Ultrastructural findings in the wound healing of the colonic mucosa of rabbits

The wound healing of the rabbit colonic mucosa after experimental excision was observed with the electron microscope. Between 5 and 7 days, considerable numbers of undifferentiated mesenchymal cells (group I), differentiating muscle cells (group II) and histiocyte-like cells (group III) appear in the regions where the muscularis mucosae is re-establishing. Our electron micrographs indicate that group I cells are stem cells which differentiate to group II cells involved in muscle regeneration or to group III cells involved in phagocytosis. The mitotic proliferation of pre-existing smooth-muscle cells at the ulcer margin does not seem to be the major reason for the re-establishment of the muscular layer. Multinucleated cells occurring in this healing mucosa are considered to be formed by successive fusions between the group III cells and to play a role in enclosure of cell debris such as fragments of elastin.     

Differentiation of mononuclear blood cells into macrophages, fibroblasts and endothelial cells in thrombus organization

The organization of thrombi and emboli may be performed exclusively by mononuclear blood cells which represent precursors of various mesenchymal cell types. Between the 10th and 20th day after the onset of blood clotting, mononuclear cells within the fibrinous matrix differentiate into (1) macrophages responsible for hematoclasia and hematophagocytosis, (2) endothelial cells lining autolytic slits in the fibrinous matrix and forming new capillaries, and (3) fibroblasts and even smooth muscle cells building up a young mesenchymal connective tissue.     

Morphological study by scanning electron microscopy of the lymphatic vessels of the guinea pig

The purpose of this study was to describe the morphology of the whole lymphatic way: from capillaries to thoracic duct including cisterna chili using scanning electron microscopy and Evan's technique. We observed the lymph vascular wall that is: the endothelial surface, the muscular layer and the adventitial one. All these vessels were covered by an endothelial surface, with raised nuclei and long cell axes oriented parallel to the direction of flow. The borders between adjacent endothelial cell were often seen and open junctions were noted in lymphatic capillaries. The technique we used, permitted the removal of connective tissue by HC1 hydrolysis, so that smooth muscle cells could be examined. The latter showed a great variety of aspects and a very irregular course. The adventitial layer was thin in capillaries and became complex in thoracic duct where collagen fibers and connective elements were seen.     

Regeneration of gastric mucosa during ulcer healing is triggered by growth factors and signal transduction pathways.

An ulcer is a deep necrotic lesion penetrating through the entire thickness of the gastrointestinal mucosa and muscularis mucosae. Ulcer healing is a complex and tightly regulated process of filling the mucosal defect with proliferating and migrating epithelial and connective tissue cells. This process includes the re-establishment of the continuous surface epithelial layer, glandular epithelial structures, microvessels and connective tissue within the scar. Epithelial cells in the mucosa of the ulcer margin proliferate and migrate onto the granulation tissue to re-epithelialize the ulcer. Growth factors, such as epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), trefoil peptides (TP), platelet derived growth factor (PDGF) and other cytokines produced locally by regenerating cells, control re-epithelialization and the reconstruction of glandular structures. These growth factors, most notably EGF, trigger epithelial cell proliferation via signal transduction pathways involving EGF-R- MAP (Erk1/Erk2) kinases. Granulation tissue, which develops at the ulcer base, consists of fibroblasts, macrophages and proliferating endothelial cells, which form microvessels under the control of angiogenic growth factors. These growth factors [bFGF, vascular endothelial growth factor (VEGF) and angiopoietins] promote angiogenesis--capillary vessel formation--thereby allowing for the reconstruction of microvasculature in the mucosal scar, which is essential for delivery of oxygen and nutrients to the healing site. The primary trigger to activate expression of angiogenic growth factors and their receptors appears to be hypoxia. During ulcer healing expression of growth factor genes is tightly regulated in a temporally and spatially ordered manner.     

Innervation of the small intestinal mucosa of laboratory animals. II. Ultrastructure of neuro-cellular connections

In addition to our light microscopic contribution (Stach, Hung 1978) giving an insight into the density, architecture, histochemical variety and relations between plexus mucosus and Lieberkühn's glands the herewith presented electron microscopic results reveal mainly neuro-cellular relations from the lamina propria. This means that the plexus mucosus has mainly the function to innervate blood vessels and lymphatics as well as smooth muscle cells and connective tissue cells (mast cells, histiocytes, plasma cells) of the small intestine mucosa.     

Localisation of lymphatic vessels and vascular endothelial growth factors-C and -D in human and mouse skeletal muscle with immunohistochemistry

The present study was aimed to localise lymphatic vessels and their growth factors in human and mouse skeletal muscle with immunohistochemistry and specific antibodies (VEGFR-3, LYVE-1, VEGF-C and VEGF-D). The largest lymphatic vessels were found in perimysial connective tissue next to the arteries and veins, as has been shown earlier with electron microscopy. As a new finding, we also found small LYVE-1 positive vessels in the capillary bed between muscle fibres. These vessels were located next to CD31 positive blood capillaries and were of the same size, but fewer in number. In addition, we described the localisation of the two main lymphangiogenic growth factor proteins, vascular endothelial growth factor-C and -D. Both proteins were expressed in skeletal muscle at mRNA and protein levels. VEGF-D was located under the sarcolemma in some of the muscle fibres, in the endothelia of larger blood vessels and in fibroblasts. VEGF-C protein was localised to the nerves and muscle spindles, to fibroblasts and surrounding connective tissue, but was not found in muscle fibres or endothelial cells. Our results are the first to suggest the presence of lymphatic capillaries throughout the skeletal muscle, and to present the localisation of VEGF-C and -D in the muscles. Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at .     

丹顶鹤胆囊的显微观察

应用光镜及透射电镜观察一例成体雄性丹顶鹤胆囊。结果表明,丹顶鹤胆囊粘粘膜、肌层和外膜三部分组成。粘膜上皮高柱状、游离端有密集排列的微绒毛,胞质面端有许多粘液颗粒,说明上皮细胞具有吸收功能并可分泌粘液。     

Studies on the microvascularization of the digestive tract by scanning electron microscopy of vascular corrosion casts. 1. Large intestine in rats and guinea pigs.

The colonic microvascularization of 10 adult Sprague-Dawley rats and guinea pigs (Cavia porcellus was studied by scanning electron microscopy of microvascular corrosion casts. The tunica muscularis is supplied by branches of the submucosal arteriolar plexus, according to the arrangement of muscle layers, longitudinally and transversally arranged capillaries are distinguished. The mucosal capillaries show a honeycomb pattern and mimic the openings of the mucosal glands. Parallel to the luminal aspect of the large intestine, the mucosal capillary loops often arise from the submucosal arterioles at the most abluminal aspect of the mucosa; however, some arterioles end just subjacent to these capillaries. The submucosal veins are located just subjacent to the capillaries of the lamina propria. The rat and guinea pig colonic vascular architecture revealed no differences, neither did the capillary density in different parts of the large intestine.     

Immunolocalization of ecto-5'-nucleotidase in the kidney by a monoclonal antibody

A monoclonal antibody IgG, has been raised against ecto-5'-nucleotidase purified from rat kidney homogenate. The specificity of the antibody was verified by immunoprecipitation. The distribution of the corresponding antigen in the rat kidney was studied by immunocytochemistry (FITC and PAP technique) in 1 micron thick cryostat sections. The antibody reacted with the brush border of proximal tubules, the apical cell membrane and the apical cytoplasm of intercalated cells in connecting tubules and collecting ducts and with interstitial cells of the cortex. Among the interstitial cells exclusively stellate shaped fibroblasts were reactive whereas rounded interstitial cells (type II interstitial cells) as well as pericytes and endothelial cells of peritubular capillaries were unreactive. Compared to the staining intensity of the fibroblasts in the cortical labyrinth the reactivity of the fibroblasts in the medullary rays of the cortex was weak or absent. Interstitial cells of the entire medulla were unreactive. Concerning the fibroblasts in the periarterial connective tissue, those surrounding the larger arteries (arcuate arteries, cortical radial arteries) were negative, those alongside afferent and efferent arterioles were positive. Endothelia of lymphatic capillaries travelling within the periarterial connective tissue were also positive. All components of the juxtaglomerular apparatus were negative. The findings are consistent with an interstitial production of adenosine, available extracellularly and thus being able to reach the major target sites of adenosine, the smooth muscles of glomerular arterioles, including the granular cells at the glomerular vascular pole.     

Factors influencing otolith increment formation in Japanese eel,Anguilla japonica T. & S., elvers

The histology of the stomach of Tilapia nilotica (Linnaeus) collected from the R. Nile (Ismailia fork in Egypt) was examined using light microscopy and scanning electron microscopy. The study revealed that the gastric wall is composed of several tunicae: mucosa, submucosa, muscularis and serosa. The tunica mucosa is thrown up into a number of high longitudinal folds projecting into a lumen which is stellate in cross-section when empty. The mucosal surface has a mosaic appearance due to the hexagonal borders of the surface epithelial cells. The latter cells are characterized by the presence of a juxtanuclear vacuole and a PAS-positive brush border made of microvilli. Gastric pits (foveolae) are present as invaginations of the mucosal surface. The foveolar epithelium secretes neutral and acid mucins. Simple, straight, tubular unbranched gastric glands occupy most of the depth of the mucosa, and are lined with a single type of cell which has eosinophilic granules. Gut-associated lymphoid tissue (mainly lymphocytes, macrophages and eosinophilic granulocytes) is concentrated on the sides of the lamina muscularis mucosa and especially in the cores of the mucosal folds. The muscular coat consists of two or three layers entirely made up of smooth muscle cells.     

Distribution and fine structure of the lymphatic system in the human testis

Summary The distribution of lymph vessels in the human testis was investigated using ink injection methods, and light and electron microscopy. Lymph capillaries occur in the septula testis but are absent in the intertubular tissue. They consist of endothelial cells provided with an incomplete basal lamina and anchoring filaments of the adjacent connective tissue. Frequently, the endothelial cells are separated by gaps measuring up to 2m. The lymph capillaries of the septula testis are connected to lymph vessels in the rete testis and tunica albuginea. These vessels have occasional smooth muscle cells and valves. At the posterior margin of the testis, the network of lymph vessels merges into collecting ducts, which together with vessels derived from the rete testis are drained by the lymphatic system in the spermatic cord.Dedicated to Prof. Henriette Oboussier, Hamburg, on the occasion of her 65th birthday     

Fibroblast spreading induced by connective tissue stretch involves intracellular redistribution of α- and β-actin

Mechanical stretching of connective tissue occurs with normal movement and postural changes, as well as treatments including physical therapy, massage and acupuncture. Connective tissue fibroblasts were recently shown to respond actively to short-term mechanical stretch (minutes to hours) with reversible cytoskeletal remodeling, characterized by extensive cell spreading and lamellipodia formation. In this study, we have examined the effect of tissue stretch on the distribution of α- and β-actin in subcutaneous tissue fibroblasts ex vivo. Normal fibroblasts uniformly exhibited α-smooth muscle actin (α-SMA) immunoreactivity. Unlike cultured fibroblasts and smooth muscle cells, α-SMA in these fibroblasts was not in F-actin form (indicated by lack of phalloidin co-localization) nor was it organized into distinct stress fibers. The lack of stress fibers and fibronexus was confirmed by electron microscopy, indicating that these cells were not myofibroblasts. In unstretched tissue, the pattern of α-actin was diffuse and granular. With tissue stretch (30 min), α-actin formed a star-shaped pattern centered on the nucleus, while β-actin extended throughout the cytoplasm including lamellipodia and cell cortex. This dual response pattern of α- and β-actin may be an important component of cellular mechanotransduction mechanisms relevant to physiologic and therapeutic mechanical forces applied to connective tissue.     

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.     

Immunostaining of a heterodimeric dermatan sulphate proteoglycan is correlated with smooth muscles and some basement membranes

A heterodimeric 760-kDa dermatan sulphate proteoglycan tentatively named PG-760 was characterized as a product of keratinocytes, endothelial cells, and fibroblasts. The two core proteins of 460 kDa and 300 kDa are linked by disulphide bridges, and both carry one or only very few dermatan sulphate chains. Different antisera against PG-760 were used in the present study to investigate the distribution in selected murine tissues by light and electron microscopy. PG-760 immunostaining was observed in cornea (epithelium including basement membrane, stroma, and Descemet's membrane), skin, mucosa of the small intestine, Engelbreth-Holm-swarm (EHS)-tumour (matrix and cells), and the smooth muscle layers of uterus, small intestine, and blood vessels. No staining was observed in capillaries, striated muscles, and liver parenchyma including the central vein. The expression of PG-760 in EHS-tumour was also demonstrated after extraction with 4M guanidine and partial purification by diethylaminoethyl (DEAE)-chromatography. We conclude that this novel proteoglycan exhibits a unique tissue distribution being a constituent of some but not all basement membranes, of some other extracellular matrices, and additionally, of all investigated smooth muscle layers.     

An analysis of the interactions between sympathetic nerve fibers and smooth muscle cells in tissue culture

The interactions between sympathetic nerve fibers and smooth muscle cells and fibroblasts from the newborn guinea pig vas deferens were studied in tissue culture with phase contrast microscopy, time-lapse microcinematography, catecholamine fluorescence histochemistry and scanning and transmission electron microscopy. The amount of sympathetic nerve fiber growth, its catecholamine fluorescence reaction and the size of the nerve cell bodies and their nuclei all increased in the presence of vas deferens tissue. Specific growth of nerve fibers to large clumps of vas deferens tissue was seen from distances of up to 2 mm. In contrast, no specific growth from a distance occurred to single cells or small groups of cells. However, random contact with a muscle cell often led to close, extensive, and long-lasting associations. Contact with fibroblasts was always transitory.The rate of sympathetic nerve fiber growth over individual muscle cells was faster than over fibroblasts, which, in turn, was faster than over the collagen-coated surface of the coverslip. Palpation of a muscle cell by a nerve fiber growth cone increased the rate of spontaneous contraction of the muscle cell, the extent of the increase being dependent on the number of nerve fibers involved. Multiple innervation of a smooth muscle cell occurred if nerve fibers reached the cell at about the same time, but not if there was a close association already established. These results are discussed in relation to possible interactions of sympathetic nerve fibers with smooth muscle cells in vivo.     

Fine structure of the mammalian renal capsule: The atypical smooth muscle cell and its functional meaning

Summary The present electron microscopic study on the fine structure of the renal capsule of some mammals (mouse, rat, mole, guinea pig and rabbit) shows that, although there are some variations in the structure, the general morphology is the same.The renal capsule of these animals consists of two layers, a connective tissue layer and an atypical smooth muscle cell layer, and is bound to the renal parenchyma by a thin peritubular loose connective tissue. The atypical smooth muscle cell is characterized by the existence of fine cytoplasmic filaments usually arranged along the long axis of the cell, and the cells also show a complicated interlocking among adjacent cells. The atypical smooth muscle cells gradually undergo a transition to fibroblasts of the upper connective tissue layer, losing their similarities to smooth muscle cells.When intrarenal pressure is elevated and the renal capsule is distended, the intercellular space among interdigitating or overlapping atypical smooth muscle cells is extensively dilated.Tracers such as horseradish peroxidase and ferritin injected intravenously or intraperitoneally can transverse the renal capsule.From the present study, it is concluded that the renal capsule of mammals possesses common structures, and contains atypical smooth muscle cells. These morphological characteristics suggest that the renal capsule could play a certain role related to the renal function.The author wishes to acknowledge the helpful advices of Prof. T. Yamamoto     

Scanning electron microscopy of the muscle coat of the guinea-pig small intestine

Summary We have studied the layers of the muscular coat of the guinea-pig small intestine after enzymatic and chemical removal of extracellular connective tissue. The cells of the longitudinal muscle layer are wider, have rougher surfaces, more finger-like processes and more complex terminations, but fewer intercellular junctions than cells in the circular muscle layer. A special layer of wide, flat cells with a dense innervation exists at the inner margin of the circular muscle layer, facing the submucosa. The ganglia of the myenteric and submucosal plexuses are covered by a smooth basal lamina, a delicate feltwork of collagen fibrils, and innumerable connective tissue cells. The neuronal and glial cell processes at the surface of ganglia form an interlocking mosaic, which is loosely packed in newborn and young animals, but becomes tightly packed in adults. The arrangement of glial cells becomes progressively looser along finer nerve bundles. Single varicose nerve fibres are rarely exposed, but multiaxonal bundles are common. Fibroblast-like cells of characteristic shape and orientation are found in the serosa; around nerve ganglia; in the intermuscular connective tissue layer and in the circular muscle, where they bridge nerve bundles and muscle cells; at the submucosal face of the special, flattened inner circular muscle layer; and in the submucosa. Some of these fibroblast like cells correspond to interstitial cells of Cajal. Other structures readily visualized by scanning electron microscopy are blood and lymphatic vessels and their periendothelial cells. The relationship of cellular elements to connective tissue was studied with three different preparative procedures: (1) freeze-cracked specimens of intact, undigested intestine; (2) stretch preparations of longitudinal muscle with adhering myenteric plexus; (3) sheets of submucosal collagen bundles from which all cellular elements had been removed by prolonged detergent extraction.     

The cytoarchitecture of the wall and the innervation pattern of the microvessels in the rat mammary gland: a scanning electron microscopic observation

This report describes the morphology of the smooth muscle cells, pericytes, and the perivascular autonomic nerve plexus of blood vessels in the rat mammary gland as visualized by scanning electron microscopy after removal of connective-tissue components. From the differences in cellular morphology, eight vascular segments were identified: 1) terminal arterioles (10-30 microns in outer diameter), with a compact layer of spindle-shaped and circularly oriented smooth muscle cells; 2) precapillary arterioles (6-12 microns), with a less compact layer of branched smooth muscle cells having circular processes; 3) arterial capillaries (4-7 microns), with " spidery " pericytes having mostly circularly oriented processes; 4) true capillaries (3-5 microns), with widely scattered pericytes having longitudinal and several circular processes; 5) venous capillaries (5-8 microns), with spidery pericytes having ramifying processes; 6) postcapillary venules (10-40 microns), with clustered spidery pericytes; 7) collecting venules (30-60 microns), with a discontinuous layer of circularly oriented and elongated stellate or branched spindle-shaped cells which may represent primitive smooth muscle cells; and 8) muscular venules (over 60 microns), with a discontinuous layer of ribbon-like smooth muscle cells having a series of small lateral projections. No focal precapillary sphincters were found. The nerve plexus appears to innervate terminal arterioles densely and precapillary arterioles less densely. Fine nerve fibers are only occasionally associated with arterial capillaries. Venous microvessels in the rat mammary gland seemingly lack innervation.     

Three-dimensional architecture of the human myosalpinx isthmus

Summary The three-dimensional architecture of the human isthmic myosalpinx is directly visualized by means of scanning electron microscopy after removal of interstitial connective tissue through NaOH maceration and ultrasound microdissection. These investigations show that the myosalpinx is composed of irregularly running bundles of smooth muscle cells, changing their orientation within the myosalpinx and displaying longitudinal, oblique and circular directions. The muscular bundles anastomose and intermingle with other bundles running at different levels in the oviduct wall, and actually give rise to a wide and complex muscular network in which no distinct layers are readily discernible. These morphological data are consistent with the physiological findings that the transport of gametes and embryo in very early stages in the isthmic portion of the oviduct tube is the result of a discontinuous pattern of forward and backward movements.