Absorption from the peritoneal cavity: SEM study of the mesothelium covering the peritoneal surface of the muscular portion of the diaphragm.

Colored tracers, injected intraperitoneally in mice, are taken up by diaphragmatic lymphatics, outlining their large, terminal cisterns, the so-called lacunae. The lacunae occur exclusively on the muscular portion of the diaphragm. The mesothelium covering non-lacunar and lacunar areas of the muscular portion was examined with the SEM. Mesothelial cells overlying non-lacunar areas are extremely flat, and their boundaries are indistinct. Mesothelial cells overlying lacunae protrude towards the lumen of the peritoneal cavity and have distinct outlines. There are openings or stomata, 4-12 micron in diameter, between them. Some of the stomata overlie a deep pit; others overlie a shallower pit in which the surface of another cell can be seen beneath the opening. It seems likely that the bulk of the fluid draining from the peritoneal cavity passes through these stomata into underlying lymphatic lacunae.     

小鼠膈腹膜淋巴孔和膈淋巴管的发育

应用透射电镜、扫描电镜和酶组织化学方法,研究胚胎期和出生后不同时期小鼠膈腹膜淋巴孔（PLS）和膈淋巴管的发生和发育,并用Elescope计算机图像处理技术对PLS进行定量分析。结果发现：胚胎13天时,膈腹膜仅由扁平形间皮细胞（FMC）组成;胚胎15天时,FMC间出现立方形间皮细胞（CMC）和早期腹膜淋巴孔（NLS）;胚胎18天时,膈毛细淋巴管出现,台盼蓝吸收试验显示NLS无物质吸收功能;出生后1天（PND1）,膈毛细淋巴管内皮细胞向PLS伸出胞质突起,并横跨CMC下结缔组织纤维和基底膜,形成腹膜下小管。后者与PLS沟通,建立了腹膜腔内物质转归通路。台盼蓝吸收试验表明,出生后PLS具有物质吸收功能,即为成熟腹膜淋巴孔（MLS）。PND5,立方细胞嵴（CMCR）发生,膈毛细淋巴管数量增多。PND10,大量立方细胞嵴融合,形成条带状分布的立方细胞区域,其上分布有大量MLS。随着发育进展,MLS平均面积和平均分布密度逐渐增大,且随着膈淋巴管的发育,吸收功能逐渐增强。     

Study on the ultrastructure of the peritoneal stomata in humans.

In 16 human specimens the topography and organization of stomata and mesothelial cells of the diaphragmatic, pelvic wall and anterior abdominal wall peritoneum were studied by transmission electron microscopy, scanning electron microscopy and the image processing technique. The mesothelial cells were organized into two discrete populations, cuboidal cells and flattened cells. The stomata were found only among cuboidal cells, either on the muscular portion or on the tendinous portion of the diaphragm. The size and shape of stomata, which were arranged in a cluster or a strip, were often irregular. The average area of a stoma on the muscular portion was 10.43 +/- 1.61 microns2, on the tendinous portion 7.93 +/- 1.67 microns2. Stomata opened to submesothelial connective tissue, under which numerous lymphatics were observed. Stomata were not discovered in the pelvic and anterior abdominal wall peritoneum. In animal experiments intraperitoneally injected trypan blue particles were rapidly removed from the peritoneal cavity through stomata of the diaphragmatic peritoneum in rabbits. It is suggested that stomata may be the main pathway for draining matter from the peritoneal cavity and that the diaphragmatic peritoneum shows the strongest absorption in all parts of the peritoneum.     

Functional arrangement of rat diaphragmatic initial lymphatic network

Fluid and solute flux between the pleural and peritoneal cavities, although never documented under physiological conditions, might play a relevant role in pathological conditions associated with the development of ascitis and pleural effusion and/or in the processes of tumor dissemination. To verify whether a pleuroperitoneal flux might take place through the diaphragmatic lymphatic network, the transdiaphragmatic pressure gradient (Delta P(TD)) was measured in five spontaneously breathing anesthetized rats. Delta P(TD) was -1.93 cmH2O (SD 0.59) and -3.1 cmH2O (SD 0.82) at end expiration and at end inspiration, respectively, indicating the existence of a pressure gradient directed from the abdominal to the pleural cavity. Morphometrical analysis of the diaphragmatic lymphatic network was performed in the excised diaphragm of three additional rats euthanized with an anesthesia overdose. Optical and electron microscopy revealed that lymphatic submesothelial lacunae and lymphatic capillaries among the skeletal muscles fibers show the ultrastructural features of the so-called initial lymphatic vessels, namely, a discontinuous basal lamina and anchoring filaments linking the outer surface of the endothelial cells to connective tissue or to muscle fibers. Primary unidirectional valves in the wall of the initial lymphatics allow entrance of serosal fluid into the lymphatic network preventing fluid backflow, while unidirectional intraluminar valves in the transverse vessels convey lymph centripetally toward central collecting ducts. The complexity and anatomical arrangement of the two valves system suggests that, despite the existence of a favorable Delta P(TD), in the physiological condition no fluid bulk flow takes place between the pleural and peritoneal cavity through the diaphragmatic lymphatic network.     

Postnatal development of the ovarian bursa of the golden hamster (Mesocricetus auratus): its complete closure and morphogenesis of lymphatic stomata

The golden hamster ovarian bursa was studied by light and electron microscopy to clarify the process of its complete closure and the development of lymphatics that leads to morphogenesis of stomata. The results were as follows. 1) The bursa completely closed at 9 days of age primarily due to development of the mesotubarium superius. 2) With the closure, the ovary and bursa became closely apposed, and most of the original bursal cavity disappeared. 3) Between 9 and 12 days of age U-shaped folds of the bursal mesothelium began to invade the connective tissue of the bursa. 4) Widening of the internal angle of the U-shaped folds contributed to reappearance of the bursal cavity, and thus separation of the bursa from the ovary. It also contributed to future geometrical proximity of lymphatics to the cavity of the bursa. 5) The separation of the bursa from the ovary began as early as 12 days of age in the cephalic half of the bursa. It occurred remarkably late in the caudal half. Juxtaposition of the window portion of the bursa to the ovary remained in some adult animals. 6) Development of lymphatics in the cephalic half of the bursa was divided into two stages, before and after days 21-24 of life. In the first stage, lymphatics grew in the submesothelial connective tissue, and the framework of lymphatics was formed. In the second stage, lymphatics extended small branches to form the submesothelial plexus or lymphatic lacuna. 7) Intercellular junctions between contiguous lymphatic endothelial cells were mostly tight and desmosomelike. Open junctions were, if they occurred at all, rare. (8) A smooth-surfaced area lined with the lymphatic endothelium was found in the bursa on day 27 of life, before the initiation of ovulation. Valvelike stomal orifices were absent before the initiation of ovulation and extremely rare even after the first ovulation. They were commonly present in the bursae after the fourth ovulation, however. The process of complete closure of the ovarian bursa is very complex and may be related to the later development of the bursal mesothelium and lymphatics. Some liplike stomal orifices are of purely developmental origin. However, all valvelike stomal orifices are assumed to be formed as a result of damage to the bursal mesothelium, as well as to the submesothelial connective tissue and lymphatics, by repetition of ovulation. It is possible that liplike stomal orifices may be formed in the process of repairing the damage.     

Immunohistochemical localisation of ET-1 and eNOS in lymphatic stomata of the porcine broad ligament of the uterus

Immunohistochemical localization and distribution of endothelin (ET-1) and nitric oxide synthase (eNOS) were investigated in lymphatic stomata in areas of their special accumulation in the porcine broad ligament during the estrous cycle. The study was performed using polyclonal antibody for ET-1 and monoclonal antibody for eNOS. ET-1 and eNOS immunoreactivities were demonstrated in some thin endothelial lymphatic lacuna walls throughout the estrous cycle. In the mesothelial cell layer, ET-1 and eNOS were detected only in stomata-related cuboidal mesothelial cells, however, the intensity of the immunostaining and distribution of the positive cells varied during the cycle. These results suggest that ET-1 and eNOS can play a role in mechanisms regulating the tone of lymphatic stomata during the absorption and passage of fluids, particles and cells from the peritoneal cavity to lymphatic vessels in the porcine broad ligament.     

Distribution of diaphragmatic lymphatic lacunae.

The morphology of the submesothelial lymphatic lacunae on the pleural and peritoneal surface over the tendinous and muscular portion of the diaphragm was studied in 10 anesthetized rabbits. The lymphatic network was evidenced by injecting 1 ml of colloidal carbon solution in the pleural (n = 5) or the peritoneal (n = 5) space. After 1 h of spontaneous breathing, the animal was killed and the diaphragm was fixed in situ by injection of approximately 5 ml of fixative in pleural and peritoneal spaces. Then both cavities were opened and the diaphragm was excised and pinned to a support. According to which cavity had received the injection, the peritoneal or the pleural side of the diaphragm was scanned by sequential imaging of the whole surface by use of a video camera connected to a stereomicroscope and to a video monitor. The anatomic design appeared as a network of lacunae running either parallel or perpendicular to the major axis of the tendinous or muscular fibers. The lacunae were more densely distributed on the tendinous peritoneal area than on the pleural one. Scanty lacunae were seen on the muscular regions of both diaphragmatic sides, characterized by large areas without lacunae. The average density of lacunae on tendinous and muscular regions was 6 and 1.7/cm2 for the pleural side and 25 and 3.4/cm2 for the peritoneal side, respectively. The average width of lacunae was 137.9 +/- 1.6 and 108.8 +/- 1.7 microns on the tendinous pleural and the peritoneal side, respectively, and 163 +/- 1.8 microns on the muscular portion of the pleural and peritoneal surfaces.     

Electronmicroscopic observations on the visceral and parietal rat's pleura after contralateral pneumonectomy

The mechanism of compensatory growth and healing of the pleura remains unresolved. Contralateral visceral and parietal (diaphragmatic and costal) pleura were investigated by transmission electron microscopy, following an experimental pneumonectomy (EP). Fifteen young-adult Wistar rats were divided into three groups and with survival times of 1, 5 and 8 days respectively after EP. Three sham-operated (thoracic cavity opened and closed) and three unoperated rats served as controls. One day following EP the superficial mesothelial cells have more microvilli and microvesicles, but a lower number of specialized contacts. Multiplication of extravasal cells leads to an increase of the thickness of the layer over the basal lamina and of the submesothelial layer. Five days after EP the superficial cells show a stratified arrangement in longer sectors of both pleural sheets. Along with typical mesothelial cells there are three new populations of cells: (1) with an abundant granular endoplasmic reticulum and secretory granules, (2) with fibroblast-like characteristics and (3) with a more extensive lysosomal system. The submesothelial layer is thickened due to newly formed blood vessels and collagen bundles. Eight days after EP the mesothelial cells build multi-row arrangement sectors and surround intercellular dilatations covered with microvilli. 'Activated' high mesothelial cells characterize the monolayer sectors. The submesothelial layer remains thicker due to larger collagen bundles and elastic fibers. The changes in the mesothelium and in the connective tissue layer suggest the existence of two periods. The first one is characterized by different mesothelial cell populations, new vasculogenesis and starting of fibrillogenesis. In the second period there are 'activated' mesothelial cells, pleural villi, groups of lymphatic lacunae and significant fibrillogenesis.     

Penetration of an ascitic reticulum cell sarcoma of the golden hampster into the body wall and through the diaphragm. A scanning electron microscopic (SEM) study.

SEM studies on infiltration of the ascitic form of the hamster reticulum cell sarcoma HaTu 25 into the ventral body wall and through the diaphragm were performed during 6 consecutive days after intraperitoneal transplantation. The findings allow an interpretation of the course of events based on 3 main stages: 1) Contraction of mesothelial cells with partial exposure of the submesothelial stratum. 2) Preferential attachment of tumor cells to these denuded areas. 3) Advance of tumor cells within defects gradually extening from the submesothelial stratum of the musculature. These stages were more pronounced and took a more rapid course at the peritoneal side of the diaphragm than at the body wall. At the pleural side of the diaphragm the appearance of single tumor cells within widened intercellular spaces of the mesothelium was recorded prior to the onset of penetration at the peritoneal surface. The rapid migration of tumor cells through the diaphragm as well as the particularly intensive tumor infiltration into this organ is thought to be connected with the mechanism of intravasation of tumor cells into the lymphatic plexus of the diaphragm. During the whole sequence of events, HaTu 25 cells were found to have maintained their spherical configuration and characteristic surface architecture. Apparently, growth pressure is of minor or no importance in this spacial mode of tumor penetration, rather the action of proteolytic enzymes elaborated by the tumor cells has to be taken into consideration.     

The ultrastructure of the peritoneal membrane in chronically dialysed rats with spontaneous peritonitis: preliminary observations

In this paper we describe ultrastructure of the peritoneal membrane from single peritoneal biopsies collected from chronically dialysed rats with spontaneous peritonitis. The results were compared with those obtained in chronically dialysed animals without peritonitis. In rats with peritonitis, peritoneum was much thicker than in peritonitis-free animals. The increased thickness of the peritoneum during peritonitis was due to infiltration of the submesothelial tissue with oedematous fluid and to the presence of huge amount of cells in the stroma. The connective tissue cells were accumulated just underneath the peritoneal surface. In deeper parts of the interstitium, infiltrating acute inflammatory cells were present (lymphocytes, polymorphonuclear cells: neutrophils and eosinophils). Inversely, the increased thickness of the peritoneum in peritonitis-free animals was mainly due to enhanced amounts of collagen. Additionally, in rats with peritonitis, the surface was often denuded of mesothelial cells. The damaged mesothelial cells that detached from the peritoneal surface were also found. In conclusion, the morphological changes observed in rats with peritonitis are similar to those reported in humans, thus the model of peritonitis in dialysed rats can be used for the study of peritoneal remodeling during peritoneal dialysis complicated by peritonitis.     

腹膜淋巴孔与淋巴转归NO-cGMP-Ca2+信号转导途径研究

为研究一氧化氮(nitric oxide,NO)调节大鼠腹膜淋巴孔和淋巴吸收的细胞内信号转导机制,在体外培养的间皮细胞上,利用cGMP检测试剂盒和激光共聚焦扫描显微镜,研究NO对间皮细胞内cGMP和游离钙离子浓度(Ca^2 )的影响;并利用动物实验研究NO-cGMP-Ca^2 通路对大鼠腹膜淋巴孔和淋巴吸收的影响。结果发现：(1)与对照组相比,NO供体Sper NO （spermine／nitric oxide complex)可以剂量依赖性地升高间皮细胞内cGMP的浓度(P＜0．01)。此作用可被可溶性鸟苷酸环化酶(soluble guanylyl cyclase,sGC)特异性抑制剂1H-[1,2,4]噁二唑[4．3-a]喹喔啉-1-one酮(1H-[1,2,4]oxadiazolo[4,3-a]quinoxalin-1-one,ODQ)阻断(P＜0．05,P＜0．01)。Sper／NO可使间皮细胞内[Ca^2 ],相对水平降低(P＜0．05),但此效应可被ODQ阻断;L-型电压依赖性钙通道阻滞剂nifedipine,可使细胞内的[Ca^2 ];在短时间内迅速明显下降(P＜0．05),达平衡后再加入Sper／NO并不能引起[Ca^2 ];的进一步改变(P＞0．05);(2)NO可以剂量依赖性地提高大鼠膈组织淋巴孔最大分布面积(P＜0．01)和对示踪剂的吸收量(P＜0．05),ODQ可明显抑制NO引起的淋巴孔和淋巴吸收的改变(P＜0．01)。该结果首次发现nifedipine能显著增加淋巴孔最大分布面积(P＜0．01)及膈组织对台盼蓝的吸收量(P＜O．05),而且nifedipine预处理后Sper／NO并不能使淋巴孔的淋巴吸收进一步升高(P＞0．05)。结果提示,NO可以通过降低cGMP水平降低大鼠腹膜间皮[Ca^2 ],且此过程和L-型电压依赖性钙通道有关;NO可通过NO-cGMP-[Ca^2 ],通路,促进淋巴孔的开放和吸收。     

A Model for Fluid Drainage by the Lymphatic System

This study investigates the fluid flow through tissues where lymphatic drainage occurs. Lymphatic drainage requires the use of two valve systems, primary and secondary. Primary valves are located in the initial lymphatics. Overlapping endothelial cells around the circumferential lining of lymphatic capillaries are presumed to act as a unidirectional valve system. Secondary valves are located in the lumen of the collecting lymphatics and act as another unidirectional valve system; these are well studied in contrast to primary valves. We propose a model for the drainage of fluid by the lymphatic system that includes the primary valve system. The analysis in this work incorporates the mechanics of the primary lymphatic valves as well as the fluid flow through the interstitium and that through the walls of the blood capillaries. The model predicts a piecewise linear relation between the drainage flux and the pressure difference between the blood and lymphatic capillaries. The model describes a permeable membrane around a blood capillary, an elastic primary lymphatic valve and the interstitium lying between the two.     

The ultrastructure of the peritoneal membrane in chronically dialysed rats

The model to estimate peritoneal function in chronically dialysed rats was previously presented by us. The aim of the paper is to report the findings obtained in electron microscopy of peritoneal biopsies from Wistar rats dialysed for 1 month with high glucose dialysis solution. In control animals, thin mesothelial cells were covered with microvilli. The submesothelial tissue was composed of sparse bundles of parallelly oriented collagen fibers with a few resting cells. In chronically dialysed rats, mesothelial cell layer was thicker and cells were fully packed with intracellular structures, mainly secretory granules with a homogeneous content. The submesothelial tissue was expanded due to the increased amount of collagen fibers, oedema and increased amount of submesothelial cells which were activated. The use of electron microscopy to study the peritoneum in dialysed rats is an excellent supplement to the chronic functional model of peritoneal dialysis in rats.     

A model for mechanics of primary lymphatic valves

Recent experimental evidence indicates that lymphatics have two valve systems, a set of primary valves in the wall of the endothelial cells of initial lymphatics and a secondary valve system in the lumen of the lymphatics. While the intralymphatic secondary valves are well described, no analysis of the primary valves is available. We propose a model for primary lymphatics valves at the junctions between lymphatic endothelial cells. The model consists of two overlapping endothelial extensions at a cell junction in the initial lymphatics. One cell extension is firmly attached to the adjacent connective tissue while the other cell extension is not attached to the interstitial collagen. It is free to bend into the lumen of the lymphatic when the lymphatic pressure falls below the adjacent interstitial fluid pressure. Thereby the cell junction opens a gap permitting entry of interstitial fluid into the lymphatic lumen. When the lymphatic fluid pressure rises above the adjacent interstitial fluid pressure, the endothelial extensions contact each other and the junction is closed preventing fluid reflow into the interstitial space. The model illustrates the mechanics of valve action and provides the first time a rational analysis of the mechanisms underlying fluid collection in the initial lymphatics and lymph transport in the microcirculation.     

Kinetics of fluid flux in the rat diaphragmatic submesothelial lymphatic lacunae

The specific role of loops and/or linear segments in pleural diaphragmatic submesothelial lymphatics was investigated in seven anesthetized, paralyzed, and mechanically ventilated rats. Lymphatic loops lay peripherally above the diaphragmatic muscular plane, whereas linear vessels run over both the muscular and central tendineous regions. Lymph vessel diameter, measured by automatic software analysis, was significantly greater (P < 0.01) in linear vessels [103.4 +/- 8.5 microm (mean +/- SE), n = 18] than in loops (54.6 +/- 3.3 microm, n = 21). Conversely, the geometric mean of intraluminal flow velocity, obtained from the speed of distribution of a bolus of fluorescent dextrans injected into the vessel, was lower (P < 0.01) in linear vessels (26.3 +/- 1.4 microm/s) compared with loops (51.3 +/- 3.2 microm/s). Lymph flow, calculated as the product of flow velocity by vessel cross-sectional area, was similar in linear vessels and in individual vessels of a loop, averaging 8.6 +/- 1.6 nl/min. Flow was always directed from the diaphragm periphery toward the medial tendineous region in linear vessels, whereas it was more complex and evidently controlled by intraluminal unidirectional valves in loops. The results suggest that loops might be the preferential site of lymph formation, whereas linear vessels would be mainly involved in the progression of newly formed lymph toward deeper collecting diaphragmatic ducts. Within the same hierarchic order of diaphragmatic lymphatic vessels, the spatial organization and geometrical arrangement of the submesothelial lacunae seem to be finalized at exploiting the alternate contraction/relaxation phases of diaphragmatic muscle fibers to optimize fluid removal from serosal cavities.     

Lymphatic lacunae of the human eye conjunctiva embedded within a stroma containing CD34+ telocytes

An accurate identification of telocytes (TCs) was limited because of the heterogeneity of cell types expressing the markers attributed to TCs. Some endothelial lineage cells also could fit within the pattern of TCs. Such endothelial cells could line conjunctival lacunae previously assessed by laser confocal microscopy. We have been suggested that an accurate distinction of TCs from endothelial cells in the human eye conjunctiva could be achieved by use of CD31, CD34 and D2‐40 (podoplanin); and that the conjunctival lacunae are in fact lymphatic. We aimed as testing the hypothesis by an immunohistochemical study on human eye conjunctiva biopsy samples. Samples of human eye conjunctiva from 30 patients were evaluated immunohistochemically by use of the primary antibodies: CD34, D2‐40 and CD31. D2‐40 was equally expressed within epithelia and laminae propria. Basal epithelial cells were D2‐40 positive. Within the stromal compartment, the lymphatic marker D2‐40 labelled several lymphatic vessels. CD31 labelled both vascular and lymphatic endothelial cells within the lamina propria. When capillary lymphatics were tangentially cut, they gave the false appearance of telocytes. Blood endothelial cells expressed CD34, whereas lymphatic endothelial cells did not. Stromal CD34‐expressing cells/telocytes were found building a consistent pan‐stromal network which was equally CD31‐negative and D2‐40‐negative. The conjunctival lymphatic lacunae seem to represent a peculiar anatomic feature of eye conjunctiva. They are embedded within a CD34‐expressing stromal network of TCs. The negative expression of CD31 and D2‐40 should be tested when discriminating CD34‐expressing TCs.     

A scanning electron microscope study of mouse peritoneal mesothelium.

As seen in the scanning electron microscope, peritoneal mesothelial cells of the mouse diaphragm, anterior abdominal wall and intestinal serosa carry numerous microvilli. These microvilli are absent over certain areas of the cell surface and are sometimes, interlocked in meshwork patterns or coronal formation. The apical cell membranes of the mesothelium at the base of the microvilli, are invaginated by many plasmalemmal vesicles and vacuoles and carry a number of protruding spherical structures. Deep circular craters, giving the impression of stomata, are also visible.     

Peritoneal fine structure of inguinal hernia: a transmission electron microscope study.

Fine structure of normal human parietal peritoneum served as control data for recording changes in the fine structure of the peritoneum of hernial sacs. In these sacs, mesothelial cells retracted, rounded up and some of them eventually separated altogether to give rise to wide open intercellular spaces thus creating unhindered passageways (stomata) between the subserosal connective tissue and the cavity of the sacs. There was a considerable collagen build-up in the subserosal fibrous tissue of hernial sacs. Occurrence of this fibrosis is at variance with an accepted surgical concept which suggests a defect in collagen synthesis as the cause of herniation. In some sacs mesothelial nodules and/or peritoneal adhesions were present. Certain cytological changes in the mesothelial cells of hernial sacs showed features in common with cells of malignant tumours in general, and features mimicking malignant mesotheliomas in particular. This is in spite of the fact that thorough gross and light microscopic examination of operative specimens and cytological evaluation of peritoneal effusion failed to reveal any evidence of malignancy. Pathologists should be aware of the consummate ability of mesothelial cells to mimic carcinomas in order to avoid possible diagnostic errors. In this report, an electron micrograph of peritoneal adhesion is being published for the first time in the literature. A syncytium-like firm bond between adjoining mesothelial cells constituted the adhesion which is obviously an irreversible process.     

The granulomatous inflammatory response in jirds, Meriones unguiculatus, to Brugia pahangi: an ultrastructural and histochemical comparison of the reaction in the lymphatics and peritoneal cavity

A granulomatous inflammatory response develops in jirds with lymphatic or intraperitoneal infections of Brugia pahangi. Light, histochemical, and ultrastructural microscopy were used for comparative studies of the reactions in these 2 locations. The reactions observed were categorized into 3 types: (1) an initial response in which lymphocytes, monocytes, macrophages, and eosinophils were present; (2) an intermediate one which consisted of macrophages, epithelioid cells, lymphocytes, eosinophils, collagen, and mesothelial/endothelial cells with central areas of necrosis; and (3) a terminal reaction consisting of degenerating, necrotic cells. Microfilariae and adult worms were associated with these reactions. Macrophages were the predominant cell type in the lesion and were often found attached to the surface of the parasite. The inflammatory responses to B. pahangi in the lymphatics and in the peritoneal cavity appear to be similar, and thus, the peritoneal cavity may be useful in studying specific cell-parasite interactions to further define the pathogenesis of filarial disease.     

Three-dimensional organization of lymphatics and its relationship to blood vessels in rat small intestine

Summary The lymphatic organization and its relationship to the vascular system in the rat small intestine was studied by scanning electron microscopy of corrosion casts and freeze-fractured tissues, and by light microscopy of injected preparations. The villus possessed 3–10 or more central lacteals depending upon the villous width. The lacteals in each villus possessed interconnections between adjacent ones and were surrounded externally by the villous capillary network. At the villous base, the lacteals fused and formed a wide sinus, from which 2 or 3 lymphatics descended and led into the submucosal ones. In the muscularis externa there was a coarse lymphatic network which, together with the submucosal one, drained into collecting lymphatics continuous with the mesenteric ones. The central lacteals and the sinus were lined with thin endothelial cells with cytoplasmic leaves interdigitating with those of adjacent ones. There were tissue channels in the villous interstitial space, which opened through the gaps between the lymphatic endothelial cells into the central lacteals.The voluminous lacteals in the villi suggest their great potential for lymph formation. The existence of collecting lymphatics with valves in the muscularis externa suggests that contraction of the layer is involved in transporting lymph towards the efferent lymphatics.