The functional and structural border of the neurohemal region of the median eminence

Summary In stressed rats the tanycytes of the ventrolateral wall of the third ventricle exhibit by light microscopic immunohistochemistry a positive staining for neurohormones which is distinctly limited to the distal perivascular end of the tanycyte process. Since by electron microscopic immuncytochemistry the tanycyte cytoplasm does not show any reaction product, the light microscopic reaction most likely results from a labeling of the intercellular space in the direct vicinity of the subendothelial cleft. Whether this subendothelial space is permeable to neurohormones was tested by injection of HRP¹. In the region of the arcuate nucleus 30 min after intravenous application, the marker is affixed to the membranes of the perivascular tanycyte processes in the subendothelial cleft of capillaries possessing non-fenestrated endothelia. Occasionally, HRP penetrates for a short distance between the tanycytes. Then the labeling of the intercellular cleft ends abruptly. Here, several parallel ridges of tight junctions between the perivascular distal tanycyte processes are found by the freezeetching technique. Since HRP cannot reach the subendothelial clefts of this region by passing through capillary walls due to the presence of a blood-brain barrier, it is suggested that the marker penetrates from the median eminence this far via the subendothelial extracellular space. It is prevented from spreading further by the tight junctions of the perivascular tanycyte endings. The same way may be taken by the neurohormones. Hence, a border area exists adjacent to the dorsolateral aspect of the neurohemal region of the median eminence where the tanycytes isolate the neuropil from the cerebrospinal fluid not only by their apical tight junctions, but also by basal tight junctions from the subendothelial cleft. This communicates with the perivascular space of the portal vessels.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr. 569/2) and Stiftung VolkswagenwerkDedicated to Professor Dr. R. Ortmann on the occasion of his 65th birthday.The skilful technical assistance of Miss K. Bielenberg, Mrs. A. Hinz and Mrs. H. Prien is thankfully acknowledged     

The functional and structural border between the CSF-and blood-milieu in the circumventricular organs (organum vasculosum laminae terminalis,subfornical organ,area postrema) of the rat

Summary The present study continues a previous investigation on the median eminence (EM) (Krisch et al., 1978). In rats with high levels of neurohormones (LHRH, vasopressin) a limited immunohistochemical labeling of perivascular tanycyte processes can be observed surrounding capillaries in the marginal region of the organum vasculosum laminae terminalis (OVLT) and in the inner part of the subfornical organ (SFO). This labeling extends from the perivascular space a short distance along the tanycyte processes. By conventional electron microscopy and by freeze-etching, tight junctions are demonstrated at a distance from the capillary lumen which corresponds to the borderline of the immunohistochemical labeling of perivascular tanycyte processes in light microscopic preparations. The tight junctions are arranged in several parallel and helical rows and correspond to those found in the median eminence. Consequently, the immunohistochemical labeling in the OVLT and in the SFO marks the intercellular cleft. In the circumventricular organs the immunostaining labels the extension of the perivascular space characterized by the hemal milieu. The perivascular space is separated off by tight junctions from the CSF-milieu of the adjacent neuropil. Furthermore, the present study demonstrates tight junctions in the marginal region of the area postrema (AP) between the perivascular processes of the tanycytes.Supported by the Deutsche Forschungsgemeinschaft (Grant Nr. Kr. 569/2) and Stiftung VolkswagenwerkThe skillful technical assistance of Miss K. Bielenberg, Mrs. A. Hinz and Mrs. Helga Prien is thankfully acknowledged     

The microvascular pattern and perivascular linings of the area postrema

Summary The microvasculature and perivascular linings of the area postrema (A.P.) were studied electron microscopically with the ultrathin section and freeze-etching techniques. Special attention was given to the intercellular contacts of the different cellular entities. Two types of microvascular segments were identified. The endothelium of these vascular segments reveals fenestrations and a high pinocytotic activity. There are no significant differences in the frequency and distribution of the endothelial openings between both types of capillaries. The endothelium of the blood vessels, however, is joined by different types of tight junctions. Focal tight junctions occur between pericytes and the endothelium, and between leptomeningeal cellular elements in the perivascular space. The cell membrane of the perivascular glia shows intramembrane particles which are either distributed at random or organized in the form of membrane-associated orthogonal particle complexes (MOPC, Dermietzel, 1974). The significance of these findings is discussed with respect to the modified blood-brain barrier mechanism in the A.P.Supported by a grant of the Deutsche Forschungsgemeinschaft (SFB 114 Bionach) to R. DermietzelThe authors are indebted to Mrs. D. Schünke and Mr. R. Eichner for technical assistance and Mr. A. Stapper for preparing the diagram     

Connective tissue in the perivascular spaces of subependymal capillaries of the spinal cord in the rabbit]

The normal structure of the subependymal capillaries and venules of the spinal cord was studied in rabbit. The endothelial cells of the capillaries and venules are surrounded by an irregularly formed perivascular space, about 0.5 to 3.3 micrometer wide, which is delimited by an endothelial and glial basal lamina. The space contains a framework of collagen fibers. A period-acid-bisulfit-aldehydthionine-method (Specht) permits to find the perivascular connective tissue lightmicroscopically, while they can be identified by electron microscopy. The significance of the perivascular connective tissue is open to discussion. Structural and functional problems have been reviewed in this context.     

Immuno-electron-microscopic analysis of the basal route of secretion in the subcommissural organ of the rabbit

Summary Low-temperature-embedded tissue of the subcommissural organ (SCO) of the rabbit was analyzed for the basal route of secretory product by means of indirect immuno-metal cytochemistry (protein A-gold technique) at the electron-microscopic level. By use of (1) an antiserum against bovine Reissner's fibre (see Sterba et al. 1981) and, thereafter, (2) particulate gold-marker solution, immunoreactive sites could be clearly visualized within the extracellular matrix of both (a) the basal part of the ependymal cell layer, and (b) the hypendyma proper. Abundant secretory material was identified within (i) dilated intercellular spaces (a + b) as well as (ii) branching basal lamina labyrinths and distinct perivascular spaces (b). All these compartments are thought to belong to a system of extracellular channels, which may function in secretion directed toward hypendymal blood vessels.Supported by Grants from the Ministry for Sciences and Technology of the German Democratic RepublicThe expert technical assistance of Mrs. S. Mehnert, Mrs. E. Siebert, Mrs. Ch. Schneider, Mrs. I. Seifert and Mr. H. Wolf is gratefully acknowledgedDedicated to Prof. Dr.Dr.h.c. Andreas Oksche on the occasion of his 60th birthday     

Organization and development of the perivascular space system in the neurohypophysis of the laboratory mouse

Summary The organization of the system of perivascular space around the capillaries in the neurohypophysis was studied in the adult and developing laboratory mouse by the use of histological silver impregnation and electron microscopical techniques.In the median eminence short and long extensions, arising mainly from the shallow space around capillary loops of the primary plexus of the portal system, formed radiations into the adjacent neural tissue of the external zone. The tissue of the neural lobe was separable into non-vascular regions dominated by undilated portions of neurosecretory nerve fibres and pituicytes, and neurovascular regions with perivascular space extensions forming an extensive system of connections between neighbouring capillaries.In the median eminence, the system of extensions of the perivascular space was estimated to increase the neurovascular contact surface area by at least 50%, implying an increased efficiency of the organ without a notable increase of its volume. The possibility that the ramifications of the perivascular space imply an enhanced uptake rate into the bloodstream and a subsequent increased concentration of the neurohormones in the portal blood, was discussed.During development of the median eminence, differentiation of perivascular space extensions of the adult type started in the juvenile of about three weeks of age, when shallow capillary loops had been formed. In the neural lobe, perivascular space ramifications were already present when the internal capillaries were formed and were fairly frequent in ten-day young. At the age of three to four weeks the organization of the system was similar to that of the adult animal.     

Drainage of macromolecules from the Caudato-Putamen of rat brain

To study the drainage of interstitial fluid and macromolecules from the brain parenchyma, an improved method was developed to inject tracers including Chinese ink in group I and phycoerythrin (PE) in group II into the right caudato-putamen of rat brain. Rats were sacrificed on the 1st, 3rd, 7th, 14th, 21st day after injection in group I and at the 0.5, 1, 2, 5, 24 hour in group II. Distribution of tracers was observed by electron microscopy and fluorescence confocal microscopy. The results showed that tracers distributed diffusely in the white matter at all time points whereas they spread selectively along perivascular spaces in the gray matter by 7 days (d) in group I and 5 hours (h) in group II. Chinese ink was ingested by perivascular phagocytes by 7 d after ink injection. The endothelial cells of capillaries in the gray matter had fluorescence staining in cytoplasm and no staining in nuclei by 24 h after PE injection. Animals in group II were stained with tracers in lateral ventricles, bilateral cervical lymph nodes, and the wall of carotid arteries. These results demonstrated that [1] the macromolecules could be cleared from the caudato-putamen through extracellular space of the neuropil in the white matter and perivascular space in the gray matter, [2] perivascular phagocytes and endothelial cells of capillaries played important roles in clearing macromolecules from the perivascular space, and [3] cervical lymph nodes were involved in draining macromolecules from the brain parenchyma.     

The development of the human lymph node

Summary Lymph nodes of human fetuses from the 11th to the 20th gestational week (g.w.) were investigated by light- and electron microscopy under particular consideration of the development of the T-cell and the B-cell regions and their specific reticulum cells. Lymph node development begins as a mesenchymal condensation, containing capillaries and mesenchymal cells; this primordium bulges into a lymph sac. Within the primordium of the lymph node granulopoiesis and erythropoiesis occur temporarily from the 12th to the 14th g.w. The first lymphoid cells and undifferentiated blast cells are seen in the 12th g.w.; monocytes and macrophages can be found from the 13th g.w. onward.The development of the T-cell regions begins during the 13th g.w., before differentiation into cortex and medulla becomes obvious in the 14th g.w. Near the marginal sinus, cells displaying features of interdigitating reticulum cells (IDC) show similarities to monocytes. The morphological differentiation of the IDC is complete in the 17th g.w. when they are found in the paracortical region. Among the IDC, lymphoid cells with features of thymocytes are arranged in small groups.The first indication of the development of B-cell regions can be recognized in the 14th g.w. when precursors of dendritic reticulum cells (DRC) are seen near the marginal sinus; this area also displays lymphoblasts, immunoblasts, and plasmoblasts. During the 20th g.w. small primary follicles are discernible in the outer cortex; in addition to blast cells they contain small lymphocytes, none of which show features of thymocytes. The morphological development of DRCs is not entirely complete until the 20th g.w.; however, some cells already show a characteristic network of interwoven processes.The probable origin of (i) the IDC from monocytes, and (ii) the DRC and fibroblastic reticulum cells from a common type of mesenchymal precursor cells, as well as their significance for a specific micromilieu in the T-cell and the B-cell regions, are discussed.This investigation was supported by grants from the Deutsche Forschungsgemeinschaft and the Sonderforschungsbereich 111 of the Deutsche ForschungsgemeinschaftThe authors appreciate the contribution of human fetal material from Dr. J. von Hollweg and Dr. J. Körner, Hospital Heidberg, Hamburg, and the excellent technical assistance of Mrs. O.M. Bracker, Mrs. H. Hansen, Mrs. R. Köpke, Mrs. I. Knauer, Mrs. F. Müller, Mrs. H. Siebke, and Mrs. H. Waluk     

Pericytes and perivascular microglial cells in the basal forebrain of the neonatal rabbit

Summary Three types of pericytes outline the vascular bed in Golgi preparations of the newborn rabbit brain. Elongate cells (Type I) are restricted to capillaries, elements resembling smooth muscle cells (Type II) surround vessels of intermediate size, and large flat forms (Type III) cover the surface of arterioles and venules. Electron microscopy shows all types to be located within a well defined perivascular basement membrane. It also reveals the presence of filaments in the cytoplasm of some pericytes resembling the myofilaments of smooth muscle cells. It suggests the possibility that some pericytes are capable of contraction and may participate in regulating blood flow in small vessels.Microglia cells bear no resemblance to pericytes in terms of their shape, distribution or staining characteristics. Microglia cells are located outside the vascular basement membrane (external basal lamina) in the brain parenchyma, and they vary in form according to their location and the character of the surrounding extracellular space. This study does not support the hypothesis that microglia cells arise from pericytes but indicates that they originate either by in situ division or from hematogenous elements that enter the brain by crossing the vessel wall.Support provided by N.I.H. Grants No. NS 10864 and NS 07938 from the U.S. Public Health Service.     

The ultrastructure of the human fetal pineal gland

Summary The ultrastructure of the pineal gland of 18 human fetuses (crown-rump lengths 30–178 mm) was investigated.The pineal gland exhibits a pyramidal shape and consists of an anterior and posterior lobe. Only one parenchymal cell type, the pinealocyte, was observed. Few neuroblasts were seen between the pinealocytes and in the extended perivascular space. The pinealocytes possess all the organelles necessary for hormone synthesis. No specific secretory granule could be observed. The organ is abundantly vascularized and richly innervated. The morphology of the capillaries indicates the existence of a blood-brain barrier.The ultrastructure of the human fetal pineal gland suggests that the gland has a secretory function in early intrauterine life. Acknowledgements. The author is grateful to Mrs. Yael Balslev and Miss Inger Ægidius for their able technical assistance. This investigation was supported in part by The Carl and Ellen Hertz's foundation and the Johann and Hanne Weimann foundation.     

The development of the human tonsilla palatina

Summary Tonsils of human fetuses at the 8th to the 28th gestational week (g.w.) were investigated by electron microscopy, enzyme histochemistry, and immunohistochemistry on cryostat sections. The development of the tonsilla palatina starts during the 14th g.w. when the mesenchyme underlying the mucous membrane of the tonsillar cavity becomes invaded by mononuclear wandering cells. In fetuses of about the 16th g.w. epithelial crypts grow down into the connective tissue and are infiltrated by T-lymphocytes. At the same time, precursors of interdigitating cells (IDC) can be identified among the epithelial cells. Frequently, lymphocytes and IDC-like cells are in close contact. From these findings it is concluded that the infiltrated crypt epithelium in the human tonsilla palatina represents a T-cell region. Primary follicles develop in earlier fetal stages than in all other secondary lymphoid organs. They contain precursors of dendritic reticulum cells and lymphoid cells that belong to the B-cell line. These primary follicles may be considered as the first assemblage of B-cell regions in human fetal lymphoid tissue. The present findings indicate that the formation of different stationary elements during the development of B-cell regions and T-cell regions is an important factor for the homing and antigen-dependent maturation of different subpopulations of immunocompetent lymphoid cells.This investigation was supported by grants from the Deutsche Forschungsgemeinschaft, particularly the Sonderforschungsbereich 111The authors appreciate the contribution of human fetal material from Dr. J. von Hollweg and Dr. J. Körner from the Hospital Heidberg c.o. Hamburg and the excellent technical assistance of Mrs. O.-M. Bracker, Mrs. H. Hansen, Mrs. I. Knauer, Mrs. R. Köpke, Mrs. I. König, Mrs. F. Müller, Mrs. H. Siebke and Mrs. H. Waluk     

Hematoencephalic barrier. Ultrastructure and histophysiology of the endothelium capillary of the neuronal nuclei of the mesencephalon.

The ultrastructure of the dorsal periaqueductal nucleus capillaries of the mesencephalon in the cat was studied under the electron microscope in relation to the hematoencephalic barrier, and its four structural levels: 1. Endothelium; 2. Basal membrane; 3, Pericytes; and 4. Glial prolongations. An analysis was performed of what occurs in these four components (in a non-experimental histophysiological state, and without manipulation by markers) in the thinnest capillaries of the centre of the mesencephalic neuronal nucleus. Special attention was placed on the first diffusion barrier formed by the endothelium capillary as the intimate guardian of the Central Nervous System (C.N.S.) neurons. The C.N.S. capillaries are formed from the continuous endothelium, with no fenestrations, and hermetic joining complexes, without pinocytosis vesicles on both sides of the plasmatic membrane (adluminal and external), and surrounded by a continuous basal membrane. The non-fenestrated capillaries of the C.N.S. are less permeable than those with similar characteristics located in other areas. In the C.N.S. these capillaries form a selective physiological barrier which determines the size of the molecules that are permitted to cross the capillary wall. It is suggested that the electron-dense globules found in the endothelium cytoplasm may be molecules assimilated from the blood, which might represent the first level or step to the selective diffusion entrusted to the hematoencephalic barrier. It is also suggested that the elongated electron-dense particles found in the endothelium cytoplasm and basal membrane may be macromolecules which are normally retained for an active defensive function. They would represent the first and second level or steps of the retention performed by the hematoencephalic barrier which blocks their passage to the confined space of the perivascular capillary.     

Normal murine melanocytes in culture

Summary A major obstacle to applying the techniques of molecular biology to the genetics and cell biology of pigmentation has been our inability to grow normal murine melanocytes in culture. We report here the establishment and characterization of continuously proliferating cultures of cutaneous pigment cells from seven strains of mice. Melanocytes were grown from the dermis of newborn mice in medium containing 12-0-tetradecanoyl-13-phorbol-acetate; a substance, such as melanotropin, that raises intracellular levels of cyclic AMP; and an extract made from human placenta. This work was supported by Grant R01 CA04679 from the U.S. National Institutes of Health and a fellowship to Dr. A. Tamura from Mr. and Mrs. Allen Locklin. The chromosome studies were carried out in the laboratory of Dr. Uta Francke, Department of Human Genetics, Yale University. JCM was supported by NIH contract number N01-CP-21037.     

Lateral connections between heart muscle cells as revealed by conventional and high voltage transmission electron microscopy

Summary The lateral surfaces of heart muscle cells are interconnected by a varied and extensive network of structures that exist in addition to intercalated discs. Ultrastructural images of this network are vastly improved over those from epoxy-embedded material, particularly for low density components, through the application of a method for removing the embedding matrix from thin or thick sections that are then stereoscopically analyzed with standard or high voltage transmission electron microscopy. The connections include cables, 3–20 nm in diameter, multi-strand cables, 10–40 nm-granules, meshlike mats, and sheets, all extensively interwoven. It is suggested that intercellular connections of varying strength and distribution aid in the integration of mechanical performance of the large population of myocytes during the contractile cycle of the heart.This study was supported by a grant from NIH Biotechnology Resources through the University of Colorado High Voltage E.M. Laboratory, NIH Research Grant HL 24336, a N.Y. Heart Association Grant-in-Aid, and NIH Research Career Development Award HL 00568I thank Dr. E.H. Sonnenblick for continual aid and encouragement and Dr. R. Terry, Ms. Y. Kress, and Ms. J. Fant for use of facilities. I also thank Dr. K.R. Porter for guidance in the use of the HVEM technique, Dr. J.J. Wolosewick and Dr. M. Fotino for valuable suggestions, and Ms. J. Fleming, Mr. G. Wray, and Mr. G. Charlie of HVEM staff at Boulder. I acknowledge Dr. F. Pepe for use of facilities, Dr. R. Bloodgood for comments, and Mrs. L. Cohen-Gould, Ms. T. Downey, Mr. F. Reingold, Mrs. T. Maio, and Mrs. R. Shamoon for excellent assistance     

The rhombencephalic recess in the rat

Summary The rhombencephalic recess, an ependymal organ, has been studied for the first time by light- and electron microscopy. It is situated mediosagittally on the floor of the rhomboid fossa at the level of the colliculus facialis. The recess and the superimposed tissue are built up by tanycytes, their apices being connected by tight junctions. HRP, injected into the c.s.f., does not penetrate into the intercellular clefts of the recess area. The recess area reveals a certain autonomy regarding its supply with arteries and capillaries. A bloodbrain barrier exists, but shows slight leakage in circumscribed areas as a result of intense transendothelial vesicular transport. The organization of the recess area is compared with that of other ependymal organs, especially circumventricular organs.The skilful technical assistance of Miss K. Bielenberg, Mrs. H. Prien, Mrs. E. Schöngarth and Mrs. H. Schöning is thankfully acknowledgedSupported by the Deutsche Forschungsgemeinschaft (Kr 569/1 and SFB 34/D4) and Stiftung Volkswagenwerk

---

     

Constrained sequence alignment

This paper presents a dynamic programming algorithm for aligning two sequeces when the alignment is constrained to lie between two arbitrary boundary lines in the dynamic programming matrix. For affine gap penalties, the algorithm requires onlyO(F) computation time andO(M+N) space, whereF is the area of the feasible region andM andN are the sequence lengths. The result extends to concave gap penalties, with somewhat increased time and space bounds. K.-M. C. and W. M. were supported in part by grant R01 LM05110 from the National Library of Medicine. R. C. H. was supported by PHS grant R01 DK27635.     

Role of the conserved arginine 274 and histidine 224 and 228 residues in the NuoCD subunit of complex I from Escherichia coli

The conserved arginine 274 and histidine 224 and 228 residues in subunit NuoCD of complex I from Escherichia coli were substituted for alanine. The wild-type and mutated NuoCD subunit was expressed on a plasmid in an E. coli strain bearing a nuoCD deletion. Complex I was fully expressed in the H224A and H228A mutants, whereas the R274A mutation yielded approximately 50% expression. Ubiquinone reductase activity of complex I was studied in membranes and with purified enzyme and was 50% and 30% of the wild-type activity in the H224A and H228A mutants, respectively. The activity of R274A was less than 5% of the wild type in membranes but 20% in purified complex I. Rolliniastatin inhibited quinone reductase activity in the mutants with similar affinity as in the wild type, indicating that the quinone-binding site was not significantly altered by the mutations. Ubiquinone-dependent superoxide production by complex I was similar to the wild type in the R274A mutant but slightly higher in the H224A and H228A mutants. The EPR spectra of purified complex I from the H224A and H228A mutants did not differ from the wild type. In contrast, the signals of the N2 cluster and another fast-relaxing [4Fe-4S] cluster, tentatively assigned as N6b, were drastically decreased in the NADH-reduced R274A mutant enzyme but reappeared on further reduction with dithionite. These findings show that the redox potential of the N2 and N6b centers is shifted to more negative values by the R274A mutation. Purified complex I was reconstituted into liposomes, and electric potential was generated across the membrane upon NADH addition in all three mutant enzymes, suggesting that none of the mutations directly affect the proton-pumping machinery.     

Control of the pars intermedia of the lizard,Anolis carolinensis

Summary Morphological changes in the disconnected neuro-intermediate lobe were studied in the lizard, Anolis carolinensis from the 2nd to the 14th post-operative day using a threefold aldehyde fixative (Rodríguez, 1969). Two phases of colour change capacity were exhibited: Phase I started immediately after the transection, lasted for 6 days (mean) and was characterised by an excessive MSH release (brown skin). This phase proceeded gradually into Phase II, designated by an interruption of the MSH release (green skin).The degenerative processes and final elimination of neurons in the disconnected neural lobe propagate in a rostro-caudal direction from the transected area. The aminergic fibres (Type II) disappear within 2 days postoperatively, whereas the degeneration continues for more than 10 days in the peptidergic fibres (Type III, IV and V). The glia cells (ependyma and pituicytes) serve as very active macrophages, engulfing fragments of axons already affected by autolysis and transferring them into glial lysosomes. No apparent morphological changes occur in the shift from Phase I to II.The great majority of the secretory cells of the intermediate lobe are not affected by degenerative processes and appear to be markedly activated by the stalk transection. They exhibit numerous mitochondria, well-developed Golgi complexes forming numerous Golgi vesicles and extensive parallel cisternae of the rough endoplasmic reticulum, sometimes forming large intracisternal droplets (7 m in diameter). Numerous pale vacuoles are seen, especially toward the intact capillaries, suggesting their coupling to the MSH release by extension of the active membrane area toward the perivascular septum. The number of these vacuoles is very markedly reduced in Phase II (no release), whereas the formation of new granules seems to proceed in early stages. The interruption of the MSH release implies a successive refilling of gradually growing secretory granules and a concomitant reduction in the development of the synthetic apparatus. Mechanisms probably involved in the control of the synthesis and release of MSH are discussed.Supported by grants from the Swedish Natural Science Research Council (to P. Meurling) and the Royal Physiographic Society of LundThe authors are indebted to Mrs. Lena Sandell, Mrs. Ingrid Hallberg and Mrs. Kirsten Thörneby for technical assistance and skillful attention of the animals and to Miss Inger Norling for photographic aid.     

The effects of variation in the arterial pulse waveform on perivascular flow

Cerebrospinal fluid (CSF) enters nervous tissues through perivascular spaces. Flow through these pathways is important for solute transport and to prevent fluid accumulation. Syringomyelia is commonly associated with subarachnoid space obstructions such as Chiari I malformation. However, the mechanism of development of these fluid-filled cavities is unclear. Studies have suggested that changes in the arterial and CSF pressures could alter normal perivascular flow. This study uses an idealised model of the perivascular space to investigate how variation in the arterial pulse influences fluid flow. The model used simulated subarachnoid pressures from healthy controls (N = 9), Chiari patients with (N = 7) and without (N = 8) syringomyelia. A parametric analysis was conducted to determine how features of the arterial pulse altered flow. The features of interest included: the timing and magnitude of the peak displacement, and the area under the curve in the phases of uptake and decline. A secondary aim was to determine if the previously observed differences between subject groups were sensitive to variation in the arterial pulse wave. The study demonstrated that the Chiari patients without a syrinx maintained a significantly higher level of perivascular inflow over a physiologically likely range of pulse wave shapes. The analysis also suggested that age-related changes in the arterial pulse (i.e. increased late systolic pulse amplitude and faster diastolic decay), could increase resistance to perivascular inflow affecting solute transport.     

Preparation and discharge of secretion in the subcommissural organ of the rat

Summary The secretion of the subcommissural organ (SCO) of the rat was studied by means of immunocytochemistry at the electron-microscopic level with the use of (1) the polar embedding medium Lowicryl K4M at -30° C, (2) the protein A-gold technique, and (3) a rabbit antiserum against bovine Reissner's fiber (see Sterba et al. 1981).Two different substructures of the ependymal and the hypendymal SCO-cells display a positive immunocytochemical reaction: (1) sacs containing flocculent secretion, which originate from the granular endoplasmic reticulum, and (2) vacuoles filled with fine granular secretion, which are pinched off from the Golgi apparatus. The secretory material of the sacs and the vacuoles is discharged both (i) apically into the cerebrospinal fluid and (ii) basally into intercellular spaces of the SCO-hypendyma. The apically released secretion is condensed to a lamina-like formation, which more caudally assumes the form of Reissner's fiber. The route of the basally released secretion remains, however, vague. The periodically striated bodies, which were thought to be morphological mediators of the discharge of the secretion into the capillaries, are never labeled by gold particles.Supported by grants from the Ministry for Science and Technology of the German Democratic RepublicThe expert technical assistance of Mrs. B. Wolff, Mrs. S. Mehnert, Mrs. E. Siebert, Mrs. Ch. Schneider, and Mrs. I. Seifert is gratefully acknowledged