Microvascular pathological features of immediate perinidal parenchyma in cerebral arteriovenous malformations: giant bed capillaries

Object. The behavior of brain tissue in cases of arteriovenous malformations (AVMs) is a matter of debate. The authors believe that the local microvascular environment in the AVM bed shares the hemodynamic changes influencing that behavior in one way or another. The purpose of this study was to investigate the microvascular pathological features in the immediate perinidal brain tissue. Methods. This retrospective study was conducted using excised AVM specimens obtained in 35 patients, from which the authors selected 20 specimens that fulfilled the criteria for sufficient brain tissue around the excised nidus. Specimens were stained with hematoxylin and eosin, and the immediate perinidal microvascular environment was examined using light microscopy. Conclusions. Eighty-five percent of the AVMs studied showed the presence of huge, dilated capillaries, and 65% showed severe congestion of these capillaries. The authors have named these capillaries “giant bed capillaries.” In this study capillary bleeding was shown in AVMs, and a pericapillary space was seen around some vessels. The brain parenchyma containing AVMs with these findings proved to be significantly ischemic.

Characteristics of Capillary Permeability in Nasal Mucosa

The transendothelial passage of horseradish peroxidase (HRP) and colloidal carbon and diffusion of HRP in pericapillary space, injected intravenously into rats, was studied at the light microscopic and ultrastructural level in the nasal mucosa. In the lamina propria of the mucosa in the middle third of the nasal septum of rats, the capillaries directly beneath the epithelium were mostly with fenestrae, while the capillaries around the nasal gland were without the fenestrae. The permeability of the capillaries in the lamina propria of the nasal mucosa was very high and some of the endothelial cells were wide open, like liver sinusoid, allowing free passage of carbon particles. Marked transendothelial passage was also noted at ten seconds after HRP infusion through the capillaries without fenestrae located around the nasal gland. On the other hand, no extracapillary leakage of HRP was noted even at 150 seconds after its infusion in the capillaries without fenestrae located in the muscles. The permeability of small venules located in the lamina propria of nasal mucosa also was extremely high. The reasons for the greater permeation of HRP through capillaries of nasal mucosa are as follows. First, the endothelial cell junction was loose in the nasal mucosa and in some capillaries endothelium had holes like liver sinusoid. Second, interstitium surrounding the capillary was loose in nasal mucosa.

Molecular organization of rat prolactin granules: in vitro stability of intact and "membraneless" granules

Studies carried out on a number of secretory cell systems suggest that the specific cytoplasmic granules in which the secretion products are stored before their release are complex organelles which can possess a distinct molecular organization. For instance, it has been reported that in some granules the segregated secretion products are organized into crystalline structures (1-3) or large intermolecular aggregates (4-8). It is likely that all phenomena of this type are favorable to the economy of the cell, in the sense that they reduce the energy required for storage of the secretion products. The prolactin (LTH) granules of the rat pituitary possess a number of morphological features which strongly suggest that the molecules(s) of their content might be arranged in a relatively stable structure. Thus, these granules are remarkably polymorphic in shape, and their membrane is usually separated from their content by a clear space. Furthermore, identifiable LTH granules devoid of their membrane are often seen in the pericapillary space, suggesting that upon discharge by exocytosis they are dissolved only slowly (9). However, no studies specifically concerned with the mechanisms of LTH storage have been reported so far. In order to obtain some information on this question, we have studied the behavior of isolated granule fractions incubated in vitro under a variety of carefully controlled experimental conditions.

Stellate Cells in the Pituitary Gland of the Salamander

The fine structure of five cell types in the pars distalis of the salamander [Notophthalmus (Triturus) viridescens viridescens] pituitary gland has been described. Four of these possess characteristic secretory granules (figure 1) and apparently they are involved in the synthesis and secretion of pituitary hormones. The other cell (Cell type #5 or “stellate cell”) does not possess characteristic secretory granules (figures 1 and 2) and they show a morphology which does not suggest a secretory function. The present report extends the observations on the fine structure of the stellate cell and considers, in addition, the distribution of this cell throughout the pars distalis.The stellate cell displays many slender, cytoplasmic extensions which penetrate between the secretory cells (figure 1). These extensions contact processes from other stellate cells and desmosomes are found at the points of contact. Moreover, desmosomes are frequently located between the stellate cells and the secretory cells (figure 2). Thus, the stellate cells are not only linked to each other throughout the pars distalis, but to each secretory cell as well. Stellate cell processes contact the outer basement lamina of the pericapillary space and often such processes follow the contour of the basement lamina for considerable distances. They do not penetrate, however, into the pericapillary space.

OBSERVATIONS ON THE FINE STRUCTURE OF LUTEIN CELLS

Corpora lutea from the period of delayed implantation and from early postimplantation stages of the armadillo, mink, and rat were fixed in buffered osmium tetroxide-sucrose or potassium permanganate. After rapid dehydration, the portions of the corpora lutea were embedded in either methacrylate or epoxy resin. Examination of the lutein cells by electron microscopy revealed the presence, in the better preserved material, of an extensive development of tubular agranular endoplasmic reticulum. Although the membranes of the endoplasmic reticulum are the most striking feature of the lutein cells of both stages of the three animals examined, very numerous large mitochondria with cristae that exhibit a variety of forms tending toward villiform, and protrusions and foldings of the lutein cell margins on the pericapillary space are also characteristic of these cells. Certain minor differences in the lutein cells of the species examined are also noted. No indications of conversion of mitochondria into lipid, of accumulation of lipid in the Golgi area, or of the protrusion of lutein cells into spaces between the endothelial cells, as suggested by other authors, were noted in these preparations. Some of the difficulties inherent in the visualization of the secretory activity of cells producing steroid hormones are briefly discussed.