Vascularization of plexus myentericus (Auerbach) in the large intestine of the cat

1. Coincidental preparation of the intramuscular vascular bed and the plexus myentericus (Auerbach) of the cat's large intestine by India-ink method and silverimpregnation allowed to demonstrate independent vascularisation of ganglia and nerve-branches of the plexus Auerbach. 2. Each ganglion is surrounded by a capillary network widely independently existing of the intramuscular capillary bed. The preferred innervated terminal arterioles and especially the sphincteric capillaries opening into the periganglionic capillary network and the numerous arterio-venous short-circuits in its marginal area suggest to conclude a differentiated regulation of blood supply.     

The vascularization of the submucous external plexus (Schabadasch) and the submucous internal plexus (Meissner) in the small intestine of swine and cat

Each ganglion of the plexus Schabadasch is supplied by a specific periganglionic capillary network. Within the plexus Meissner, several ganglia are connected to circulation areas. The communicating branches of the plexus Schabadasch have their own capillary system; as to the plexus Meissner, this is valid for the cat only. The results allow to conclude that the centres of the intramural nervous system of the intestinal wall are equipped with a preferred and self-acting vascularization.     

Fluorescence microscopic study of the architecture and structure of an adrenergic network in the plexus myentericus (Auerbach), plexus submucosus externus (Schabadasch) and plexus submucosus internus (Meissner) of the porcine small intestine

The distribution of adrenergic fibres in the ganglionated plexuses of the porcine small intestine has been made on air-dried stretch preparations using the glyoxylic acid fluorescence method. Adrenergic fluorescent fibres occur in the ganglia and internodal strands of the three fundamental ganglionated plexuses: the myenteric plexus (Auerbach) and the two superimposed meshworks of the plexus submucosus , i.e. the plexus submucosus externus ( Schabadasch ) and the plexus submucosus internus (Meissner). The plexus Auerbach consists of densely glyoxylic acid induced fluorescent (GIF) elongated ganglia with in general a longitudinal axis running parallel to the circular muscle layer and large dense interconnecting fibre tracts with primary, secondary and tertiary subdivisions. In the ganglia, the fibres are varicose, forming large fluorescent 'baskets' which might be related to the occurrence of well defined enteric neurones. The plexus Schabadasch can be distinguished from the plexus Meissner by its size, strongly fluorescent ganglia and broad densely fluorescent internodal strands. The pattern of fluorescing ring-like formations at the margin and out of the nodes, clearly present in the Auerbach and Schabadasch plexuses, completely lack in the plexus Meissner, the latter being narrow-meshed with smaller fluorescent 'baskets', indicating that the corresponding neurones are smaller in size. In the ganglionic nodes of all three plexuses the axons display comparatively more varicosities than in the fibre tracts. Each of the three main ganglionated enteric plexuses are quite different with regard to the pattern of the adrenergic network both in the ganglia and in the strands.     

The innervation of the lymphoid tissue at the ileocolonic transition: an enzyme and immunohistochemical study.

Using enzyme and immunohistochemical methods on whole-mount preparations and cryostat sections, a morphologic and semiquantitative study was performed of the nervous tissue in the appendix and the ileum (areas with and without Peyer's patches) of the rabbit. The plexus submucous externus (Meissner) consists of a network of small ganglia, vaguely associated with the vascular submucosal plexus. From the nerve cell bodies, cell processes occasionally penetrate the lymphoid follicles at the junction between the mucosa and the submucosa while other extensions form a dense plexus in the lamina propria of the mucosa. No nerve fibers are present in the dome of the follicles. The plexus submucous internus (Henle), consisting of large cell bodies and large processes, closely follows the blood vessels. The numeration of the nerve fibers of the submucosal plexus endorses the histological finding that the appendix is a richly innervated lymphoid organ. In addition, the plexus myentericus (Auerbach) of the appendix is a network of small meshes, while in the ileum, in the area of Peyer's patches, the same plexus is composed of a network with large meshes. These differences point to a higher density of innervation in the appendix. Yet a specialized anatomic distribution of the innervation of lymphoepithelial structures cannot be demonstrated.     

The perineural epithelium of sympathetic nerves and ganglia and its relation to the pia arachnoid of the central nervous system and perineural epithelium of the peripheral nervous system

Summary A multiple layered flat epithelial cell layer covering the sympathetic ganglion chain and its derivatives (e.g. the splanchnic nerves) has been described. This layer is continuous around the grey and white rami communicans and is in turn continuous with the perineural epithelium of peripheral nerves. A capillary plexus and mast cells in this layer have also been demonstrated. This epithelium is shown on the surface of the blood vessel which enters the sympathetic trunk and resembles the leptomeningeal covering of the blood vessels of the central nervous system. The epi- and perineural. and epi- and periganglionic connective tissue layers of the sympathetic system are extremely delicate and minimal in quantity when compared to the epi- and perineurium of peripheral nerves. This paper thus completes the evidence that the whole of the peripheral nervous system and its ganglia (voluntary and autonomic) is isolated from the environment in which it lies and is maintained in an environment similar to or identical with that of the central nervous system.Supported by grant B-1914 of the National Institute of Neurological Diseases and Blindness and by funds from Anatomy Training Grant 5T1-GM-305, National Institutes of Health, Division of General Medical Sciences. Acknowledgement. We wish to thank Dr. Robert Mathewson, Resident Director, Lerner Marine Biological Laboratories of the American Museum of Natural History, Bimini, Bahamas, for providing facilities for collection of whale material.     

Vascularization of the pituitary of the Australian lungfish and Neoceratodus forsteri

The vascularization of the brain and the pituitary region of the Australian lungfish, Neoceratodus forsteri is described from serial section reconstruction. The distal lobe has no direct arterial blood supply and receives blood solely from a pituitary portal system basically similar to that of other sarcopterygians. The primary capillary plexus of the median eminence receives its arterial blood from the infundibular arteries, which on their way distribute some small branches to the prechiasmatic region. The primary plexus also receives capillaries from the adjacent pial hypothalamic plexus. The primary capillary plexus of the median eminence comprises a rostral 'uncovered' and caudal 'covered' part which are not sharply delineated. Distinct portal vessels connect the 'uncovered' rostral part of the primary plexus with the secondary capillary plexus supplying the rostral subdivision of the pars distalis. The 'covered' caudal part of the primary plexus merges into the proximal subdivision of the pars distalis, apparently without formation of distinct portal vessels. The primary plexus has some connections with the plexus intermedius via a hypophysial stem capillary plexus. The plexus intermedius has a substantial arterial supply and gives off capillaries to the parenchyma of the pars intermedia. The adenohypophysis is drained into an unpaired hypophysial vein. The significance of the vascular pathways is discussed from comparative, functional, and evolutionary viewpoints.     

The innervation of the umbilical cord of the rat. A histochemical study

The umbilical cords of 21 days old rat foetuses were investigated using histochemical methods for acetylcholinesterase and catecholamines. An AChE positive nerve plexus is situated only around the vitelline vessels. At regular intervals the bundles of this plexus exhibit small ganglia. These ganglia are made up of nerve cells, which are AChE positive and show formaldehyde induced fluorescence, thus indicating an adrenergic nature of these cells. No innervation could be found in the allantoic part of the umbilical cord.     

The neuronal organization of the plexus myentericus (Auerbach) in the small intestine of the pig. II. Typ II-neurone (author's transl)

The population of type II-neurons in the Auerbach's plexus of the pig's small intestine consisting of bipolar, pseudo-unipolar, and multipolar elements could be characterized a.o. as follows: 1. The type II-cells are on principle concentrated in aggregates in the periphery and outside the ganglia. 2. The processes of type II-cells all leaving the ganglia or aggregates of origin, are of the same axonal structure. Considering further characteristics type II-cells are defined therefore as adendritic, multiaxonal neurons. 3. Contrary to the axons of the other multidendritic, uniaxonal types of neurons (type I, III, IV, V) those of type II-cells forming circular routes (besides the vertical ones) in the secondary branches of Auerbach's plexus can be followed up to the intramuscular plexus. That's why the type II-cells finally can be considered as adendritic, multiaxonal, and efferent neurons.     

Pivotal role of the interstitial cells of Cajal in the nitric oxide signaling pathway of rat small intestine. Morphological evidence

The nitric oxide (NO) signaling pathway is a major nonadrenergic-noncholinergic transmitter mechanism in the enteric nervous system. Our aim was to localize the enzymes in question, i.e., neuronal nitric oxide synthase (nNOS), soluble guanylate cyclase (sGC), and cGMP-dependent kinase type I (cGK-I) in rat small intestine by indirect immunofluorescence. nNOS staining was found in neurons of the myenteric plexus and in varicose nerve fibers mainly in the circular muscle layer. The cells positive for neurokinin-1 (NK-1) receptor and c-kit (interstitial cells of Cajal, ICC) in the deep muscular plexus (DMP) did not show nNOS reactivity, but nNOS-positive nerve fibers were directly adjacent to them. sGC was found in flattened cells surrounding myenteric ganglia (periganglionic cells, PGC), in ICC of the DMP, faintly in smooth muscle cells (SMC), and in cells perivascularly scattered throughout the circular muscle layer. cGK-I immunoreactivity was found abundantly in PGC (which presumably are ICC), in ICC of DMP, in SMC of the innermost circular and longitudinal muscle layers, but less intensively in the outer circular layer. Weak cGK-I staining occurred in nerve cells within the myenteric and submucosal plexus. Conclusively the key enzymes of the NO signaling pathway are differentially distributed: Occurrence of nNOS exclusively in neurons and the presence of sGC and cGK-I predominantly in ICC suggest a sequence of neuronal NO release, activation of ICC, and consecutive smooth muscle relaxation. ICC of the DMP seem to be the primary targets for neurally released NO.     

Capillary plexus development in the day five to day six chick chorioallantoic membrane is inhibited by cytochalasin D and suramin

The chick chorioallantoic membrane (CAM) is a valuable model for evaluating angiogenesis and vasculogenesis. Our purpose was to characterize the formation of the CAM vasculature, in particular the capillary plexus, between days five and six after fertilization and to examine the mode of action of cytochalasin D and suramin on vascular development during this interval. The CAM increased 20-fold in size between days five and six, during which time the capillary plexus forms by both migration of mesodermal blood vessels toward the ectoderm and by the formation of new vessels from angioblasts near the ectoderm. Between days five and six, the CAM becomes thinner, and the density of the mesodermal cells decreases. To determine the mode of action of anti-angiogenic drugs on the day five to day six CAM, various concentrations of cytochalasin D or suramin were added directly to day five CAMs, and their effects were evaluated on day six. Both drugs significantly inhibited CAM growth, altered branching patterns of the major vessels, decreased area of the major vessels, and inhibited the formation of the capillary plexus by inhibiting both vasculogenesis and the migration of mesodermal blood vessels to the ectoderm. Cytochalasin D also inhibited compartmentalization of the plexus. Cytochalasin D and suramin were inhibitory at similar doses. This study provides new information on early CAM development, establishes the mode of action and dose dependency of cytochalasin D and suramin on day five to day six CAMs, and demonstrates that the day five to day six CAM provides a useful assay to examine the effect of anti-angiogenic drugs on blood vessel development, including capillary plexus formation.     

Sensory endings in the intramural ganglia of the stomach. Light optical and electron microscopic study

Puppies and young dogs at the age of 3 days up to 2 months were used in the investigation. In total stomach preparations neuronal structures were stained with methylene blue after A. S. Dogel. Routine electron microscopic studies were carried out. Within the structure of intramuscular vegetative plexus of the stomach a sensory plexus was demonstrated, its terminals forming receptive bushy structures in all the tissues. Especially numerous the sensory endings were in neuronal cords and ganglia. The sensory endings innervated all the elements in ganglia. Ultrastructure of receptor terminals situated in the intramural ganglia of the stomach corresponded to that of terminals in tissue mechanoreceptors described for skin, auriculum, carotid sinus and trachea. Peculiar multilayer lamillar structures formed by cytoplasmic axonal processes of lemmocytes around lance-shaped, arranged in rosary fashion receptor varicosities were described. Contact of receptor terminals with the neuronal cell body was demonstrated. Functional nature of the tissue receptors described was discussed.     

Cholinergic innervation of the gastric wall of the cat.

The inbuilt intrinsic cholinergic nervous apparatus of the gastric wall of the cat was studied by using two thiocholine methods for mapping the acetylcholinesterase-positive nerves and nerve cells. A rich distribution of acetylcholinesterase-positive nerves was observed in all layers of the gastric wall, except the superficial half of the lamina propria (with the epithelium), which was completely devoid of acetylcholinesterase activity, and the submucosa, in which a scarce distribution of large nerve fascicles and nerve trunks was observed. Acetylcholinesterase-positive ganglia were observed both in the subserous layer and in the myenteric plexus of Auerbach, whereas none were recognized in the submucous plexus of Meissner. This obviously fits well to the results of some electrophysiological experiments which indicate that the submucous plexus of Meissner includes an important intramural pathway from the extrinsic vagus nerves to the antrum region; so the submucous plexus of Meissner seems to be mainly involved in direct rapid conduction of nerve impulses without integrative activities, like a cable. Certain clear differences exist in the pattern of organization of the cholinergic intrinsic nervous apparatus within the different layers of the gastric wall in the fundic and pyloric regions. These differences seem to correspond quite logically to the different types of motor, secretory and neurohumoral activities of these main regions of the stomach. The activity of the non-specific cholinesterases was localized both in the neural elements and the smooth muscle, as well as in some epithelial cells.     

Anterior and posterior groups of portal vessels in the avian pituitary: incidence in forty nine species.

The hypophyseal portal vessels were studied in forty nine species of birds. The primary capillary plexus in the median eminence is single or divided into an anterior and a posterior plexus. Irrespective of whether the primary capillary plexus is single or divided, distinct, non-interconnected anterior and posterior groups of portal vessels are present in all the species investigated. The anterior group of portal vessels originates in the anterior region of the median eminence and breaks up into capillaries in the cephalic lobe of the pars distalis; the posterior group of portal vessels originates in the posterior region of the median eminence and breaks up into capillaries in the caudal lobe of the pars distalis. This type of regional distribution of portal vessels appears to be of general occurrence in the avian pituitary. The median eminence in the species investigated shows an AF-positive anterior region and an AF-negative posterior region. The pars distalis is differentiated into histologically distinct cephalic and caudal lobes. The arrangement of the portal vessels into anterior and posterior groups provides morphological basis for the view that the functions of the cephalic lobe may be controlled by the anterior median eminence, whereas those of the caudal lobe may be controlled by the posterior median eminence. However, experimental data available to date do not suggest a physiological significance to the widespread incidence of the regional distribution of portal vessels in the avian pituitary.     

Electron microscopy of the mucosal plexus of the rat colon.

The ultrastructure of neurons, glial cells and axons of the mucosal plexus of the rat colon descendens was studied. Serial semithin sections and a re-embedding technique were used in order to localize the ganglia. The ganglia are free of blood vessels and connective tissue. The ratio of neurons to glial cells is approximately 1. Ganglia and nerve strands are enclosed by a basement membrane, without a well-defined perineural connective tissue. The neurons show a structure similar to other enteric plexus. Synaptic contacts were observed frequently in the neuropil, where nerve endings and varicosities show a diverse outfit in vesicles. The glial cells, which contain immunocytochemically detectable glial fibrillary protein, possess the same ultrastructural attributes in the intra- and extraganglionic localizations. In the nerves, axonic profiles and varicosities appear in close relation with glial cells or their processes. The distance between the nerves and their target cells, i.e. the enterocytes, is 0.5 microns or more with interposed basement membranes and fibroblasts.     

家鸽小肠绒毛微血管铸型的扫描电镜观察

用扫描电镜观察了ＡＢＳ丁酮溶液灌注的家鸽小肠绒告发同血管构筑情况。家鸽小肠绒毛血管丛由输入沁动脉、毛细血管网和输出小静脉组成,小肠绒毛血管丰富,并相到吻合成单层密集网;办入小动脉既可从肠腺周围血管丛发出,也可直接由粘膜下去一发出,绒毛下部血管表现为微直血管形态,可能部分具有门静脉性质。     

Fine structure of the vessels of the hypophysial portal system of the White-crowned Sparrow,Zonotrichia leucophrys gambelii

Summary The angioarchitecture of the hypophysial portal system of the White-crowned Sparrow, Zonotrichia leucophrys gambelii, was investigated by electron microscopy in conjunction with light microscopy of serial thick sections.The small arteries or arterioles supplying the primary capillary plexus of the median eminence have the typical form of arterioles.The vessels of the primary capillary plexus, on the surface of the median eminence, with their many fenestrations and pinocytotic vesicles, are typical of the form of capillary usually found in other endocrine organs.The portal vessels in the pars tuberalis have wide perivascular spaces between the basement membrane of the endothelium and that of parenchymal lobules of the pars tuberalis. These perivascular spaces are occupied usually by the perivascular cells, but sometimes contain erythrocytes.The endothelial cells of the portal vessels often protrude into vascular lumen giving the appearance of valve-like structures. These may have a role in the regulation of blood flow.The endothelial cells of the portal vessels are invested by a definitive basement membrane and by the cytoplasm of pericytes which are oriented spirally to the longitudinal axes of the vessels. The pericytes may have a function in the mechanical support of the vascular wall and a contractile function that might regulate the flow rate of blood.The investigation reported herein was supported by a scientific research grant (No. 291049) from the Ministry of Education of Japan to Prof. Mikami; by a grant from the Deutsche Forschungsgemeinschaft to Prof. Oksche; by a grant (5 ROI-NB 06817) from the National Institutes of Health to Prof. Farner, and by a research grant (5 ROI-HE 07240 NEUA) from the National Institutes of Health to Prof. Vitums.     

Two submucosal nerve plexus in human intestines

We examined the architecture of human submucosal nerve networks of gut segments derived from 12 individuals (each six from small and large intestines). Twelve undivided submucosal wholemounts were prepared and immunohistochemically stained for peripherin (nerve elements) and for α-smooth muscle actin (remnants of attached muscle bundles). We found two ganglionic nerve networks. The plexus submucosus externus was generally monolayered and located under the outermost surface of the submucosal wholemounts. Its nerve fibre strands frequently joined each other in acute or obtuse angles, the meshes of the network were relatively wide and frequently polyangular shaped. The plexus submucosus internus was generally multi-(mostly two- or three-)layered and occupied at least the inner half of the thickness of the wholemount, sometimes extending abluminally beyond the great submucosal vessels. Its meshes were irregular. The shapes of ganglia of the two plexus were generally different, those of the internal plexus were frequently grape-like whereas the neurons of external ganglia were mostly embedded in the contoures of the joining nerve fibres. Both plexus were intensely connected via coiled interconnecting strands, either with or without intercalated ganglia. For use of eponyms for two different submucosal plexus, the names of Meissner (inner) and Schabadasch (outer) are historically justified.     

The extrinsic blood vessels of the ovary of the sheep.

The extrinsic ovarian blood vessels were studied in 134 ewes. In view of recent evidence that uterine luteolysis may involve venoarterial transfer of prostaglandin F2alpha in the ovarian pedicle, particular attention was paid to the interrelationships between veins and arteries. The ovarian artery and utero-ovarian vein are large vessels of conventional structure and lie in close apposition. Their walls are slightly thinner on their apposing sides. The ovarian branches of the ovarian artery are very tortuous, and closely intertwined with the plexiform ovarian branches of the utero-ovarian vein. An extensive plexus of small veins surrounds the ovarian artery and its ovarian branches. Within this plexus are many thin-walled, dilated regions, interspersed with narrow, thick-walled segments. Valves are inconstantly present at sites of entry of branches of the plexus into the major veins. Small numbers of arterio-venous anastomoses are present in the distal part of the ovarian pedicle. Unless blood can flow in a veno-arterial direction through arterio-venous anastomoses or capillary beds, the structural barrier between uterine venous and ovarian arterial blood is substantial.     

Microvasculature of the feline stomach

The feline gastric microvasculature was studied by corrosion of the injected vascular bed, which allowed evaluation of the vascular pattern of the different tunics. The serosal pattern consisted of numerous interconnected capillary vessels, forming a delicate network. Submucosal arteries supplied the muscular tunic through numerous anastomosing vessels that followed the direction of the smooth muscle fibers. The entire mucosal tunic was supplied by arterioles derived from the submucosal plexus; these gave rise to capillaries that surrounded the gastric glands and terminated in a diffuse, anastomosing subepithelial capillary network. Venules coursed through the mucosa in a perpendicular manner, forming submucosal veins.