Development and morphology of rat synovial membrane

The development of the knee joint and synovial membrane in Wistar rats was studied from the 13th fetal day until adulthood by means of light microscopy, transmission electron microscopy and scanning electron microscopy. Using acid phosphatase and peroxidase methods, the different cell types of synovial membrane could be identified.     

THE UPTAKE OF IRON IN RABBIT SYNOVIAL TISSUE FOLLOWING INTRA-ARTICULAR INJECTION OF IRON DEXTRAN : A Light and Electron Microscope Study

Iron dextran (molecular weight 7,000) diffuses rapidly from the joint cavity through the synovium, along lymphatics and extracellular tissue spaces; articular cartilage is impermeable to iron dextran. There is also rapid cellular uptake by synovial lining cells, particularly of the vacuolar type; endoplasmic reticulum-containing lining cells rarely take up iron dextran. Cellular uptake is probably effected by pseudopodial folds projecting from the cell surface and enclosing extracellular material. Cells containing iron may degenerate and be ingested by phagocytes, and this may account for the concentration of iron in a smaller proportion of cells on or below the synovial surface in the later stages. At 6 to 18 hours after injection there is a mild inflammatory reaction and some synovial proliferation; from this stage onwards intracellular iron occurs in the form of haemosiderin. Granules of haemosiderin are present in the synovium 3 months after injection and possibly longer.     

SEM observations of the neural fold associated with neurulation in the rat

The topography of the ectoderm was examined by scanning electron microscopy during neurulation in rat embryos at stage 24 (somites 8-11). A zone of altered cell morphology was observed along the crest of neural folds. This zone was located between the presumptive neural tube and the surface ectoderm and exhibited numerous rounded cell blebs, immediately prior to fusion between the folds. It is suggested that the observed surface alterations may reflect a change in the properties of the altered cell which correlate with initial adhesion between the folds.     

Morphological aspect of voice disturbances of aged persons coexisting hypopharynx cancer

The voice quality in prebysphonia is conditioned by morphological changes in the vocal folds mucosa. The studies including light microscopy and transmission electron microscopy (TEM) revealed changes within the basal membrane epithelium and the stroma of the vocal folds mucosa. Age-related changes in thickness of the epithelium and direction of the basal membrane, increased number of collagenous fibres (C) and fibroblasts and chronic inflammatory process in the stroma were found. Vacuolated and keratinised epithelial cells, enlarged extracellular spaces and numerous blood vessels confirm the edematous form of prebysphonia. Thinned epithelium with signs of hyalinization, inflammatory infiltrations in the stroma with numerous collagenous fibres and small number of blood vessels indicate atrophy of the vocal folds mucosa. Edematous and atrophic changes in the vocal folds mucosa are most frequently reported form of prebysphonia.     

Videostroboscopic and morphological aspects of voice disturbances in patients with larynx atrophy and coexisting hypopharynx cancer

Vocal folds play a crucial role in voice production. The physiological vibrations of vocal folds depend on the unchanged multilayered structure of the vocal folds mucosa. Morphological changes of mucosa are the cause of voice quality disorders - dysphonia. The aim of this study was to determine the morphological base of dysphonia in patients with vocal folds atrophy. A group of 24 patients with larynx atrophy confirmed by endoscopic (VLS) and stroboscopic (VLSS) examination of the larynx was included in the study. The morphological assessment of the larynx mucosa was carried out with the use of the transmission electron microscopy (TEM). Ultramorphological examinations revealed changes in the epithelium, basal membrane and lamina propria of the vocal folds mucosa. An increased number of collagenous fibers, fibroblasts with signs of vacuolar degeneration inflammatory cells and a decreased number of blood vessels and pericytes were observed. Morphological changes found in the epithelium, basal membrane and lamina propria of the vocal folds mucosa were the cause of disorders of vocal folds vibrations registered in the stroboscopic examination of the larynx (VLSS).     

A Study of the Structure and Gliding Movement of Gregarina garnhami

SYNOPSIS The structure and gliding movement of Gregarina garnhami Canning, a eugregarine found in the midgut of the desert locust, Schistocerca gregaria , have been studied by light microscopy and transmission and scanning electron microscopy (EM). Ultrastructural studies revealed that the cytoplasm of G. garnhami is separated from the epicyte folds by a basal lamina. The pellicle consists of 3 membrane layers. At the tips of the epicyte folds there are 2 sets of longitudinally oriented filaments. An ectoplasmic network is present in the ectoplasm and the endoplasm contains numerous paraglycogen granules. The effect of cytochalasin B on G. garnhami was studied. Examination of scanning EM preparations of gliding and stationary gregarines yielded inconclusive results. In some instances the epicyte folds were thrown into waves; in others the folds were straight, regardless of treatment before fixation. Gregarina garnhami glides through its environment without any apparent deformation in shape. As it moves, a mucus trail is left behind it. Phase-contrast observations were made of centrifuged gregarines in which the endoplasm was displaced. Centrifuged gregarines continued to glide. Displacement of the endoplasm allows visualization of the epicyte folds in gliding animals. No lateral waves were seen in the epicyte folds of gliding centrifuged animals.     

Gap junctions in human synovial cells and tissue

Our objective was to establish the existence of intercellular communication through gap junctions in synovial lining cells and in primary and passaged cultures of human synovial cells. Communication between cells was assessed using the nystatin perforated-patch method, fluorescent dye transfer, immunochemistry, transmission electron microscopy, and immunoblotting. Functional gap junctions were observed in primary and passaged cultures and were based on measurements of the transient current response to a step voltage. The average resistance between cells in small aggregates was 300 +/- 150 MOmega. Gap junctions were also observed between synovial lining cells in tissue explants; the size of the cell network in synovial tissue was estimated to be greater than 40 cells. Intercellular communication between cultured cells and between synovial lining cells was confirmed by dye injection. Punctate fluorescent regions were seen along intercellular contacts between cultured cells and in synovial membranes in cells and tissue immunostained for connexin43. The presence of the protein was verified in immunoblots. Regular 2-nm intermembrane gap separations characteristic of gap junctions were seen in transmission electron micrographs of synovial biopsies. The results showed that formation of gap-junction channels capable of mediating ionic and molecular communication was a regular feature of synovial cells, both in tissue and in cultured cells. The gap junctions contained connexin43 protein and perhaps other proteins. The physiological purpose of gap junctions in synovial cells is unknown, but it is reasonable to anticipate that intercellular communication serves some presently unrecognized function.     

Demonstration of actin in the protozoon--Gregarina

Actin was identified in the motile trophozoites of Gregarina by indirect immunofluorescence microscopy. Ultrastructurally actin was found by immunogold labelling to be associated with the internal cytomembranes of the ectoplasmic folds and the general ectoplasmic region below the folds. Western blotting with antibodies to actin identified polypeptides with molecular weights around 43kD and 98kD in non-ionic detergent extracted trophozoites. The possibility of two distinct forms of cytoplasmic actin (43kD and 98kD) was considered.     

Ontogenetic development of synovial A cells in fetal and neonatal rat knee joints

Summary Ontogenetic development of the synovial A cells in fetal rat knee joints was investigated by immunohistochemistry, immuno-electron microscopy, cultivation, and autoradiography. At day 17 of gestation, immature macrophages were first seen in the articular interzone, and thereafter they differentiated into macrophages (synovial A cells), which were found in the synovial intima. The degree of reactivity of macrophages with five monoclonal antibodies increased in the developing synovial membranes of fetal rats as shown by immunohistochemistry. Similar findings were obtained in organ cultures of fetal knee joints. A marked difference of proliferative potential was found between A and B cells during ontogeny. A cells after birth did not incorporate ³H-thymidine in contrast to B cells. Before birth, B cells had a labelling index which was at least five times larger than that of A cells. The results of this study indicate that the synovial A cells are derived from both monocytes and fetal macrophages circulating in peripheral blood and that they differ from the synovial B cells in morphology, differentiation, and proliferative potential.     

Study of development of ciliary folds and Zinn's zonules in Rana temporaria L. by means of scanning electron microscopy]

The development of ciliary folds and zonul of Zinn has been studied in the eyes of the common frog Rana temporaria L. by means of scanning electron microscopy. The development of ciliary folds begins at the stage 45 by the flexure of the external layer in the ciliary zone. At the stage 46 this process involves the internal layer and the folds become two-layered. The zonules of Zinn form before the folds of internal layer of the ciliary epithelium begin to form as separate bundles of fibers. At the stage 45 they are already distinct. Later the ciliary filaments fold in 2 felt-like layers -- zonula which pass from the equatorial lens zone and attach near orbiculum ciliaris. In the place of attachment the margin of zonul repeats the relief of folds, thus attaching to their whole surface, and individual filaments go farther, to orbiculum ciliaris. All these processes take place in they eye prior to the beginning of metamorphosis.     

Innervation and membrane specialization at neuromuscular junctions in submaxillaris muscle of the frog

The submaxillaris muscle of the frog after zinc iodide-osmium staining reveals the presence of polyneural innervation. Cholinesterase staining shows that the longer terminals have postsynaptic folds whereas the smaller terminals (up to 5 micron) lack them. Thin-section electron microscopy shows that muscle fibers with or without an M line have terminals with and without postsynaptic folds. The terminals with postsynaptic folds have presynaptic membrane outpocketings above folds. These outpocketings are rudimentary or absent in the terminals without postsynaptic folds. In longer junctions, the P face of the presynaptic membrane has double rows of paired particles on active zone ridges perpendicular to the axis of the muscle. In smaller junctions active zone ridges are rudimentary or absent and double rows of particles form various patterns. Postsynaptic active zones in longer junctions consist of clusters of particles leaving gaps in between, whereas in the smaller junctions they lack gaps. The polyneural innervation and different deployment of membrane particles at neuromuscluar junctions could be a factor responsible for different physiological properties of this muscle.     

Fusion of Neural Folds in the Rhombencephalic Region of Rat Embryos

The progression of fusion of neural folds in the rhombencephalic region of rat embryos was examined using actin-specific antibody and scanning electron microscopy. In the region of unfused neural folds, actin was distributed over the entire luminal surface of the neural plate. Subsequently, the actin became localized on the luminal surface of outwardly opened, dorsolateral portions of the neural plate. Reduction in the area over which actin was distributed corresponded to the decrease in the area of the luminal surface of outwardly opened, dorsolateral portions of the neural plate. Decrease in the area of the luminal surface synchronized with elevation of the neural folds and their approach to the midline and, finally, actin became localized in areas of the apices of the neural plate that formed the bridge between the two opposing neural folds. These results suggest that formation of the bridge is orchestrated and supported by microfilaments. The procession of fusion in the rostral direction may cause approach of the neural folds to the middle, and this approach may be guaranteed by reduction in the area of the luminal surface over which actin is distributed.     

Influence of synovial cells on cartilage in vitro: induction of breakdown and inhibition of synthesis.

Organoid or high density cultures of: (1) synovial cells from patients with rheumatoid arthritis, and (2) prechondrogenic mesenchymal cells from limb buds of 12-day-old mouse embryos, were co-cultured for 7-10 days using the Trowell culture system. Depending on the time of commencing co-cultivation, chondrogenesis was inhibited (co-cultivation from the start) or the cartilaginous matrix was partly degraded (co-cultivation after formation of embryonic cartilage, i.e. on day 4). These effects were obtained with cells from synovial fluid as well as from synovial tissue. Matrix degradation and the behaviour of the different cell types could be demonstrated well by electron microscopy under the in vitro conditions applied.     

Scanning electron microscopic and histochemical studies of foliate papillae in the rabbit, rat and mouse

The foliate papillae of the rabbit, rat and mouse were studied by scanning electron microscopy and histochemistry. The papillae consisted of folds and grooves located on the posterolateral margin of the tongue in front of the circumvallate papillae. The numbers of folds and taste buds varied among the three animals species. Scanning electron microscopy showed that in longitudinal sections the taste buds were oval in shape and their pores were surrounded by microvilli. The reaction product of alkaline phosphatase could only be demonstrated in the superficial epithelium of the rabbit as well as in the mouse foliate papillae, but it also diffused into the taste buds in the rat. The intensity and distribution of the reactions of adenosine triphosphatase, acetylcholinesterase and butyrylcholinesterase were identical to those reported by other investigators in spite of differences in animal species and histochemical techniques employed.     

Epithelial cell proliferation in the intestine of the winter flounder,Pseudopleuronectes americanus

Summary To study epithelial cell proliferation in the North American flounder (Pseudopleuronectes americanus), fed and fasted fish received intravenous injections of ³H-thymidine and were killed 11/2 to 2 h later. Radioautographs of proximal, middle, and distal intestinal segments revealed proliferating epithelial cells at all levels of intestinal folds including the crest although labelled nuclei were most abundant in the epithelial cells on the lower half of folds and between folds. Mature appearing goblet cells with labelled nuclei were observed at all levels of the folds. The mean labelling index was greater in the epithelium of fed than fasted flounder. In fed flounder the mean labelling index was greatest in the proximal segment and least in the distal segment; no substantive differences in mean labelling indices were observed in the various segments of intestine from fasted fish. Electron microscopy revealed no major structural differences among epithelial cells along the base of folds compared to cells near the crest of folds. These findings indicate that 1) epithelial cell proliferation occurs at all levels of the folds of flounder intestine and is not compartmentalized to the base of the folds and interfold epithelium as reported in other teleosts, and 2) epithelial cell proliferation in the flounder intestine varies with feeding status.Supported be research grants AM 17537 and RR 05764 from the National Institutes of Health, Bethesda, Maryland and grant DEB7826821 AO1 from the National Science Foundation, Washington, D.C.The authors are grateful to Dr. Michael Field for stimulating discussions and suggestions and for providing facilities for collecting material from fish     

Neural fold and neural crest movement in the Mexican salamander Ambystoma mexicanum

In studies of amphibian neurulation, the terms "neural ridge," "neural fold," and "neural crest" are sometimes used as synonyms. This has occasionally led to the misconception that grafting of the neural crest is equivalent to grafting of the neural fold. The neural fold, however, is composed of three parts: the neural crest, prospective neural tube tissue, and epidermis. In order to investigate how these neural fold components move during neurulation, time-lapse photography, electron microscopy, and grafting were performed. Ambystoma mexicanum embryos were photographed during neurulation at regular intervals. The photographs were analyzed to find the position of those cells at beginning of neurulation that end up on the line of fusion as the neural folds close. Posteriorly, these cells are already on the emerging neural fold. In the anterior neural folds, however, these cells are located in the lateral epidermis. Electron microscopy of the neural folds confirms the presence of epidermis. To follow the movement of the cells differentiating into melanophores (neural crest), neural fold parts were grafted into albino hosts. The crest cells differentiating into melanophores following ectopic grafting are located in the flank of the neural fold that is in contact with the neural plate. In grafts from the outside (distal) flank, no melanophores developed. Semithin sections show that the third part of the neural fold consists of apically constricted cells known to differentiate into neural tissue. Because the neural folds consist of epidermis, neural tissue, and neural crest, neural fold and neural crest cannot be used as synonyms.     

Proventricular structure in solitary bees (Hymenoptera: Apoidea)

Proventricular structure, analyzed by scanning electronic microscopy, is compared among 28 species of solitary bees representing four families. Observations on the shapes of proventricular folds and on hair-like cuticular projections are presented, discussed, and suggested as useful to future studies of bee systematics.     

Observations on closure of the neuropores in the chick embryo.

Neuropore closure was studied in chick embryos by light and electron microscopy. Surface ectoderm reflects over the crests of the neural folds at all craniocaudal levels, merging with the neural ectoderm lining the neural groove. Apices of surface ectodermal cells have an essentially identical morphology prior to approximation of folds, both within the presumptive fusion sites and more laterally. Cells of these areas have slightly convex profiles exhibiting few cellular protrusions. Each neural fold contains a superficial half, composed of neural ectoderm covered by surface ectoderm, and a deep half consisting entirely of neural ectoderm. Initial contact between folds usually occurs near the junction between these halves in cranial regions, but is restricted primarily to surface ectoderm at caudal levels. Subsequent fusion of folds at all levels involves both ectodermal layers. Cellular protrusions and small, morphologically unspecialized intercellular junctions often interconnect cells of apposed folds in areas undergoing fusion. The anterior neuropore closes at stages 10-11, but fusion of folds in this region is not completed until stages 13-14. Fusion occurs dorsoventrally in this area and is more advanced internally than externally. Numerous pleomorphic inclusions and a few apparently necrotic cells are present in areas bordering the anterior neuropore. The posterior neuropore closes at stages 12-13 and fusion is completed in this region during stages 13-14. The caudal end of the posterior neuropore closes dorsal to the developing tail bud. Several morphological features of this closure may at least partially account for the high susceptibility to myeloschisis localized specifically at caudal spinal cord levels.     

Morphological aspects of the euphonic voice

The high quality of a euphonic voice is the result of complex interactions between many organs and systems. Vibrating vocal folds play a crucial role in this process. Their physiological motion is conditioned by the presence of the layered structure of laryngeal mucosa. In this study, we assessed the degree of dysphonia according to the Union of European Phoniatrics (UEP) scale. Videoendoscopy (VLS) and videostroboscopic (VLSS) examination of the larynx was used to visualize the vibration of the vocal folds. Morphological assessment of the inter-membranous part of the vocal fold mucosa was carried out using material collected after surgical treatment (60%) or obtained from autopsy (40%). The samples were examined by light microscopy and transmission electron microscopy. In euphonic voices, 1° of dysphonia (UEP) and the physiological endoscopic (VLS) and stroboscopic (VLSS) findings of vocal folds were registered. No morphological or ultramorphological changes were observed in the cells of the multilayered flat epithelium, basal membrane or in the stroma. Unchanged epithelial cells were situated on the basal membrane with folds. Moreover, numerous pericytes, vessels with multiplication of basal membranes, scanty collagenous fibers, plasmatic cells and lymphocytes were seen. Morphological changes with signs of atrophy and polypoid degeneration of the vocal fold mucosa were found in only 3 (15%) patients.     

Substrate Contact,Mucus, and Eugregregarine Gliding1

ABSTRACT. Experiments have been carried out on Gregarina garnhami to examine some of the factors that may be significant in gliding. Suspension of gregannes in Ficoll showed that substrate contact is essential. Reflection interference microscopy shows that there are fluctuating surface/substrate contacts, but it is not necessary for the whole of the undersurface of the cell to be in close contact with the substrate. Gliding is always accompanied by the formation of a mucus trail. The effects of the drugs amphetamine and ephedrine on mucus trail formation and gliding have been examined. Lateral undulations of the epicyte folds have previously been implicated in grcgarinc gliding, but G. garnhami does not exhibit lateral undulations of the epicyte folds as it moves. The folds are predominantly straight with indications of varicosities or swellings along the length of the folds. These observations are discussed in relation to gliding movement.