesogaster, the stomach and the anal sphincter. Mucosubstances have been shown to vary in the different regions of the gut: acid mucines are found in the oesophagus, pyloric stomach, caeca, intestine and rectum, whereas neutral mucosubstances dominate in the anterior portion of the stomach. The muscularis is well developed throughout the length of the tract: two layers of striated muscle at the oesophageal level; two layers of smooth muscle in the stomach wall and three at the intestinal level.     

马铁菊头蝠消化系统的组织学观察

应用石蜡常规切片、HE染色,对马铁菊头蝠消化系统各器官的组织结构进行了观察.结果 表明:食管粘膜上皮为复层扁平上皮,轻微角质化,前、中、后段的上皮结构没有显著差异,食管腺在前段较多,中、后段较少.胃固有层含有大量的管状腺.小肠粘膜表面有许多环形皱襞,在十二指肠上段粘膜下层分布有十二指肠腺.大肠粘膜表面光滑,无绒毛,在粘膜下层的结缔组织中有小动脉、静脉和淋巴管.肝内结缔组织多,肝小叶分界较明显,肝血窦发达.胰的小叶间分界不明显.     

泽陆蛙消化道组织学观察

采用解剖学和组织学的方法对泽陆蛙消化道各部分的形态和组织学结构进行了观察。泽陆蛙的消化道分为口腔、咽、食道、胃、十二指肠、回肠和大肠。各管壁都由黏膜层、黏膜下层、肌层和外膜组成。食道黏膜层有皱褶和纤毛,无杯状细胞;胃黏膜层有杯状细胞和胃腺,黏膜下层有血管分布;小肠具绒毛、杯状细胞和肠腺,大肠皱褶少,杯状细胞也少。     

Surface architecture of the oropharyngeal cavity and the digestive tract of Mulloidichthys flavolineatus from the red sea,Egypt: A scanning electron microscope study

Surface architecture of the buccal cavity and the surface organization of the luminal mucosa of the oesophagus, stomach, and intestine of the carnivorous fish M. flavolineatus from the Red Sea were studied by using SEM. The results revealed that M. flavolineatus has four kinds of teeth; curved-blunt, wedge-shaped, flattened crowns, molariform and papilliform. Three types of taste buds (type I, II and III) were recorded in the oropharyngeal cavity. It was observed that taste buds and teeth are co-located in the pharyngeal region. Characteristic patterns of microridges of the surface cells in the oral cavity and oesophagus were observed. Mucous cells are distributed in the lining of the mouth cavity, oesophagus, stomach, and intestine. Characteristic patterns of mucosal folds throughout the alimentary canal, concerning oesophagus, stomach, and intestine were revealed. Numerous gastric pits, which represents the emergence of the gastric glands, were recorded in the anterior and middle regions of the stomach. Complex patterns of the folds and mucous cells were recorded in the intestinal mucosa. These results were discussed with other teleost fishes.     

Structure of the gut of the racer goby Neogobius gymnotrachelus (Kessler, 1857)

The morphological and histological features of the gut of juvenile racer goby Neogobius gymnotrachelus [range of body mass 0·2–0·9 g and standard length ( L _S) 20·0–38·8 mm] were examined in fish collected from the Włocławek Reservoir on the Vistula River, Poland. Evidence is provided of the stomachless nature of the gut of the racer goby. The intestine of the juveniles lacks the intestinal bulb. A particular feature of the racer goby gut is the secretory oesogaster (the transitional region where the secretory oesophagus merges into the intestine) with multicellular alveolar glands that secrete via a common duct to the surface between the mucosal folds. The cells in the secretory oesogaster alveolar glands are periodic-acid-Schiff (PAS) positive indicating the presence of neutral mucopolysaccharides. It is hypothesized that the secretory oesogaster is evidence of the loss of the functional stomach in this species. There are two sphincters: the oesogaster–intestinal and the intestinal–rectal in the racer goby gut. It can be concluded that the oesogaster–intestinal sphincter is functionally related to the gastro-intestinal sphincter described in many fish species having a stomach. Enterocytes with a distinct brush border and only a few goblet cells are observed in the epithelium along the whole intestine. The existence of vacuoles in the supranuclear region of the rectal enterocytes is also confirmed.