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1.
C. Knospe 《Anatomia, histologia, embryologia》1996,25(2):75-94
The development of the gastric glands of the cat (Felis silvestris catus) There are five stages in the development of the cat's gastric glands: 1. During the stage of the indifferent epithelium from day 19 to day 24, the anlage of the stomach develops with all layers; 2. The stage of gland formation from day 24 to day 41 is the beginning of the gland buds. They develop in connection with endocrine cells on day 34 into primitive oxyntic and primative mucous cells. The latter form the basis for all other cells, including the surface mucous cells; 3. During the stage of gland evagination from day 42 to 55, the anlagen are separated into primitive pits and tubules, while the cells continue to differentiate and the first intermediate cells are seen; 4. The stage of gland branching from day 56 to birth is characterized by the formation of additional glands at the bottom of the pits which change the ordinary anlagen into branched glands. During this stage, the cardiac glands are formed; 5. In the stage of gland maturation from birth to the 9th week, the peptic cells are formed and the glands start functioning. The oxyntic cells show carbonic-anhydrase activity and signs of acid secretion, and, between the weeks 4 and 8, the peptic cells contain pepsinogen, producing a negative reaction to PAS and a positive reaction to HID. Mucous cells and mucous neck cells produce PAS- and AB-positive mucin. 相似文献
2.
The postnatal development of the stomach in the Japanese field vole, Microtus montebelli , were studied with the light and scanning electron microscopes.
Three kinds of cells constituting the fundic glands, that is, mucous neck cells, parietal cells and chief cells were distinguished clearly by light microscopy to have been differentiated around 14 days old. At 4 days old, the structure of pyloric glands was similar to that of adult stage. The investigation on the development of esophageal sac, fundic stomach and pyloric stomach was made by measuring each area of the vertical section. The fundic stomach grew more rapidly than the esophageal sac and pyloric stomach. The ratio of esophageal sac to fundic stomach and pyloric stomach in the area was about 1.5: 2: 1 at 20 days old.
In the fundic glands, 5-hydroxytriptamine (5-HT)- and somatostatin-immunoreactive cells appeared first at 6 days old and at birth, respectively and in the pyloric glands, gastrin-, 5-HT- and somatostatin-immunoreactive cells appeared at 19th day fetus. Gastrin-immunoreactive cells showed a rapid increase in the pyloric glands after birth. The distribution and frequency of endocrine cells were similar to that of adult at about 20 days old.
The fimbria showed bank-like appearance at the beginning and thereafter they showed the process-like structure. The fimbria in both the appearance and the length at 60 days old was similar to that of adult stage.
As a whole, the stomach of the field vole seemed to became mature at 20 days old in the aspects of gastric endocrine cells and morphology of gastric wall, although the fimbria formation was not accomplished at the same period. 相似文献
Three kinds of cells constituting the fundic glands, that is, mucous neck cells, parietal cells and chief cells were distinguished clearly by light microscopy to have been differentiated around 14 days old. At 4 days old, the structure of pyloric glands was similar to that of adult stage. The investigation on the development of esophageal sac, fundic stomach and pyloric stomach was made by measuring each area of the vertical section. The fundic stomach grew more rapidly than the esophageal sac and pyloric stomach. The ratio of esophageal sac to fundic stomach and pyloric stomach in the area was about 1.5: 2: 1 at 20 days old.
In the fundic glands, 5-hydroxytriptamine (5-HT)- and somatostatin-immunoreactive cells appeared first at 6 days old and at birth, respectively and in the pyloric glands, gastrin-, 5-HT- and somatostatin-immunoreactive cells appeared at 19th day fetus. Gastrin-immunoreactive cells showed a rapid increase in the pyloric glands after birth. The distribution and frequency of endocrine cells were similar to that of adult at about 20 days old.
The fimbria showed bank-like appearance at the beginning and thereafter they showed the process-like structure. The fimbria in both the appearance and the length at 60 days old was similar to that of adult stage.
As a whole, the stomach of the field vole seemed to became mature at 20 days old in the aspects of gastric endocrine cells and morphology of gastric wall, although the fimbria formation was not accomplished at the same period. 相似文献
3.
The gastroenteropancreatic (GEP) endocrine cells of the Japanese field vole were studied immunohistochemically. Somatostatin-, 5-hydroxytryptamine-, glicentin-, glucagon-, bovine pancreatic polypeptide-, gastrin-, gastric inhibitory polypeptide-, cholecystokinin-, substance P-, secretin-, neurotensin- and insulin-immunoreactive cells were revealed. The characteristic findings of the regional distribution and relative frequency of these immunoreactive cells in the GEP system of the vole were as follows. Somatostatin-immunoreactive cells were more numerous in the oxyntic glands than in the pyloric glands. Some somatostatin-immunoreactive cells were found in small clusters in the oxyntic glands. Gastrin-immunoreactive cells were detected not only in the pyloric glands and small intestine but also in the caecum and spiral colon. Gastric inhibitory polypeptide-immunoreactive cells were also detected in the pyloric glands and no motilin-immunoreactive cell was found in the gastroenteropancreatic system. 相似文献
4.
Shimokawa T Doihara T Makara M Miyawaki K Nabeka H Wakisaka H Kobayashi N Matsuda S 《The Journal of veterinary medical science / the Japanese Society of Veterinary Science》2012,74(2):155-160
The stomach of the Pacific white-sided dolphin is divided into three parts: forestomach, proper gastric gland portion, and pyloric chamber. The histological features of the dolphin stomach are similar to those of terrestrial mammal stomachs, although the distribution of glycoconjugates in mucosal cells of the dolphin stomach is unknown. To learn about glycoconjugates in cetacean gastric mucosa, the glycoconjugate distribution in the mucous epithelium of the Pacific white-sided dolphin was studied using 21 lectins. Among the lectins tested, GSL-I and DBA specifically labelled the superficial layer of the forestomach epithelium. GSL-I, SBA, RCA-I, VVA, GSL-II, DSL, LEL, STL, s-WGA, WGA, PNA, and Jacalin labelled the luminal surface of the chief cells in the proper gastric gland. GSL-I, SBA, RCA-I, DSL, LEL, STL, s-WGA, PNA, and LCA labelled tubular structures in the cytoplasm of parietal cells. The surface portion of the pits in the pyloric chamber strongly reacted with RCA-I, GSL-II, WGA, PNA, LCA, PHA-L, and UEA-I, whereas the neck portion reacted weakly. Although lining one tubular portion, individual secretory cells in the pyloric gland displayed a heterogeneous reaction. This is the first report on the lectin histochemistry of a cetacean stomach and reveals GSL-I and DBA as specific marker lectins for the cornified stratified squamous epithelium cells of the Pacific white-sided dolphin. The stomachs of cetaceans and terrestrial mammals have similar histological features and mucous glycoconjugate content. 相似文献
5.
The morphology, distribution and relative frequencies of endocrine cells in the gastrointestinal tract of the barking deer (Muntiacus muntjak) were investigated. The immunohistochemical method employed used seven types of antisera against chromogranin, serotonin, gastrin, cholecystokinin, somatostatin, glucagon and insulin. Chromogranin and serotonin immunoreactive (IR) cells were found throughout the gastrointestinal tract. Conversely, gastrin-IR cells were only found in the oxyntic gland, pyloric gland and duodenum, while cholecystokinin-IR and somatostatin-IR cells were detected in the oxyntic gland, pyloric gland and small intestines. Somatostatin-IR cells were also seen in the caecum. Glucagon-IR cells were found in all parts of the gastrointestinal tract apart from the colon and rectum. No insulin-IR cells were found in the gastrointestinal tract of this species. The cells in the small intestine were generally spindle shaped with long cytoplasmic processes ending in the lumen (open type), while in the stomach and large intestine, they were occasionally round or spherical in shape (closed type). An uncommon distribution pattern of endocrine cells in the gastrointestinal tract of the barking deer was noted for cholecystokinin- and glucagon-IR cells. 相似文献
6.
Moraes PT Pacheco MR de Souza WM da Silva RA Neto PB Barreto CS Ribeiro AA 《Anatomia, histologia, embryologia》2002,31(6):362-366
The digestive system of the capybara has been investigated because of its coprofagia habits, important for their absorptive activity. These species present differences in terms of gastrointestinal morphological characters when compared with other rodents. Macroscopiclly, the stomach of the capybara is constituted of the following parts: cardiac, pyloric, body, fundic and gastric diverticulum. It presents two curvatures, one big and another small. Externally, the presence of gastric bands (tenias) is observed. With regards to the volumetric view, the gastric capacity varies from 850 to 2010 ml, with an average of 1498.57 ml. So, the stomach of this animal can be classified as a simple stomach, in the format of a curved sack and similar to an inverted letter 'J'. The gastric mucous membrane presents a surface filled by numerous tortuous gastric folds and longitudinally distributed along all its extension. The mucous tunic also possesses recesses located among the successive gastric folds, which were denoted as gastric parts with numerous openings described as gastric pits. In the cardiac part, a glandular epithelium with cardiac glands is noticed containing a lot of parietal and mucous neck cells. The fundic part, body and gastric diverticulum contain proper gastric glands with main, parietal and mucous neck cells. Finally, the pyloric part has pyloric glands with two cellular types, mucous neck and parietal cells. 相似文献
7.
Immunocytochemical distribution of endocrine cells in the gastrointestinal tract of the horse 总被引:1,自引:0,他引:1
Endocrine cells immunoreactive for somatostatin, gastrin, glicentin, glucagon, secretin, cholecystokinin, motilin and neurotensin were identified immunocytochemically in the gastrointestinal mucosa of the horse. Somatostatin-, glicentin- and glucagon-immunoreactive cells were very numerous in the cardiac and fundic regions of the stomach, whereas most gastrin-immunoreactive cells were confined to the pyloric region. Somatostatin-immunoreactive cells also were detected in all portions of the small intestine while gastrin-immunoreactive cells were confined exclusively to the upper portion and glicentin-immunoreactive cells were limited to the lower portions of the small intestine. Secretin-, cholecystokinin- and motilin-immunoreactive cells were observed only in the duodenum, while neurotensin-immunoreactive cells were confined primarily to the ileum. In the large intestine, somatostatin- and glicentin-immunoreactive cells were detected in the colon and rectum. The preferential location of endocrine cells provides additional information for future studies on the physiological roles of gastrointestinal peptides in the gastrointestinal tract of the horse. 相似文献
8.
秦岭细鳞鲑消化系统的形态学观察 总被引:1,自引:0,他引:1
运用大体解剖和常规组织学方法对秦岭细鳞鲑消化系统的组织形态进行了系统观察。结果表明,秦岭细鳞鲑的消化道由口咽腔、食道、胃和肠等4部分组成,除口咽腔外,管壁由内向外分为黏膜、黏膜下层、肌层和浆膜。口咽腔宽大,上颌、犁骨及腭骨等处布有细齿,黏膜衬以复层扁平上皮,间有较多的黏液细胞和少量的杯状细胞及味蕾;食管粗而短,黏膜向管腔突出形成多个纵行皱襞,上皮由复层扁平上皮逐渐向单层柱状过渡,上皮细胞间可见到数量较多的粘液细胞和杯状细胞,食管腺不发达;胃体积较大,呈“U”形,包括贲门部、胃体和幽门部,胃体部小凹及胃底腺结构明显,肌层发达;胃与肠相接处有63-65个幽门盲囊,肠道粗短而略微盘曲,黏膜上皮为单层柱状,未见明显的肠腺。以上结果显示,秦岭细鳞鲑消化道组织结构与其肉食性功能密切相关。肝小叶界限不清;双列肝细胞围绕中央静脉呈放射状走行,肝细胞个体大、呈多边形,核呈圆形或卵圆形,1-2个。胰脏大部分环绕前肠边缘、呈细长条索状,另可见分散于幽门盲囊及胃周围的弥散部分;其外分泌部为管泡状腺,腺细胞呈锥体形,胰岛结构明显。 相似文献
9.
T. S. Leeson 《Anatomia, histologia, embryologia》1975,4(2):97-112
The effects of varying intensities of histamine stimulation on cells of the western newt fundic stomach epithelium have been studied. Oxyntic, mucous neck and surface mucous cells all secrete. In the oxyntic cell, the main effects are a movement of zymogen granules toward the apex, the discharge of their contents into the lumen and, eventually, their disappearance from the cytoplasm. Additionally, the tubular membrane elements (tubulo- vesicles) fuse with the apical plasma membrane with a corresponding reduction in their numbers and an increase in microvilli, which eventually are so numerous as to virtually occlude the lumina of gastric glands. Total histamine stimulation results in apparent damage to the oxyntic cells. Mucous neck and surface mucous cells release their mucigen droplets by exocytosis and are grossly changed in appearance also. 相似文献
10.
T. S. Leeson 《Anatomia, histologia, embryologia》1975,4(1):38-55
Triturus torosus has a resting fundic stomach with gastric pits and glands and cell types similar to previously described amphibian species. Lining the surface and the gastric pits are columnar mucus-secreting cells. They differ in morphology and staining reactions from the mucous-neck cells, the second type of mucus-secreting cells. The latter are confined to a limited region at the necks of gastric glands where they empty into the pits and appear to “isolate” the main oxyntic, acid-secreting cells from the surface mucous cells. The gastric glands are lined by a single cell type, the oxyntic cell, which shows features of both the mammalian chief (zymogenic) and parietal (oxyntic) cells and which presumably secretes both enzymes and acid. This cell has a prominent granular endoplasmic reticulum with prezymogen and zymogen granules, numerous mitochondria, and in the apical cytoplasm an extensive system of tubules and tubulovesicles. The membrane bounding these tubules appears identical to the surface plasmalemma, and occasional continuity between the two can be demonstrated. The oxyntic cells have also a few apical microvilli and intercellular but not intracellular canaliculi. Occasional argentaffin or enterochromaffin cells with few granules are scattered among the oxyntic cells. Like other amphibia, the western newt feeds intermittently and thus is a good experimental animal for the study of gastric secretion. 相似文献
11.
H S Lee Y Hashimoto Y Kon M Sugimura 《The Japanese journal of veterinary research》1991,39(2-4):117-131
The regional distribution and relative frequencies of gastrointestinal endocrine cells were studied immunohistochemically in the gastrointestinal mucosa of Korean tree squirrels. Seven kinds of endocrine cells were identified in this study. Although a large number of 5-hydroxytryptamine-immunoreactive cells were seen throughout the gastrointestinal tract, they were most predominant in the duodenum. A moderate number of glucagon-immunoreactive cells which were restricted to the cardia and fundus of the stomach was also observed. Bovine chromogranin-immunoreactive cells were numerous in the cardia and pylorus of the stomach, found in moderate numbers in the fundus, duodenum and large intestine, but rare in the jejunum. Porcine chromogranin-immunoreactive cells were found in moderate numbers in the stomach but were rare in the duodenum. Gastrin/cholecystokinin-immunoreactive cells were abundant in the pyloric gland region but scarce in the duodenum. Bovine pancreatic polypeptide-immunoreactive cells were observed to be rare and found only in the pyloric gland region. Somatostatin-immunoreactive cells were distributed moderately in the stomach but were few in number in the intestine. No insulin-immunoreactive cells were found in the gastrointestinal tract of Korean tree squirrels. These results suggest that although the Korean tree squirrel is a herbivorous rodent, the distribution pattern of its gastro-entero-endocrine cells is rather similar to that reported for omnivorous animals. 相似文献
12.
野生黄鼬消化管组织结构的观察 总被引:1,自引:1,他引:0
通过组织学观察,探讨野生黄鼬消化管的组织结构特点.将8只野生黄鼬经乙醚麻醉后处死,解剖取食管、胃、小肠、大肠,制作石蜡切片,观察其组织结构.结果显示野生黄鼬食管的黏膜为复层扁平上皮,食管腺发达,肌层以骨骼肌为主.胃贲门部有发达的皱襞和贲门腺;胃底腺有大量的主细胞和壁细胞;胃大弯部的腺体以壁细胞为主,仅有少量主细胞;胃幽门部有发达的幽门腺和大量壁细胞.十二指肠黏膜层有小肠腺,内有潘氏细胞存在,黏膜下层含有十二指肠腺;空肠可见孤立淋巴小结、弥散淋巴组织及集合淋巴小结.结肠无皱襞和肠绒毛,大肠腺排列紧密,其中杯状细胞特别多;直肠固有膜内有发达的大肠腺.所以野生黄鼬消化管的特点是胃各部胃腺发达,壁细胞特别多. 相似文献
13.
C. van Ginneken A. Weyns F. van Meir L. Ooms A. Verhofstad 《Anatomia, histologia, embryologia》1996,25(4):269-275
Using an immunohistochemical technique, the presence and distribution of vasoactive intestinal polypeptide (VIP) was investigated in cryostat sections, both tangential and transverse, of the fetal pig's stomach. In all fetuses and in all gastric segments investigated, VIP-like immunoreactive (IR) nerve-cell bodies were seen in all intramural ganglia, and VIP-IR nerve fibres were found in all layers of the gastric wall except the tunica serosa. Consequently, VIP-IR nerve fibres were found to form a periglandular network, to accompany arterioles, to interconnect the intramural ganglia, to encircle both VIP-IR-negative and -positive neurons, and were found in all muscle layers. Despite the fact that VIP-IR seems to be restricted to the intramural nervous elements, some nonspecific-reacting VIP-IR glandular cells were noticed in the basal parts of the fundic, antral and pyloric gastric glands. The distribution pattern of VIP in the fetal pig resembles that of the adult pig. This suggests a possible functional role for VIP during fetal life and/or puts forward the suggestion that the stomach of a fetal pig from the second half of the gestation period is prepared, from then on, for postnatal function. High similarities with regard to the general distribution pattern of VIP in the stomach have also been noted between the fetal pig and humans, proving once more that the fetal pig can serve as a good animal model in several research areas. Finally, the morphological data provided here may, combined with the physiological significance of VIP, contribute to a better insight into the physiopathology of economically important gastro-intestinal disorders in the pig, such as gastric ulceration. 相似文献
14.
Immunohistochemical study on the distribution of endocrine cells in the gastrointestinal tract of the babirusa, Babyrousa babyrussa (Suidae) 总被引:3,自引:0,他引:3
Agungpriyono S Macdonald AA Leus KY Kitamura N Adnyane IK Goodall GP Hondo E Yamada J 《Anatomia, histologia, embryologia》2000,29(3):173-178
The distribution and relative frequency of endocrine cells in the gastrointestinal tract of the babirusa were studied immunohistochemically using the avidin-biotin-peroxidase complex method. Thirteen types of gut endocrine cells were detected; they were immunoreactive for chromogranin, serotonin, somatostatin, gastrin, bovine pancreatic polypeptide (BPP), glucagon, secretin, cholecystokinin (CCK), methionine-enkephalin-Arg6-Gly7-Leu8 (MENK8), motilin, gastric inhibitory polypeptide (GIP) and peptide tyrosine tyrosine (PYY). Cells that were immunoreactive for chromogranin, serotonin, somatostatin and glucagon were found in all portions of the gastrointestinal tract. MENK8-immunoreactive cells were observed in the stomach and small intestine. Gastrin-immunoreactive cells were detected in the pyloric region and duodenum. PYY-immunoreactive cells were found in the small and large intestine. Cells immunoreactive for motilin, CCK, GIP, and secretin were observed in the proximal small intestine and those immunoreactive for neurotensin were found only in the ileum. Although the distribution pattern of endocrine cells in the gastrointestinal tract of babirusa was similar to those reported for pig, restricted distribution of several endocrine cells, gastrin, BPP, MENK8, motilin, CCK, GIP, secretin and neurotensin and wider distribution of glucagon and PYY were observed in the babirusa. The unexpected presence of MENK8 in all glandular regions of the stomach and PYY in the small intestine was also noted. The distribution of gut endocrine cells might be related to the regulatory characteristics of the babirusa digestive tract. 相似文献
15.
为揭示牦牛皱胃组织结构和黏膜免疫相关细胞的分布与数量变化的规律,采用组织化学法、图像分析法及透射电镜技术,对牦牛皱胃组织结构及上皮内淋巴细胞、浆细胞和肥大细胞变化进行了研究.结果表明:牦牛皱胃胃壁由黏膜层、黏膜下层、肌层和浆膜构成.皱胃幽门腺区胃小凹深度最深、腺体最长、肌层最厚;3个腺区肌层厚度、腺体长度之间差异极显著(P<0.01);幽门腺区与胃底腺区、贲门腺区之间胃小凹差异极显著(P<0.01),胃底腺区与贲门腺区之间差异不显著(P>0.05).牦牛皱胃黏膜上皮内淋巴细胞数量和浆细胞数量,3个腺区之间差异不显著(P>0.05);肥大细胞数量以胃底腺区最多,幽门腺区最少,两者之间差异极显著(P<0.01),贲门腺区与胃底腺区和幽门腺区之间差异不显著(P>0.05).皱胃各腺区固有层中均有大量的弥散淋巴细胞和孤立淋巴小结.电镜观察表明,胃小凹柱状上皮细胞排列紧密.幽门腺区固有层中有大量的黏液细胞,黏液细胞呈高柱状或锥体状,核位于基底部,在细胞顶端常聚集有较多的电子密度较高的颗粒.胃底腺区和贲门腺区有大量的壁细胞和主细胞.牦牛皱胃的组织结构和其他反刍动物基本相似,但各层有其明显特点.牦牛皱胃各腺区固有层中均有大量弥散淋巴细胞和孤立淋巴小结,使牦牛皱胃具有比其他反刍动物更强的黏膜免疫功能. 相似文献
16.
Mucosal morphology, morphometry and mucin histochemistry of the stomach were studied in the one-humped camel. The lining of the stomach was divided into eight grossly identifiable regions. The first region was non-glandular, occupied the body of the first compartment of the stomach and constituted 53.2% of the gastric mucosa. The other seven regions were lined by a glandular mucosa. Histological, histochemical and morphometric investigations have shown that glandular mucosa comprises pseudo-cardiac, cardiac, fundic and pyloric regions. The pseudo-cardiac region was characterized by widely separated short tubular serous glands. It constituted 36.2% of the gastric mucosa; it extended over the entire lining of the second compartment and parts of the first and third compartments. The cardiac region was confined to the initial zone of the third compartment amidst the psuedo-cardiac region but contiguous with the distal end of the gastric groove. It constituted 3.4% of the gastric mucosa and was characterized by neutral and acid mucin positive glands. The fundic and pyloric regions occupied the distal distended part of the third compartment. The fundic region constituted 4.3% of the gastric mucosa. It was packed with typical fundic glands characterized by chief cells, parietal cells and acid mucin positive neck cells. The pyloric region constituted 2.9% of the gastric mucosa. Its glands were positive to acid mucins except for their bases that were positive to neutral mucins. Differences in volume densities of the mucosal components and reactivity of the surface epithelium and gastric pits to mucin stains were noted in the different regions of the stomach. 相似文献
17.
The development of the gastric gland cells in the ferret was studied with particular reference to maturation during the postnatal period. In the newborn, the glands consist of immature parietal cells with numerous mitochondria, and shallow rudimentary intracellular canaliculus with numerous microvilli, and undifferentiated cells. At one week old, mucous neck cells are present containing scattered mucin granules and the parietal cells contain tubulovesicular components. At two weeks old chief cells can be seen with large secretory granules in their basal cytoplasm. The gastric gland cells subsequently increase considerably in size, and their epithelium undergoes rapid histological maturation towards weaning. 相似文献
18.
Shimokawa T Yamagiwa D Hondo E Nishiwaki S Kiso Y Makita T 《The Journal of veterinary medical science / the Japanese Society of Veterinary Science》2003,65(3):423-426
To accumulate histological information of cetaceans, the proper gastric gland of Minke whales was examined by light and electron microscopic observation. A small number of mucous neck cells and a large number of chief and parietal cells were observed in the gland. At the body to basal portions of the gland, the ratio of chief cells to other cells seemed to be large compared to the neck portion. Transmission electron microscopy revealed that the chief cell had secretory granules with middle level of electron density, and that the parietal cell contained abundant mitochondria and intracellular canaliculi. The proper gastric gland of the Minke whales may appear to secrete large amounts of digestive enzymes and have high digestive activity. 相似文献
19.
Histology and Mucin Histochemistry of The Digestive Tract of Yellow Catfish, Pelteobagrus fulvidraco
The histology and characteristics of mucins secreted by epithelial mucous cells of the digestive tract in yellow catfish, Pelteobagrus fulvidraco were investigated using light microscope and transmission electron microscope. The digestive tract was divided into a pharynx, oesophagus, U-shaped stomach (with a cardiac, fundic and pyloric part) and intestine, composed of anterior intestine, middle intestine and posterior intestine, which consisted of a mucosa (epithelial layer), lamina propria-submucosa, muscularis and serosa. A large number of isolated longitudinal striated muscular bundles were present in the lamina propria-submucosa of pharynx. Goblet cells were observed throughout the digestive tract, except in the stomach. In the cardiac and fundic stomach, a plenty of gastric glands were observed, whereas they were absent in the pyloric part. Numerous mitochondria and endoplasmic reticulum were observed in the columnar epithelial cells of the intestine, especially of the anterior part. The epithelial mucous cells contained neutral or other two mixtures of acid and neutral mucins, the first being the most common. The neutral mucin was the only type of mucins in the stomach, anterior intestine and middle intestine. The results of this study will be helpful for understanding the digestive physiology and diagnosing some gastrointestinal diseases in yellow catfish. 相似文献
20.
Carbohydrate histochemistry of the alimentary canal of the shi drum, Umbrina cirrosa L 总被引:2,自引:0,他引:2
Pedini V Scocco P Radaelli G Fagioli O Ceccarelli P 《Anatomia, histologia, embryologia》2001,30(6):345-349
Histochemical staining techniques, which differentiate the main categories of carbohydrates, were applied to sections from different segments of the alimentary canal of the shi drum Umbrina cirrosa L. to study patterns of distribution of epithelial glycoconjugates. In the oesophagus, mucous cells contained sulphomucins, together with a small amount of sialomucins. Stomach epithelial cells secreted neutral and acidic glycoconjugates, while gastric glands only produced small quantities of sialomucins. Goblet cells showed the presence of sialo and sulphomucins in the pyloric caeca, whereas intestinal mucous cells secreted sulphated glycoconjugates. This work serves as a baseline for further studies on carbohydrate composition of the mucosa of the shi drum digestive system. 相似文献