Use of high resolution algorithm in computerized tomography of disseminated lung diseases]

Lobule of the lung is a principal anatomical structure of the respiratory zone in the lungs. Secondary lobule of the lung consists of about fifty primary lobules and is delineated by fibrous interlobular septa. Each lobule is delineated by interlobular septa and blood is supplied by small arterioles of pulmonary artery system. Its shape is conical and size ranges from 10 to 22 mm. The author used algorithm of high resolution in HR CT to present normal distal generations of respiratory area of the lungs and the same in 32 patients with disseminated lesions to the lungs. It is known, that lobule of the lung may be involved in very important pathologies. The author shown that significant architectural rearrangement takes place in pulmonary lobules and adjacent areas in the course of disseminated pulmonary diseases. The process include thickening of interlobular septa, consolidation of lobular area, changes in the shape of lobuli, and appearance of small cysts. The use of HR CT enables imaging in such pathologies which normally are inaccessible to conventional radiologic examinations.     

Injection studies of cortical and medullary organization in the avian kidney

Cortical lobules of the avian kidney are branched structures in which the efferent venous system forms an intralobular axis. The latter receives portal blood through an intertubular capillary plexus. Capillary distribution is regionalized thus delimiting the boundaries of individual cortical lobules. The size of cortical lobules (combined length of individual branches) varies intraspecifically from less than 1 mm to more than 18 mm. The largest units are peripherally located in the dorsal and lateral aspects of the kidney, while smaller lobules are deeper within the renal mass. A system of naming the branches of the efferent venous drainage is described. Cortical lobules take origin at varied levels along this venous network. A typical cortical lobule provides collecting ducts and loops of Henle to several medullary lobules. The latter contact the cortical unit at intervals along its length, and each may be associated with more than one cortical lobule. Although boundaries are indefinite, a renal lobe can be regarded as a group of medullary lobules usually draining into a secondary ureteral branch plus their associated cortex.     

A fully coupled porous media and channels flow approach for simulation of blood and bile flow through the liver lobules

Two dimensional, steady state, and incompressible blood and bile flows through the liver lobules are numerically simulated. Two different geometric models A and B are proposed to study the effects of lobule structure on the fluid flow behaviour. In Model A, the lobule tissue is represented as a hexagonal shape porous medium with a set of flow channels at its vertices accounting for the hepatic artery, portal and central veins along with bile ductules. Model B is a channelized porous medium constructed by adding a set of flow channels, representing the bile canaliculies and lobule sinusoids, to Model A. The bile and blood flow through the lobule is simulated by the finite element approach, based on the Darcy/Brinkman equations in the lobule tissue and the Navier-Stokes (or Stokes) equations in the flow channels. In Model B, a transmission factor on the boundaries of the bile canaliculies is introduced to connect the bile and blood flows. First, a single regular lobule is utilized to exhibit the fluid flow pattern through the liver lobule represented by proposed geometric models. Then, the model is extended to a group of liver lobules to demonstrate the flow through a liver slice represented by irregular lobules. Numerical results indicate that the Darcy and Brinkman equations provide nearly the same solutions for Model A and similar solutions with a little difference for Model B. It is shown that the existence of sinusoids and bile canaliculies inside the liver lobules has noticeable effects on its fluid flow pattern, in terms of pressure and velocity fields.     

Liver units in three dimensions: I. Organization of argyrophilic connective tissue skeleton in porcine liver with particular reference to the "compound hepatic lobule"

Liver units were investigated in pig livers by means of histologic serial tracing, physical model building, and computer-aided three-dimensional imaging. Observations of the argyrophilic connective tissue skeleton were based mainly on the celloidin-embedded serial sections treated with silver impregnation. The parenchymal mass that clothed the initial segments of hepatic venous radicles was demarcated by fibrous septa which formed isolable units with two basic patterns: the simple hepatic lobule (SHL) and the compound hepatic lobule (CHL). Both lobule types presented regular limiting structures circumscribing each unit. Three-dimensional studies revealed that 25% of the lobules in a section belonged to the SHL type and 75% to the CHL type, the latter being predominant among the surface lobules. When considered in only two dimensions, however, the SHL-like lobules constituted the majority. Polygonal analysis disclosed that the pentagonal lobule was the most typical, instead of the "hexagonal" or "classic" lobule. The CHLs represented a multiaxial unit containing a system of venous tributaries in accordance with intralobular septation, whereas the SHLs were found with one axial vessel having a dendritic tendency at the incipient end; some SHLs were drained eccentrically by separate vessels into a sublobular vein. It was observed that, in dividing CHLs, whereas particular sinosoids were transformed into portal twigs, other sinusoids were changed into central venous tributaries. Fibrous deposition occurred along the septal-line sinusoids, bringing into view the septum-initiating plane. Fibroconnective tissue was supplied from the portal area and central (sublobular) adventitia, where portal triad structures and adventitial arterioles, respectively, were included. The findings of the present study facilitate the understanding of several characters of the lobules that have been reported previously, or occasionally postulated, such as the portal-central bridging tendency, the intralobular arterioles or ductules, the translobular artery or portal vein, the "portal-portal" or "portal-central" anastomoses, and the apposition of pericentral zone close to periportal zone. Based on differences in argyrophilia of sinusoidal reticulum, in proportion of lobule types, and in vasculature, the anatomic heterogeneity of liver unit was demonstrable in zonality, regionality, and locality.     

Structural Changes in the Subcutaneous Compartment in Morbid Obesity

Most of the excess fat that accumulates in the morbidly obese is accommodated in the subcutaneous compartment (SCC), specifically in the adipose tissue lobules of the panniculus adiposus which enlarge and expand the SCC. However, the fibroelastic septa that are attached to the skin on one side of the SCC and to the deep fascia on the other invest each lobule and thereby offer resistance to the enlarging lobules. We report observations made during pathologic examinations of the abdominal wall SCC that were surgically excised by abdominal dermo-panniculectomy from 48 morbidly obese subjects afler gastroplasty and weight loss. Lobules were large but varied notably upwards in size and, to some extent, shape. Simultaneously upon incision of the SCC, the lobules bulged above and the septa retracted below the same cut surfaces. Light microscopy revealed disruptions of septal elastic fibers, calcification of septa and septal arteries and necrosis of adipocytes, all sparsely distributed. Certain questions and facts emerge from these observations. Are the variations in lobule sizes normal, or do they reflect uneven fat deposition or mobilization during weight gain or loss respectively? Is there any correlation between lobule and adipocyte sizes? The tightly coupled phenomena of lobule-bulging and septal-retraction indicate that the lobules and septa are subjected to compressional and tensile stresses respectively in the intact, non-incised SCC. The histologic changes might be consequences of these stresses. Studies of the variations in body fat distribution and in adipocyte size have contributed to an understanding of obesity pathogenesis. The relevance of the present fmdings is unknown at this time, but these appear to have potential implications for studies of the morphogenesis of obesity. Confirmation of these fmdings, particularly the lobule variations, is required so that these can be compared with those in never-obese subjects and in morbidly obese subjects without prior weight loss.     

Sertoli cells in the testis of caecilians, Ichthyophis tricolor and Uraeotyphlus cf. narayani (Amphibia: Gymnophiona): light and electron microscopic perspective

The caecilians have evolved a unique pattern of cystic spermatogenesis in which cysts representing different stages in spermatogenesis coexist in a testis lobule. We examined unsettled issues relating to the organization of the caecilian testis lobules, including the occurrence of a fatty matrix, the possibility of both peripheral and central Sertoli cells, the origin of Sertoli cells from follicular cells, and the disengagement of older Sertoli cells to become loose central Sertoli cells. We subjected the testis of Ichthyophis tricolor (Ichthyophiidae) and Uraeotyphlus cf. narayani (Uraeotyphliidae) from the Western Ghats of Kerala, India, to light and transmission electron microscopic studies. Irrespective of the functional state of the testis, whether active or regressed, Sertoli cells constitute a permanent feature of the lobules. The tall Sertoli cells adherent to the basal lamina with basally located pleomorphic nuclei extend deeper into the lobule to meet at the core. There they provide for association of germ cells at different stages of differentiation, an aspect that has earlier been misconceived as the fatty matrix. Germ cells up to the 4-cell stage remain in the intercalating region of the Sertoli cells and they are located at the apices of the Sertoli cells from the 8-cell stage onwards. The developing germ cells are intimately associated with the Sertoli cell adherent to the basal lamina until spermiation. There are ameboid cells in the core of the lobules that appear to interact with the germ cells at the face opposite to their attachment with the Sertoli cells. Adherence of the Sertoli cells to the basal lamina is a permanent feature of the caecilian testicular lobules. The ameboid cells in the core are neither Sertoli cells nor their degeneration products.     

Lobule shape evolution in Radula (Jungermanniopsida): one rate fits all?

The quantification of lobule shape for Radula spp. shows that there is overlap in lobule shape space occupied by subgenera, such that lobule shape does not always reflect relationships. Morphological convergence caused by lineages repeatedly traversing shared regions of morphospace appears commonplace in Radula, and means that many pairs of relatively unrelated species have similar lobule shapes. When observed over time, as in comparisons between fossil and extant species, this may give the impression of stasis if fossil species resemble modern species by chance, independent of their relatedness. This poses a challenge to relating fossils of known age to extant lineages, particularly when fossils are sterile. Significant rate variation between lineages was identified by Adams' Q‐mode analysis, with the fastest subgenus evolving 23 times more quickly than the slowest. Species of subgenus Volutoradula and subgenus Metaradula are apparently over‐dispersed throughout lobule morphospace according to Sidlauskas' method; morphometric branch lengths and hypervolumes in other subgenera can be explained by a stochastic process. In contrast, Bayesian analysis of macroevolutionary mixtures (BAMM) identified a single evolutionary rate as having the highest posterior probability. Consideration of the three independent accessions into auriculate lobule morphospace by Cladoradula and Radula, wherein convergent lobule shapes result from convergent lobule ontogenies and are correlated with bipinnately branched shoot systems and robust primary stems, leads to an ontogenetic hypothesis driven by structural requirements for light interception, under which auriculate lobules are a spandrel. It is speculated that lobules themselves, however, may be a key innovation facilitating radiation into microsites devoid of or depauperate in fungal endophytes. © 2015 The Linnean Society of London, Botanical Journal of the Linnean Society, 2015, 178 , 222–242.     

Eph receptors and ephrins demarcate cerebellar lobules before and during their formation.

The formation of the ten cerebellar lobules is an unsolved problem in brain development. We report a screen for the four subfamilies of Eph receptors and their ligands (ephrins) in developing mouse cerebellum, using soluble receptor-immunoglobulin and ligand-immunoglobulin fusion proteins, and antibodies against EphA and ephrin-B proteins. Our results identify Eph receptors and ephrins as the first molecules known to demarcate individual lobules during development. Staining for ephrin-A ligands is in lobule VIII as it forms, across the whole width of the cerebellum. Staining for three EphA receptors approximately coincides with presumptive lobules VI and/or VII before and just after birth, whereas a fourth EphA receptor (EphA4, which binds ligands of both subfamilies) has more widespread expression. Staining for EphB receptors is in lobules VII, VIII, and IX. Staining for ephrin-B ligands is much weaker, becomes detectable only after birth, and does not appear to be lobule-specific. Staining for all subfamilies spreads to at least some adjacent lobules as maturation proceeds. The lobule-specific patterns appear before the lobules form, and initially extend across the width of the cerebellum, in spite of the lesser conservation of the lateral extensions of the lobules. These expression patterns define previously unknown developmental units and suggest that Eph family proteins may contribute to cerebellar morphogenesis.     

Seasonal Changes in the Newt,Trituroides hongkongensis,Testis. II. An Ultrastructural Study on the Lobule Boundary Cell

An electron microscopical study was made on the lobule boundary cells. They were found to show characteristic ultrastructures of a typical steroid-producing cell. Changes in these cells were divided into five stages according to the development within the lobules. The possible significance of the changes and their correlation with the degree of steroid production at different stages are discussed.     

Cell Degeneration and Cavity Formation in the Endocrine Pancreas of the Hagfish Myxine glutinosa

Abstract Cell degeneration within the islet lobules of the pancreas of Myxine glutinosa appears to be a natural feature of the gland in this species. Degenerating cells bordering a lobule cavity discharge debris directly into the cavity, while cells undergoing degeneration at sites distant from such cavities discharge debris into the surrounding intercellular space. The latter process may well act as a locus for local degeneration within the lobule and the formation of a lobule cavity.     

Zonal plant communities of the Ribesalbes‐Alcora Basin (La Rinconada mine,eastern Spain) during the early Miocene

Changes in lobule morphology in Radula subgenus Cladoradula show liverworts have the capacity for dramatic, relatively rapid morphological change by heterochrony. In individuals of R. bipinnata, R. boryana and R. tenax, lobules on secondary and tertiary shoots are progenetic with respect to lobules on primary shoots, in that the slope of the relationship between growth duration and shape does not change. However, in R. campanigera, lobules on secondary and tertiary branches exhibit different slopes from primary branches, but have the same growth duration, a pattern consistent with neoteny. The trajectory of allometric growth is extended or truncated in different species compared with outgroup and ancestral nodes. Changes in duration of lobule growth explain 85% of variation in lobule shape between species. Species are related by relatively shallow nodes in the crown of the Radula subgenus Cladoradula clade, suggesting that divergence and associated heterochronic changes have occurred relatively recently. The rapid morphological diversification in the crown contrasts with the relative stasis between the ancestral node and R. brunnea, the outgroup used in this analysis. A robust primary axis may be required to hold shoots away from vertical surfaces to maximize light interception, and hypermorphosis in lobule ontogeny could be a by‐product of the longer growth durations required to build axes sufficiently large to perform this structural role. Alternatively, the large auriculate lobules could function in external water transport systems by providing continuity of surfaces for solute transport via capillary action. © 2013 The Linnean Society of London, Botanical Journal of the Linnean Society, 2013, 173 , 153–175.     

Intralobular Pulmonary Lymphatic Distribution in Normal Human Lung Using D2-40 Antipodoplanin Immunostaining

It has been assumed for a long time that except for limited areas close to respiratory bronchioles or their satellite arteries, there is no evidence of lymphatic vessels deep in the pulmonary lobule. An immunohistochemical study using the D2-40 monoclonal antibody was performed on normal pulmonary samples obtained from surgical specimens, with particular attention to the intralobular distribution of lymphatic vessels. This study demonstrated the presence of lymphatics not only in the connective tissue surrounding the respiratory bronchioles but also associated with intralobular arterioles and/or small veins even less than 50 μm in diameter. A few interlobular lymphatic vessels with a diameter ranging from 10 μm to 20 μm were also observed further away, in interalveolar walls. In conclusion, this study, using the D2-40 monoclonal antibody, demonstrated the presence of small lymphatic channels within the normal human pulmonary lobules, emerging from interalveolar interstitium, and around small blood vessels constituting the paraalveolar lymphatics. This thin intralobular lymphatic network may play a key pathophysiological role in a wide variety of alveolar and interstitial lung diseases and requires further investigation. (J Histochem Cytochem 57:643–648, 2009)     

Ecological characteristics of the structural organization of respiratory segments of the lung

The structure of the bronchial tree in the lung lobules has been studied and the number of lobules and acini in different lobes and in the entire lung has been determined in polar foxes and dogs. Branching pattern and the number of generations of interlobular and intralobular bronchioli have been defined. It has been found that the number of lung lobules in polar foxes was twice as high as in dogs, the lobule volume being smaller almost by half. A smaller number of acini in polar fox lobules enables the central regulation mechanisms to intensify the control of local ventilation. It broadens the possibilities for physiological responses to the influence of climatic factors of the Extreme North.     

The topographical localization of acetylcholinesterase in the adult rat cerebellum: A reappraisal

Summary The adult rat cerebellum has been investigated histochemically for acetylcholinesterase activity by the direct-coloring thiocholine technique. Results obtained are as follows:Staining indicative of sites of acetylcholinesterase (AChe) activity are predominantly delimited to the granular layer of the cerebellar cortex. The white matter directly adjacent to the granular layer of any lobule exhibit stronger activity than the medullary core. Often the molecular layer stain, diffusely and weakly.A great proportion of the enzyme staining is attributed to afferent mossy terminals. Golgi cells are also considered to possess intracellular AChe.Topographically, the vermian lobules of the cerebellum stain stronger relative to the hemispherical lobules except for the flocculus and paraflocculus. Mediolateral gradation of activity if present is not convincing. In the vermis, the lingula stains moderately. A distinctive feature of the present study is the enzyme activity in sub-lobuli VIb and VIc of the declive and the anterior portion of lobule VII. These areas stain densely and strongly. The nodule and lower part of the uvula exhibit dense and intense staining for AChe. All other lobules of the cerebellum stain weakly, more so those of the anterior lobe (besides the lingula).A rich core of AChe staining fibres radiate from the white matter adjacent to lobule X to reach lobules I, II, III, IV and V. A similarly intense core of AChe is found subjacent to the granular layer of lobules VI and VII.The three pairs of cerebellar peduncles stain differentially. Staining in the intracerebellar nuclei are however uniformly weak.The present findings are discussed as they relate to previous studies and in the light of current thoughts in cerebellar anatomy and function. Attention is drawn particularly to the functional implication of the dense and strong enzyme activity herein reported for the declive-tuber vermis complex of the cerebellum as these areas are believed to be sites of termination of cerebellar teleceptive inputs.     

The fine structure of the vertical lobe of octopus brain

Although much is known about the structural organization and connexions of the various lobes of the octopus brain from light microscopy, this is the first attempt at a detailed analysis of one of the lobes- the vertical lobe, with the electron microscope. The vertical lobe consists of five lobules. The median superior frontal (MSF) axons enter each lobule from the MSF lobe. The MSF axons contain both microtubules and neurofilaments. The varicosities of the MSF axons contain both agranular and dense-cored vesicles and synapse with trunks of the amacrine cells. These trunks run together in bundles termed amacrine tracts into the centres of the lobules. The amacrine trunks contain microtubules but no neurofilaments. The trunks contain large and small agranular synaptic vesicles and synapse with what are in all probability branches of the trunks of the large cells. These trunks contain microtubules but no neurofilaments. They run out through the bases of the lobules probably without forming synaptic contacts within the lobule. Fibres signalling 'pain' (nocifensor) enter the lobules from below. They can be recognized by their content of neurofilaments. Their terminals contain numerous very small synaptic vesicles and a few larger and dense-cored ones. These 'pain' fibres appear to synapse mostly with processes of the large cells. J. Z. Young has shown that the vertical lobe is especially concerned with the integrative action of the visual system, linked with the chemo-tactile system. Electron microscopy supports Young's suggestion that the superior frontal and interconnected vertical lobe systems constitute a loop which could sustain a positive feed-back mechanism (MSF -- amacrine -- large cell -- lateral superior frontal -- MSF) while the 'pain' (nocifensor) input could exert a suppressor (inhibitory) effect on the loop by its action on the large cells.     

The olivocerebellar projection to lobules I and II.

The olivocerebellar projection to lobules I and II was studied by means of retrograde transport from implants of the crystalline WGA-HRP complex. Retrogradely labelled neurons were found in the medial and dorsal accessory olives. Judged from the distribution of labelled cells, we conclude that parasagittally the olivocerebellar terminal zones A and B (i.e., the cerebellar cortical strips receiving axons from the olivary A and B regions) extend anteriorly into lobule Ia, whereas the fused olivocerebellar terminal C1/C3 zones reach lobule IIa. The olivocerebellar terminal C2 zone extends into lobule IIIa but not into lobule IIa. In lobule I the medial border of the B zone lies about 1 mm from the midline, in lobule II the B zone extends somewhat more medially. The lateral border of this zone is 1.9-2 mm from the midline. Compared to previous results, it appears that most of the Purkinje cells in lobule I projecting to the vestibular nuclei lie medially to the olivocerebellar terminal B zone.     

Mathematical modeling of the circulation in the liver lobule

In this paper, we develop a mathematical model of blood circulation in the liver lobule. We aim to find the pressure and flux distributions within a liver lobule. We also investigate the effects of changes in pressure that occur following a resection of part of the liver, which often leads to high pressure in the portal vein. The liver can be divided into functional units called lobules. Each lobule has a hexagonal cross-section, and we assume that its longitudinal extent is large compared with its width. We consider an infinite lattice of identical lobules and study the two-dimensional flow in the hexagonal cross-sections. We model the sinusoidal space as a porous medium, with blood entering from the portal tracts (located at each of the vertices of the cross-section of the lobule) and exiting via the centrilobular vein (located in the center of the cross-section). We first develop and solve an idealized mathematical model, treating the porous medium as rigid and isotropic and blood as a Newtonian fluid. The pressure drop across the lobule and the flux of blood through the lobule are proportional to one another. In spite of its simplicity, the model gives insight into the real pressure and velocity distribution in the lobule. We then consider three modifications of the model that are designed to make it more realistic. In the first modification, we account for the fact that the sinusoids tend to be preferentially aligned in the direction of the centrilobular vein by considering an anisotropic porous medium. In the second, we account more accurately for the true behavior of the blood by using a shear-thinning model. We show that both these modifications have a small quantitative effect on the behavior but no qualitative effect. The motivation for the final modification is to understand what happens either after a partial resection of the liver or after an implantation of a liver of small size. In these cases, the pressure is observed to rise significantly, which could cause deformation of the tissue. We show that including the effects of tissue compliance in the model means that the total blood flow increases more than linearly as the pressure rises.     

Protein malnutrition and response of pancreatic acinar cells to stimulation by cholecystokinin

Pancreatic lobules were isolated from 2 groups of male Wistar rats after 23 days of diet. A control group (C) fed on a 20% protein diet (16% gluten + 4% casein) and an experimental group (E) on a 5% protein diet (4% gluten + 1% casein). After isolation, lobules were preincubated 10 min with 10 muCi [3H]-leucine, washed, then incubate within Krebs Ringer bicarbonate Hepes. Basal secretion, then stimulated secretion (50 pM of cholecystokinin (CCK] of radioactive and non-radioactive protein and amylase outputs were measured. During basal secretion, in (E) group, lobules secreted more proteins than (C) one, the same outputs of amylase and radioactive protein were observed in both groups. The stimulated secretion by CCK increased the outputs of non-radioactive protein and amylase of lobules (T) (2-3 fold), but was without effect on lobule (E) outputs. Therefore, a low-protein diet involved a decrease of CCK sensibility on acinar cells, this fact might be mediated by a decreasing number and/or affinity of their CCK receptors.     

四川短尾鼩肝脏和胰腺的组织解剖学研究

对四川短尾鼩肝脏和胰腺的组织解剖结构进行了研究,结果表明:肝脏分为4叶,它们的肝实质完全分开.肝小叶的分界极不明显,1个肝小叶内的肝细胞大小不一致,靠近中央静脉的肝细胞体积较小,而肝小叶外围的肝细胞体积较大.胰腺的形态松散,无法区分出胰头、胰体和胰尾.胰腺小叶非常明显,大小不等.胰腺的组织结构包括外分泌部和胰岛两部分.     

Heterogeneous distribution of plasma membrane glycoconjugates in pancreatic acinar cells

Flow-cytometric studies of lectin binding to individual acinar cells have been carried out in order to analyse the distribution of membrane glycoconjugates in cells from different areas of the pancreas: duodenal lobule (head) and splenic lobule (body and tail). The following fluoresceinated lectins were used: wheat germ agglutinin (WGA), Tetragonolobus purpureus agglutinin (TP) and concanavalin A (Con A), which specifically bind to N-acetyl D-glucosamine and sialic acid, L-fucose and D-mannose, respectively. In both pancreatic areas, two cell populations (R1 and R2) were identified according to the forward scatter (size). On the basis of their glycoconjugate pattern, R1 cells displayed higher density of WGA and TP receptors than R2 cells throughout the pancreas. Although no difference in size was found between the cells from duodenal and splenic lobules, N-acetyl D-glucosamine and/or sialic acid and L-fucose residues were more abundant in plasma membrane cell glycoconjugates from the duodenal lobule. The results provide evidence for biochemical heterogeneity among individual pancreatic cells according to the distribution of plasma membrane glycoconjugates.