三种蝗虫消化道贲门瓣形态比较

采用扫描仪和扫描电镜观察的方法对太原地区中华稻蝗、短额负蝗和东亚飞蝗的贲门瓣的形态结构进行了观察,并对其结构和功能进行了描述和分析.     

中华稻蝗全消化道内壁显微结构观察

本文采用扫描仪和扫描电镜对中华稻蝗消化道内壁的细微结构进行了系统观察和研究。结果表明,中华稻蝗食道内壁由纵行脊组成,前端有齿。嗉囊包括两段,前段的一个小的膨大部分,由V-形区和两侧的V-形脊组成,只在前端内壁有齿;后段为一个大的膨大部分,由柳叶脊、扇形脊和不规则脊组成,脊的上缘有齿。前肠内壁的齿主要为单生齿,除贲门瓣上齿的齿尖指向前方外,全部齿的齿尖指向后方。后肠的前端为12个幽门瓣,内壁有齿。回肠和结肠由6条纵行脊组成,结肠内壁有齿。直肠的齿在除直肠垫外的直肠内壁上。后肠的齿主要为丛生齿,后肠除直肠内壁齿的齿尖指向附着环外,全部齿的齿尖指向后方。根据我们的观察,对前肠提出了新的分区。     

黑水虻消化道形态及组织结构的观察

本文比较了不同发育阶段黑水虻Hermetia illucens消化道的形态学差异,掌握了幼虫消化系统的组织学特征。利用体视镜观察黑水虻5龄幼虫、预蛹及成虫的消化道形态,利用光学显微镜和扫描电镜观察幼虫消化道各段(前肠、中肠、后肠)的显微及超微结构。结果表明：黑水虻幼虫及预蛹的消化道均由前肠(食道和前胃)、中肠及后肠组成,从幼虫到成虫,消化道的长度不断缩短。与幼虫和预蛹相比,成虫消化道形态变化明显,前胃消失,出现了嗉囊及胃盲囊,中肠进一步缩短,后肠分化为回肠、结肠和直肠。组织学观察结果显示,幼虫的唾液腺开口于口腔,由膨大的管状腺体和腺管组成。食道由特化为角质刺突的内膜层及发达的肌层组成,其末端延伸至前胃。前胃膨大为球状,包括三层组织结构。根据上皮细胞形态的差异,中肠可分为四个区段。后肠薄,肠腔内褶丰富,肠壁可见数量较多的杆状细菌。马氏管开口于中、后肠交界处,包括4支盲管,管内壁密布微绒毛。黑水虻消化道形态随发育阶段的变化,反映了各阶段摄食及消化生理的差异。幼虫消化道各段具有各自典型的组织学特征,其前、中、后肠可能分别承担了食物接纳与初步消化、消化与吸收以及重吸收功能。本研究结果为进一步了...     

蝗虫消化道结构的比较研究

采用扫描仪分析方法对10种蝗虫消化道形态结构进行了观察比较,发现蝗虫不同类群个体其中肠占消化道总长的比例依进化地位呈现递增趋势,胃盲囊和后肠则呈递减趋势.这种趋势可能是随着蝗虫类群的进化,中肠在消化道所占的比例逐渐增大,对食物的消化吸收能力逐渐增强,与之相应的是胃盲囊呈退化趋势,同时后肠所排泄的残渣逐渐减少,导致蝗虫消化道形态发生适应性变化的结果.     

可口革囊星虫消化道的形态及组织学结构

对可口革囊星虫(Phascolosoma esculenta)消化道各部分结构进行了形态学和组织学观察,表明可口革囊星虫消化道由翻吻、咽、食道、肠、直肠和肛门组成。翻吻收缩性很强;肠道极长,沿纺锤肌螺旋缠绕成肠索。消化道管壁由内向外分为粘膜层、粘膜下层、肌层和外膜。粘膜上皮主要由柱状细胞组成。除肠外,消化道上皮细胞均有发达的纤毛,肠上皮细胞主要具发达的微绒毛;粘膜下层及肌层的发达程度因消化道的部位不同而异。     

马拉硫磷对东亚飞蝗消化道影响的形态学观察

为探讨农药马拉硫磷对东亚飞蝗Locusta migratioria manilensis(Meyen)消化系统的影响,文中以喂食形式给药,不同喂食时间点蝗虫处死后固定、石蜡包埋、连续切片、HE染色并观察蝗虫消化系统不同部位形态学的病理变化。结果表明马拉硫磷对东亚飞蝗嗉囊、前胃、胃盲囊、中肠、回肠、结肠、直肠等各消化道部位均能造成明显的形态学改变,包括内膜完整性被破坏、上皮细胞死亡、纵肌、环肌、结缔组织等病变和坏死等,且呈时间依赖性。故马拉硫磷的作用可以影响到东亚飞蝗对食物贮存、研磨、消化、养分吸收的每一个环节,最终导致蝗虫的死亡。本文研究结果对蝗虫防治研究具有重要意义。     

紫胫长夹蝗消化道的形态学观察

本文通过扫描仪对紫胫长夹蝗Choroedocus violaceipes Miller消化道内外壁进行了扫描.观察到消化道各部位的形态特征:食道直管状,由多列纵行脊组成;嗉囊由V形区、V形脊、柳叶脊、扇形脊和不规则脊组成;前胃杯形,由多列纵行脊组成;贲门是由6个凸出于肠壁的Y形结构环围而成;中肠膜质,约占消化道长度的2...     

中华稻蝗消化道内分泌细胞的鉴别与定位

采用整块组织Grimelius银染法和过氧化物酶标记的链霉亲和素免疫组织化学技术,结合生物统计学分析,对中华稻蝗Oxya chinensis消化道内分泌细胞进行鉴别与定位。结果表明：嗜银细胞分布于中华稻蝗的胃盲囊、中肠和后肠各段,以中肠和直肠中最多（P<0.05）, 前肠中未见分布。免疫组织化学法检测出了五羟色胺（5-hydroxytryptamine, 5-HT）、 胃泌素（gastrin, Gas）、 胰高血糖素（glucagon, Glu）和胰多肽（pancreatic polypeptide, PP）细胞, 未检出生长抑素（somatostatin, SS）细胞。免疫阳性细胞分布于中肠和后肠中, 前肠中未见分布。5-HT细胞和Gas细胞均主要分布于胃盲囊、中肠及直肠中,且均以直肠中最多（P<0.05）。Glu细胞在胃盲囊及整个中、后肠均有分布, 在中肠和直肠中最多（P<0.05）。PP细胞主要分布于中肠、回肠和直肠中,中肠中分布密度最大（P<0.05）。本研究显示中华稻蝗消化道中存在多种内分泌细胞,它们的分布情况与其他节肢动物相比存在一定的共性,也有其一定的特异性,可能与中华稻蝗特定的消化道结构和消化生理功能有关。     

四种蝗虫前肠形态的比较研究(直翅目:斑腿蝗科)

采用体视显微摄影技术对斑腿蝗科Ｃａｔａｎｔｏｐｉｄａｅ３属４种（亚科）蝗虫前肠形态进行了分析,并对分布于不同地区的同一亚种进行了观察。结果表明,斑腿蝗亚科几种前肠特征同一性很高,同种不同亚种之间略有差异,相同亚种不同地区之间不存在明显差异。     

野生与养殖黄鳍鲷消化道形态组织结构

采用常规石蜡组织切片的方法对野生和养殖黄鳍鲷(Sparus latus)消化道的形态组织结构进行了比较观察。结果表明,野生和养殖黄鳍鲷的消化道存在一定差异。(1)形态学研究表明,食道粗而短,胃呈V形,分为贲门部、胃体部和幽门部,胃与肠的连接处有4条幽门盲囊,肠道在体腔内迂回两个回折。野生黄鳍鲷牙齿更为坚硬锋利,体腔中脂肪较少,消化道更为粗短。野生和养殖黄鳍鲷的肠道系数分别为0.71±0.03和0.94±0.12。(2)组织学研究表明,食道黏膜上皮由扁平细胞层和杯状细胞层组成,杯状细胞发达。胃黏膜由单层柱状上皮组成,无杯状细胞,贲门部和胃体部胃腺发达。幽门盲囊组织学特征与肠相似,上皮为柱状上皮,其中的杯状细胞少于肠。肠中,前肠杯状细胞最多,中肠次之,后肠最少。直肠杯状细胞多于肠。野生与养殖黄鳍鲷组织学的区别在于,消化道相同部位养殖鱼的杯状细胞多于野生鱼,野生鱼的肌层厚度大于养殖鱼。黄鳍鲷消化道的形态组织结构与其生活环境和食物是相关的。     

日本纺织娘消化系统的细微构造

运用光镜及扫描电镜的技术对日本纺织娘MecopodaniponensiDeHaan消化道的内、外结构进行了研究。结果表明 :日本纺织娘的消化系统可分为前肠、中肠和后肠三大段 ,其前肠的结构较为特殊 :嗉囊内壁具有排列紧密的大刺 ,前胃内部则有 6列骨化大嵴 ,嵴上具大齿。胃盲囊分上、下两叶 ,上叶又被膜分隔成若干小叶。因这些特征在不同种类的螽斯中均不相同 ,所以在分类上具有一定的意义 ,同时也为农业上进行害虫防治及天敌昆虫的研究提供解剖生理学方面的依据     

日本纺织娘消化系统的微细构造

运用光镜及扫描电镜的技术对日本纺织娘Mecopoda niponensi De Haan消化道的内、外结构进行了研究.结果表明日本纺织娘的消化系统可分为前肠、中肠和后肠三大段 ,其前肠的结构较为特殊嗉囊内壁具有排列紧密的大刺,前胃内部则有6列骨化大嵴, 嵴上具大齿.胃盲囊分上、下两叶,上叶又被膜分隔成若干小叶.因这些特征在不同种类的螽斯中均不相同,所以在分类上具有一定的意义,同时也为农业上进行害虫防治及天敌昆虫的研究提供解剖生理学方面的依据.     

Morphological and ultrastructural characterization of the alimentary canal in larvae of Streltzoviella insularis (Staudinger) (Lepidoptera: Cossidae)

Streltzoviella insularis (Staudinger) is an important tree‐boring pest, that primarily damages Sophora japonica (Linnaeus) and Ginkgo biloba (Linnaeus), as well as other common species, at great economic cost to the urban landscape construction industry in China. In the present study, the alimentary canal morphology of S. insularis was observed using light microscopy, and its ultrastructure was investigated by scanning and transmission electron microscopy. The foregut of S. insularis can be divided into the pharynx, esophagus, crop, proventriculus, and cardiac valve. The well‐developed crop forms the longest section of the foregut. It is able to store large amounts of food and is lined with a monolayer of epithelial cells. Many sclerotized microspines occur on the surface of the anterior intima and there are dense spines on the posterior intima of the proventriculus. Epithelial cells of the midgut include columnar cells, goblet cells, and regenerative cells, but endocrine cells are absent. The hindgut consists of the pyloric valve, ileum, and rectum. There is no clear distinction between the ileum and colon. The intima surface of the pyloric valve carries many microspines, whereas the intestinal wall of the rectum is thin with well‐developed rectal pads. The rectal epithelial cells form a squamous monolayer. A cryptonephric excretory system is located in the hindgut. There are six spiral Malpighian tubules, in which a cellular layer on a basement membrane encloses a lumen. These results will provide the basis for further studies of the structure and function in S. insularis larvae.     

Immnunohistochemical detection of phthalate esters in the alimentary canal of Tilapia spp.

An examination of the occurrence and distribution of phthalate esters in the alimentary canal of a polyhybrid of Tilapia gave evidence of different and selective patterns of distribution in the organ tissues: the phthalate esters were shown to be concentrated in the stomach and anterior intestine. The restricted distribution of phthalate esters can have implications for the physiology of the digestive system. The phthalates, stored in the oxyntic cells of the gastric tubular glands, probably interfere with the digestive process. The strategic location of the enterocytes in the anterior intestine implies that they can hamper the reabsorption of digestion products. The endocrine disrupting effects known for these chemicals are probably related to the absorption of them via the alimentary canal.     

光滑足距小蠹消化道的解剖结构

采用体视显微和扫描电镜技术研究光滑足距小蠹Xylosandrus germanus(Blandford)消化道的解剖结构。结果表明,光滑足距小蠹消化道由前肠、中肠和后肠三部分组成。成虫前胃由8个骨化的前胃板组成,呈灯笼状结构。前胃板由板状部和片状部组成,板状部短而简单,片状部甚长,由斜面、咀嚼刷和关闭刚毛组成。胃盲囊着生在中肠近后端,有细管状和囊状2种,成虫分别有1对,幼虫有1对细管状和3~5对囊状。6根马氏管分成2组,1组4根,另一组2根。6根马氏管与后肠肠壁形成隐肾系统。消化道具有1对囊状和1对细管状的胃盲囊可作为光滑足距小蠹成虫的识别特征。     

黄脸油葫芦消化道和马氏管的组织学观察

应用石蜡切片技术对黄脸油葫芦Teleogryllus emma(Ohmachi and Matsumura)成虫消化道和马氏管的显微结构进行观察。消化道由前肠、中肠和后肠3部分组成:前肠由内向外可分为6层:内膜、肠壁细胞层、底膜、纵肌、环肌和围膜;中肠组织结构也分为6层,即由内向外依次为围食膜、肠壁细胞层、底膜、环肌、纵肌和围膜;后肠的组织结构与前肠基本相似,但内膜比前肠的薄,且肌肉的排列较前肠不规则,与中肠的肌肉排列相似,即环肌在内,纵肌在外。消化道各部位的结构差异与功能有密切关系。马氏管管壁由8个左右形状多变并具有显著细胞核的大形的单层上皮细胞组成。     

Histology and carbohydrate histochemistry of the alimentary canal in the rainbow trout Oncorhynchus mykiss

A histological and histochemical analyses were carried out on the entire alimentary canal of the rainbow trout Oncorhynchus mykiss . In particular the oesophageal region showed presence of terminal β‐D‐galactose(1–3)‐N‐acetylgalactosamine and α‐N‐acetylgalactosamine. In the anterior and posterior regions of the stomach, lining epithelium and gastric pits exhibited the presence of β‐gal and α‐GalNAc. In addition sialoglycoconjugates having sialic acid–β–galactose(1–3)‐N‐acetylgalactosamine and sialic acid‐N‐acetylgalactosamine as terminal tri‐ and di‐saccharides, were demonstrated. In proximal and distal intestine goblet cells showed the presence of sialoglyconjugates, having sialic acid‐β‐gal(1–3)‐GalNAc and sialic acid‐GalNAc as terminal sequences, belonging to N‐linked chains. In the enterocytes of the entire intestine, terminal GlcNAc, α‐Gal, α‐fucose were found.     

A histochemical study of pollen digestion in the alimentary canal of honeybees (Apis mellifera L.)

Histochemical staining of embedded sections of the alimentary canal of honeybees indicated that carboxylated polysaccharides could be efficiently digested and absorbed, except when sequestered within unswollen and unbroken pollen grains that appeared to be impervious to enzymes of the gut. Hemicelluloses and pectic acids of the pollen wall structure underwent partial digestion, but pollen wall cellulose and sporopollenin were not digested. A separation of pollen walls from colloidal semisolids of the pollenkitt and disgorged protoplasm was apparent. The layers of slurry created by this separation remained into the rectum, and consisted primarily of saturated organic compounds which do not stain with weakly basophilic or acidophilic dyes.