人胎大肠氮能神经元发育的研究

用NADPH-d组织化学法对人胎大肠氮能神经元的发育进行了观察.结果表明第5个月胎龄时,肌间神经节处圆形细胞中部分细胞出现一氧化氮合酶(NOS)阳性反应,并分化成氮能神经细胞.第6个月胎龄时,氮能神经元胞体增大,突起伸长,在肌层、粘膜下层和肠腺基部出现氮能神经纤维分布.第7个月胎龄时,氮能神经元生长发育达到高峰,肌间神经节细胞数目增多,环肌层神经纤维分布密度增加,膨体结构明显.第8-10个月胎龄时,氮能神经元染色强度加深,其胞体分布以肌间神经节最多,粘膜下层和内环肌层较少.氮能神经纤维的分布密度以内环肌层最高,粘膜下层和外纵肌层次之,粘膜层较低.本研究揭示了大肠氮能神经元发育的变化规律.     

棕色田鼠小肠肌间神经丛NOS的组织化学观察

用NDP-黄递酶组织化学法研究了NOS在棕色田鼠（Microtus mandarinus)小肠肌间神经丛的分布,同样的方法对大白鼠进行了实验比较。结果发现,棕色田鼠小肠肌间祖辈 经丛NOS阳性神经元形态各异,大小悬殊数倍;在神经节和阳性神经纤维中可见阳性神经元呈“串珠”状和“U”型排列。10倍镜下记数100个视野,观察到阳性神经元平均密度为42.8个/mm^2,每个视野内平均有神经节12.4个,每个神经节内平均有NOS阳性神经元8.5个,占其神经节内神经元总数的27.2%,棕色田鼠为野生草食性动物,其NOS在小肠肌间神经丛的分布与其他杂食性啮齿类有相同之处,但也存在着种属差异。     

大鼠食管胸段，腹段乙酰胆碱酯酶阳性神经的配布

大鼠食管胸段和腹段壁内乙酰胆碱酯酶（ＡＣｈＥ）阳性神经存在于神经束和分支的粗细神经纤维内,也见于外膜丛,肌间丛,粘膜下丛和粘膜肌内。食管肌层内ＡＣｈＥ阳性神经纤维多而密集,而食管腹段肌内尤为丰富,肌间神经纤维末梢分布于肌束表面,可能与控制肌纤维活动有关;分布于肌内,粘膜下层和上皮基部的ＡＣｈＥ阳性神经中,尚含有内脏感觉神经纤维。食管壁的肌间丛和粘膜下丛内散在有多极形和卵园形的ＡＣｈＥ阳性神经元,在食管腹段内数多,而以中小型神经元为主。     

甘肃鼢鼠胃肠道肌间神经丛一氧化氮合酶阳性神经元的分布

用NADPH-黄递酶组织化学法及整装铺片技术,对甘肃鼢鼠(Myospalax cansus)胃肠道肌间神经丛NOS阳性神经元的分布进行研究.结果显示,甘肃鼢鼠胃肠道肌间神经丛NOS阳性神经元分布广泛,形态多样,神经元大小不同,阳性神经节与阳性神经纤维束形成网络;胃肠道不同部位NOS阳性神经元密度有差异,结肠最高,直肠次之.从十二指肠至回肠段,NOS阳性神经元密度整体呈上升趋势;胃与空肠、十二指肠与盲肠间NOS阳性神经元密度无显著差异,其他各段之间差异显著.甘肃鼢鼠胃肠道肌间神经丛NOS阳性神经元分布与其他已研究动物的分布模式基本一致.     

大豆甙元磺酸钠对应激性胃粘膜损伤的影响及其机制探讨

目的：观察大豆甙元磺酸钠对力竭应激性渍疡的影响,探讨其可能的作用途径。方法：采用小鼠力竭性游泳,计数胃部溃疡点数建立应激溃疡模型,腹腔注射不同剂量的大豆甙元磺酸钠及一氧化氮合酶（NOS）抑制剂（L-NAME）并通过NADPH-黄递酶组织化学法检测胃壁NOS阳性神经元的变化。结果：大豆甙元磺酸钠具有保护胃粘膜的作用,且呈剂量效应;L-NAME可防止应激引起的胃粘膜损伤,L-NAME与有效剂量的大豆甙元磺酸钠联合使用后,大豆甙元磺酸钠对胃粘膜的保护作用明显增强;正常及应激小鼠胃壁NOS神经节数目基本不变,大豆甙元磺酸钠对正常小鼠胃壁NOS神经元影响不明显,而对应激小鼠胃壁单位面积及单个神经节内NOS阳性神经元数目均有显著降低作用。结论：应激时NO升高可导致溃疡,大豆甙元磺酸钠能够保护胃粘膜,其作用是通过抑制应激状态下NOS的升高,限制应激状态下NO过度升高,起到保护胃粘膜的作用。     

中华大蟾蜍多种组织内5-羟色胺免疫染色细胞的分布

用过氧化物酶-抗过氧化物酶(PAP)法,对中华大蟾蜍消化道(冬眠期与非冬眠期),脑及其他组织的5-HT分布进行了研究。5-HT免疫染色细胞位于脑干中缝核区和间脑的第Ⅲ脑室腹侧的室管膜细胞区。阳性神经元呈圆形或卵圆形,细胞常有突起与其他阳性细胞突起相连,上述部位中还有一些阳性神经纤维。消化道的免疫染色细胞密度在胃幽门、胃体和胃贲门处最高,食道和十二指肠次之,大肠和小肠最低。非冬眠期蟾蜍消化道内免疫染色细胞密度明显高于冬眠期的(P<0.05)。阳性细胞位于粘膜上皮或腺上皮细胞间,细胞有一个或一个以上呈阳性反应的突起,有的突起伸入肠腔面或腺腔面,有的穿过基膜到达固有层,表明这些细胞兼有内、外分泌的功能。在甲状旁腺的主细胞间,肺呼吸性细支气管上皮和肺泡管上皮细胞间都有5-HT免疫染色细胞,细胞呈立方形、圆形、卵圆形或不规则形,常有几个细胞成簇分布。     

人小肠粘膜内神经元的组织化学与免疫组织化学观察

使用ＮＡＤＨ黄递酶组化法,我们观察到小肠的固有层和粘膜肌层内的神经元和小神经节。粘膜内神经元经ＮＡＤＨ黄递酶组化与ＮＳＥ免疫组化法联合染色,由蓝色转变为黑色;在同一切片内粘膜下丛和肌间神经丛的神经元具有相同的染色性。粘膜内一些ＡＣｈＥ阳性反应神经元,胞体呈校形,两端伸出较长的突起;另一些神经元胞体呈卵圆形或不规则形,可见突起伸入肠膝下部,参与腺周丛。粘膜内神经元的类型和性质有待进一步研究。     

扬子鳄新皮质NOS、AChE阳性神经元的分布

目的 观察扬子鳄新皮质内一氧化氮合酶(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新皮质内NOS和AChE阳性神经元的分布和特征.结果 扬子鳄新皮质内有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,胞体呈圆形、椭圆形、三角形和梭形.结论 扬子鳄新皮质内有NOS和AChE阳性神经元分布.     

扬子鳄梨状皮质NOS、AChE阳性神经元的分布

目的观察扬子鳄梨状皮质内一氧化氮合酶(nitric oxide synthase,NOS)和乙酰胆碱酯酶(acetylcho-linesterase,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梨状皮质内NOS和AChE阳性神经元的分布和特征。结果扬子鳄梨状皮质内有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,胞体呈圆形、椭圆形、三角形和梭形。结论扬子鳄梨状皮质内有NOS和AChE阳性神经元分布。     

神经激肽B受体在小鼠消化道内的定位

采用免疫组织化学ABC染色方法研究了神经激肽B受体（NK3r)在小鼠消化道的分布。MK3r样阳性的神经无胞体及神经纤维主要分布在十二指肠,空肠,回肠及结肠的粘膜下层神经丛和肌间神经丛,NK3r样阳性产物在食管,胃和直肠的神经丛中未见分布;NK3r样阳性产物大部分避限于神经细胞表面,也存在于胞和一些轴突内部,并在胞质中较细胞表面染色浅。。统计结果表明NK3r样免疫阳性神经元占肠神经系统神经元总数的0．5－1％,提示小鼠消化道内NK3r样阳性神经元可能参与消化功能的调节。     

人胎大肠氮能神经元发育的研究

By using histochemical methed of NADPH-diaphorse, the development of the nitrergic neurons in the large intestine of human fetus were studied. The results showed: At the fifth month of gestation, weak positive reaction of nitric oxide synthase (NOS) appeared in part of the round cells of intermuscular ganglia. The round cells differentiated into the nitrergic nerve cells. At the sixth month, the bodies of nitrergic neurons were obviously enlarged, the processes of which were lengthened. The nitrergic nerve fibers were seen in the muscle layer, the submucosa and the base of the intestinal gland. The growth and development of nitrergic neurons reached its peak at the seventh month. The number of intermuscular ganglionic cells was increased. The density of nitrergic nerve fibers was increased in the inner circular muscle layer, and have bead-like structures. At the eighth to tenth month, the staining intensity of nitrergic neurons was increased. The myenteric plexus was densely distributed with nitrergic nerve cell bodies, whereas the submucosa and the inner circular muscle layers contained only a few neurons. The nitrergic nerve fibers were observed in all layer of large intestine, the density of the distribution of nitrergic nerve fibers was by far the highest in the inner circular muscle layer, less in the submucosa and outer longitudinal muscle layer, and only a few were found in the mucous layer. To our knowledge, it is the first time that the development of nitrergic neurons in the large intestine of human fetus was demonstrated.     

Projections of neurochemically specified neurons in the porcine colon

The intramural projections of nerve cells containing serotonin (5-HT), calcitonin gene-related peptide (CGRP), vasoactive intestinal peptide (VIP) and nitric oxide synthase or reduced nicotinamide adenine dinucleotide phosphate diaphorase (NOS/NADPHd) were studied in the ascending colon of 5- to 6-week-old pigs by means of immunocytochemistry and histochemistry in combination with myectomy experiments. In control tissue of untreated animals, positive nerve cells and fibres were common in the myenteric and outer submucous plexus and, except for 5-HT-positive perikarya, immunoreactive cell bodies and fibres were also observed in the inner submucous plexus. VIP- and NOS/NADPHd-positive nerve fibres occurred in the ciruclar muscle layer while VIP was also abundant in nerve fibres of the mucosal layer. 5-HT- and CGRP-positive nerve fibres were virtually absent from the aganglionic nerve networks. In the submucosal layer, numerous paravascular CGRP-immunoreactive (IR) nerve fibres were encountered. Myectomy studies revealed that 5-HT-, CGRP-, VIP- and NOS/NADPHd-positive myenteric neurons all displayed anal projections within the myenteric plexus. In addition, some of the serotonergic myenteric neurons projected anally to the outer submucous plexus, whereas a great number of the VIP-ergic and nitrergic myenteric neurons send their axons towards the circular muscle layer. The possible function of these nerve cells in descending nerve pathways in the porcine colon is discussed in relation to the distribution pattern of their perikarya and processes and some of their morphological characteristics.     

Electronmicroscopical localization of nitric oxide synthase-containing nerve elements in cat pylorus.

Intrinsic nitric oxide synthase (NOS)-containing nerve cells and fibers were studied in the wall of the pylorus of cat at the ultrastructural level using ABC immunocytochemistry. Large numbers of NOS immunoreactive (IR) nerve cell bodies were observed in the myenteric and in the submucous plexuses, and few in the tunica propria mucosa. The NOS IR nerve fibers were most abundant in the inner circular muscle layer and in the tunica mucosa. They were found in very close vicinity to the smooth muscle cells of the inner circular muscular layer as well as to the blood vessels and the epithelial lining. The gap between the NOS IR nerve fibers and the membrane of the target cells was 20 to 250nm. Apparent synaptic contacts were observed between the IR nerve fibers and unlabelled nerve processes and other non IR nerve cell body. It is confirmed that NO might influence smooth muscle cell activity, regulate blood flow and modulate the function of the epithelial cells. Our ultrastructural study suggested that some of the NOS containing neurons belong to the intrinsic interneurons and have a regulatory effect on other intrinsic nerve elements involved in local neuronal reflexes.     

Nitric oxide synthase in the gastrointestinal tract of the estuarine crocodile, Crocodylus porosus

The aim of this study was to investigate the distribution of nitric oxide synthase (NOS)-containing nerve cells in the gastrointestinal tract of a reptile and to compare it with the pattern in other vertebrate classes. In the estuarine crocodile, Crocodylus porosus, NOS-positive nerve cell bodies and fibres were found in all regions of the gut examined. Most myenteric microganglia contained one or several NOS-immunoreactive neurons together with unlabelled neurons. The majority of the neurons were multipolar, ranging from 10 to 25 microns in diameter. Both the circular and the longitudinal muscle layers were innervated by NOS-immunoreactive nerve fibres, which mostly ran parallel to the muscle fibres. In addition, small blood vessels in the submucosa and on the serosal surface of the gut were innervated by NOS-immunoreactive fibres. Double labelling with antisera to NOS and vasoactive intestinal peptide (VIP) revealed three neuronal subpopulations. A small proportion of the NOS-immunoreactive cells also contained immunoreactivity to VIP while a majority of the VIP-immunoreactive cells were NOS immunoreactive. There were more nerve fibres showing VIP immunoreactivity than fibres with NOS immunoreactivity, although most of the latter also contained immunoreactivity to VIP. VIP-immunoreactive fibres often surrounded the NOS-immunoreactive nerve cells. These results suggest that neuronally released nitric oxide is likely to be involved in the control of gastrointestinal motility in the crocodile as in most other vertebrate species.     

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。     

Cholinergic innervation of the human stomach.

A histochemical method for the acetylcholinesterase activity was used to establish the parasympathetic components of the gastric coats in man. The four gastric layers contain a rich cholinergic innervation. In the mucosa the positive nerve fibers are located around the gastric glands and between the muscles of the muscularis mucosae. In the submucosa rich interconnected nerve fibers, rare large nerve trunks, and scarce ganglia cells show a strong cholinergic reaction. The muscular layer contains the highest density of cholinergic nerve fibers, isolated or in large bundles. Auerbach's plexus has a strong acetylcholinesterase activity in the nerve cell bodies. The subserous layer is very rich in cholinergic nerve fibers, rarely isolated, but interconnected. The vessels of each gastric layer exhibit a rich cholinergic innervation in the adventitia and the outside part of media.     

Distribution of nitric oxide synthase and vasoactive intestinal polypeptide immunoreactivity in the sphincter of Oddi and duodenum of the possum

The nitrergic innervation of the sphincter of Oddi (SO) and duodenum in the Australian brush-tailed possum and the possible association of this innervation with the neuropeptide vasoactive intestinal polypeptide (VIP) were investigated by using immunohistochemical localisation of nitric oxide synthase (NOS) and VIP, together with the general neuronal marker, protein gene product 9.5 (PGP9.5). Whole-mount preparations of the duodenum and attached SO without the mucosa, submucosa and circular muscle (n=12) were double- and triple-labelled. The density of myenteric nerve cell bodies of the SO in the more distal region (duodenal end) was significantly higher than that in the more proximal region. In the SO, approximately 50% of all cells were NOS-immunoreactive (IR), with 27% of the NOS-IR cells being VIP-IR. Within the duodenal myenteric plexus, NOS immunoreactivity was present in about 25% of all neurons, with 27% of these NOS-IR neurons also being VIP-IR, a similar proportion to that in the SO. Varicose nerve fibres with NOS and VIP immunoreactivity were present within the myenteric and submucous plexuses of the SO and duodenum, and in the circular and longitudinal muscle layers. The NOS-positive cells within both the SO and duodenum were unipolar, displaying a typical Dogiel type I morphology. The myenteric plexuses of the SO and duodenum were in direct continuity, with many interconnecting nerve trunks, some of which showed NOS and VIP immunoreactivity. Thus, the possum possesses an extensive NOS innervation of the SO and duodenum, with a significantly higher proportion of NOS-IR neurons within the SO, a subset of which contains VIP.     

Nitric oxide synthase immunoreactivity in the enteric nervous system of the developing human digestive tract

We have investigated indirectly the presence of nitric oxide in the enteric nervous system of the digestive tract of human fetuses and newborns by nitric oxide synthase (NOS) immunocytochemistry and nicotinamide adenine dinucleotide phosphate diaphorase (NADPHd) histochemistry. In the stomach, NOS immunoactivity was confined to the myenteric plexus and nerve fibres in the outer smooth musculature; few immunoreactive nerve cell bodies were found in ganglia of the outer submucous plexus. In the pyloric region, a few nitrergic perikarya were seen in the inner submucous plexus and some immunoreactive fibres were found in the muscularis mucosae. In the small intestine, nitrergic neurons clustered just underneath or above the topographical plane formed by the primary nerve strands of the myenteric plexus up to the 26th week of gestation, after which stage, they occurred throughout the ganglia. Many of their processes contributed to the dense fine-meshed tertiary nerve network of the myenteric plexus and the circular smooth muscle layer. NOS-immunoreactive fibres directed to the circular smooth muscle layer originated from a few NOS-containing perikarya located in the outer submucous plexus. In the colon, caecum and rectum, labelled nerve cells and fibres were numerous in the myenteric plexus; they were also found in the outer submucous plexus. The circular muscle layer had a much denser NOS-immunoreactive innervation than the longitudinally oriented taenia. The marked morphological differences observed between nitrergic neurons within the developing human gastrointestinal tract, together with the typical innervation pattern in the ganglionic and aganglionic nerve networks, support the existenc of distinct subpopulations of NOS-containing enterice neurons acting as interneurons or (inhibitory) motor neurons.     

Immunohistochemical analysis of neuron types in the mouse small intestine

The definition of the nerve cell types of the myenteric plexus of the mouse small intestine has become important, as more researchers turn to the use of mice with genetic mutations to analyze roles of specific genes and their products in enteric nervous system function and to investigate animal models of disease. We have used a suite of antibodies to define neurons by their shapes, sizes, and neurochemistry in the myenteric plexus. Anti-Hu antibodies were used to reveal all nerve cells, and the major subpopulations were defined in relation to the Hu-positive neurons. Morphological Type II neurons, revealed by anti-neurofilament and anti-calcitonin gene-related peptide antibodies, represented 26% of neurons. The axons of the Type II neurons projected through the circular muscle and submucosa to the mucosa. The cell bodies were immunoreactive for choline acetyltransferase (ChAT), and their terminals were immunoreactive for vesicular acetylcholine transporter (VAChT). Nitric oxide synthase (NOS) occurred in 29% of nerve cells. Most were also immunoreactive for vasoactive intestinal peptide, but they were not tachykinin (TK)-immunoreactive, and only 10% were ChAT-immunoreactive. Numerous NOS terminals occurred in the circular muscle. We deduced that 90% of NOS neurons were inhibitory motor neurons to the muscle (26% of all neurons) and 10% (3% of all neurons) were interneurons. Calretinin immunoreactivity was found in a high proportion of neurons (52%). Many of these had TK immunoreactivity. Small calretinin neurons were identified as excitatory neurons to the longitudinal muscle (about 20% of neurons, with ChAT/calretinin/± TK chemical coding). Excitatory neurons to the circular muscle (about 10% of neurons) had the same coding. Calretinin immunoreactivity also occurred in a proportion of Type II neurons. Thus, over 90% of neurons in the myenteric plexus of the mouse small intestine can be currently identified by their neurochemistry and shape.