2D/3D hybrid structural model of vocal folds

The spatial dimensionality of the vocal fold vibration is a common challenge in creating parsimonious models of vocal fold vibration. The ideal model is one that is accurate, with the lowest possible computational expense. Inclusion of full 3D flow and structural vibration typically requires massive amounts of computation, whereas reduction of either the flow or the structure to two dimensions eliminates certain aspects of physical reality, thus making the resulting models less accurate. Previous 2D models of the vocal fold structure have utilized a plane strain formulation, which is shown to be an erroneous modeling approach since it ignores influential stress components. We herein present a 2D/3D hybrid vocal fold model that preserves three-dimensional effects of length and longitudinal shear stresses, while taking advantage of a two-dimensional computational domain. The resulting model exhibits static and dynamic responses comparable to a 3D model, and retains the computational advantage of a two-dimensional model.     

Permeability characteristics of cultured endothelial cell monolayers

The purpose of this study was to characterize the permeability characteristics of an in vitro endothelial cell monolayer system and relate this information to available in vivo data. We cultured bovine fetal aortic endothelial cells on fibronectin-coated polycarbonate filters and confirmed that our system was similar to others in the literature with regard to morphological appearance, transendothelial electrical resistance, and the permeability coefficient for albumin. We then compared our system with in vivo endothelium by studying the movement of neutral and negatively charged radiolabeled dextran tracers across the monolayer and by using electron microscopy to follow the pathways taken by native ferritin. There were a number of differences. The permeability of our monolayer was 10-100 times greater than seen in intact endothelium, there was no evidence of "restricted" diffusion or charge selectivity, and ferritin was able to move freely into the subendothelial space. The reason for these differences appeared to be small (0.5-2.0 micron) gaps between 5 and 10% of the endothelial cells. Although the current use of cultured endothelial cells on porous supports may provide useful information about the interaction of macromolecules with the endothelium, there appear to be differences in the transendothelial permeability characteristics of these models and in vivo blood vessels.     

Tilapia mast cell lysates enhance neutrophil adhesion to cultured vascular endothelial cells

The possible role of fish mast cells in regulating neutrophil adhesion to vascular endothelial cells was studied using primary cultures of tilapia vascular endothelial cells. The endothelial cell monolayer, which was cultured in 96 well plates, was stimulated for appropriate periods with tilapia mast cell (tMC)-lysates or with Leibovitz-15 (L-15) medium, as a control, and peripheral neutrophils were added into each well after removal of the lysates. After 30 min incubation, cells in the wells were fixed with formalin and non-adherent neutrophils were removed. The cells were stained with Giemsa and neutrophil adhesion was observed microscopically. Although some neutrophils attached to the endothelial cells without stimulation, neutrophil adhesion was enhanced after the incubation of the endothelial cells with tMC-lysates. Neutrophil adhesion was maximal 6 h after the lysate stimulation, with a six-fold increase compared to the control. Neutrophil adhesion also increased when the endothelial cells were stimulated with neutrophil lysates, lipopolysaccharide and zymosan-treated tilapia sera. These results indicate that fish vascular endothelial cells express some neutrophil adhesion molecule(s) after stimulation with various substances.     

Plasma membrane topography governs the 3D dynamic localization of IgM B cell antigen receptor clusters

B lymphocytes recognize bacterial or viral antigens via different classes of the B cell antigen receptor (BCR). Protrusive structures termed microvilli cover lymphocyte surfaces, and are thought to perform sensory functions in screening antigen‐bearing surfaces. Here, we have used lattice light‐sheet microscopy in combination with tailored custom‐built 4D image analysis to study the cell‐surface topography of B cells of the Ramos Burkitt''s Lymphoma line and the spatiotemporal organization of the IgM‐BCR. Ramos B‐cell surfaces were found to form dynamic networks of elevated ridges bridging individual microvilli. A fraction of membrane‐localized IgM‐BCR was found in clusters, which were mainly associated with the ridges and the microvilli. The dynamic ridge‐network organization and the IgM‐BCR cluster mobility were linked, and both were controlled by Arp2/3 complex activity. Our results suggest that dynamic topographical features of the cell surface govern the localization and transport of IgM‐BCR clusters to facilitate antigen screening by B cells.     

Properties of endothelial cell and smooth muscle cell cultured in ambient pressure

Summary Cultures of umbilical vein endothelial cells and smooth muscle cells were studied in a constant pressure chamber. The following results were obtained: (a) Endothelial cell growth was maximal at 80 mmHg and minimal at 0 mmHg (atmospheric pressure) for the first 2 d of incubation. However, these growth rates were reversed during the following 6 d because of steady increase in growth at 0 mm Hg and a decrease in growth at higher pressures. A degeneration of endothelial cells began at 120 mmHg and marked degeneration was noted at 160 mmHg. Growth of Smooth muscle cells was not influenced by ambient pressure and a steady increase in labeled nuclei continued throughout the period of culture. (b) Elastin, stainable with tannic acid, was noted electronmicroscopically in both endothelial and smooth muscle cells. (c) Production of prostacyclin by endothelial cells was maximal at 0 mmHg and minimal at 80 mmHg, in contrast to the growth pattern of these cells. Production of thromboxane B₂ by endothelial cells and prostacyclin and thromboxane B₂ by smooth muscle cells was very slight and not significantly different. Although it is not known at present what mechanism acts on the vascular cells when cultured in ambient pressure, these results may indicate a new concept of the behavioral relationship between endothelial cell, smooth muscle cell, and blood pressure in vivo.     

Ascorbic acid stimulates barrier function of cultured endothelial cell monolayer

The macromolecular permeability of cultured bovine aortic, bovine venous, and human umbilical vein endothelial cell monolayers was decreased significantly in culture medium containing L-ascorbic acid (Asc Acid; 0.01–0.1 mM) and L-ascorbic acid 2-phosphate (Asc 2-P). Dithiothreitol, which shows reducing activity equivalent to that of Asc Acid, did not affect endothelial permeability. Asc Acid induced a sixfold increase in collagen synthesis by the endothelial cells. The coexistence of L-azetidine 2-carboxylic acid, an inhibitor of collagen synthesis, attenuated the effect of Asc 2-P in a dose-dependent manner. Another collagen synthesis inhibitor, ethyl-3,4-dihydroxybenzoate, also inhibited collagen synthesis and increased endothelial permeability. The decrease in permeability of the endothelial monolayer was dependent on a reduction of the permeability coefficient of the endothelial monolayer. These findings indicate that endothelial barrier function is stimulated by Asc Acid via an increase in collagen synthesis. © 1995 Wiley-Liss, Inc.     

Effects of pulsatile flow on cultured vascular endothelial cell morphology

Endothelial cells (EC) appear to adapt their morphology and function to the in vivo hemodynamic environment in which they reside. In vitro experiments indicate that similar alterations occur for cultured EC exposed to a laminar steady-state flow-induced shear stress. However, in vivo EC are exposed to a pulsatile flow environment; thus, in this investigation, the influence of pulsatile flow on cell shape and orientation and on actin microfilament localization in confluent bovine aortic endothelial cell (BAEC) monolayers was studied using a 1-Hz nonreversing sinusoidal shear stress of 40 +/- 20 dynes/cm2 (type I), 1-Hz reversing sinusoidal shear stresses of 20 +/- 40 and 10 +/- 15 dynes/cm2 (type II), and 1-Hz oscillatory shear stresses of 0 +/- 20 and 0 +/- 40 dynes/cm2 (type III). The results show that in a type I nonreversing flow, cell shape changed less rapidly, but cells took on a more elongated shape than their steady flow controls long-term. For low-amplitude type II reversing flow, BAECs changed less rapidly in shape and were always less elongated than their steady controls; however, for high amplitude reversal, BAECs did not stay attached for more than 24 hours. For type III oscillatory flows, BAEC cell shape remained polygonal as in static culture and did not exhibit actin stress fibers, such as occurred in all other flows. These results demonstrate that EC can discriminate between different types of pulsatile flow environments.(ABSTRACT TRUNCATED AT 250 WORDS)     

The relative importance of topography and RGD ligand density for endothelial cell adhesion

The morphology and function of endothelial cells depends on the physical and chemical characteristics of the extracellular environment. Here, we designed silicon surfaces on which topographical features and surface densities of the integrin binding peptide arginine-glycine-aspartic acid (RGD) could be independently controlled. We used these surfaces to investigate the relative importance of the surface chemistry of ligand presentation versus surface topography in endothelial cell adhesion. We compared cell adhesion, spreading and migration on surfaces with nano- to micro-scaled pyramids and average densities of 6×10(2)-6×10(11) RGD/mm(2). We found that fewer cells adhered onto rough than flat surfaces and that the optimal average RGD density for cell adhesion was 6×10(5) RGD/mm(2) on flat surfaces and substrata with nano-scaled roughness. Only on surfaces with micro-scaled pyramids did the topography hinder cell migration and a lower average RGD density was optimal for adhesion. In contrast, cell spreading was greatest on surfaces with 6×10(8) RGD/mm(2) irrespectively of presence of feature and their size. In summary, our data suggest that the size of pyramids predominately control the number of endothelial cells that adhere to the substratum but the average RGD density governs the degree of cell spreading and length of focal adhesion within adherent cells. The data points towards a two-step model of cell adhesion: the initial contact of cells with a substratum may be guided by the topography while the engagement of cell surface receptors is predominately controlled by the surface chemistry.     

Inherent toxicity of organ preservation solutions to cultured hepatocytes

Organ preservation solutions have been designed to protect grafts against the injury inflicted by cold ischemia. However, toxicity of University of Wisconsin (UW) solution during rewarming has been reported. Therefore, we here assessed the toxicity of UW, histidine-tryptophan-ketoglutarate (HTK), Euro-Collins, histidine-lactobionate (HL), sodium-lactobionate-sucrose and Celsior solutions in cultured hepatocytes under hypothermic (4 °C), intermediate (21 °C) and physiological (37 °C) conditions. Marked toxicity of UW, HTK, HL and Euro-Collins solutions was observed at both 37 and 21 °C. With the exception of UW solution, these solutions also increased cell injury during cold incubation (LDH release after 18 h at 4 °C: HTK 76 ± 2%, Euro-Collins 78 ± 17%, HL 81 ± 15%; control: Krebs-Henseleit buffer 20 ± 6%). Testing of individual components using modified Krebs-Henseleit buffers suggested that histidine and phosphate are responsible for (part of) this toxicity. These potential toxicities should be taken into account in the development of future preservation solutions.     

From 3D cell culture to organs-on-chips

3D cell-culture models have recently garnered great attention because they often promote levels of cell differentiation and tissue organization not possible in conventional 2D culture systems. We review new advances in 3D culture that leverage microfabrication technologies from the microchip industry and microfluidics approaches to create cell-culture microenvironments that both support tissue differentiation and recapitulate the tissue-tissue interfaces, spatiotemporal chemical gradients, and mechanical microenvironments of living organs. These 'organs-on-chips' permit the study of human physiology in an organ-specific context, enable development of novel in vitro disease models, and could potentially serve as replacements for animals used in drug development and toxin testing.     

猪动脉内皮细胞胞膜小窝的电子断层三维结构分析

利用电子断层三维重构技术对猪动脉内皮细胞 (porcine aorta endothelial cell,PAE cell) 胞膜小窝的三维结构进行了初步研究,发现胞膜小窝在细胞膜表面呈不均匀分布并在局部形成聚集,胞膜小窝膜内外表面都由宽度约14～16 nm的条纹状结构所环绕,推测该条纹状结构主要由小窝蛋白和胆固醇构成,狭窄的胞膜小窝颈部区域存在高密度的丝状结构．三维结构显示胞膜小窝与纤维丝体网络(推测为微管网络)相互作用,暗示了细胞内吞可能的运输途径．     

3D automatic quantification applied to optically sectioned images to improve microscopy analysis

New fluorescence microscopy techniques, such as confocal or digital deconvolution microscopy, allow to easily obtain three-dimensional (3D) information from specimens. However, there are few 3D quantification tools that allow extracting information of these volumes. Therefore, the amount of information acquired by these techniques is difficult to manipulate and analyze manually. The present study describes a model-based method, which for the first time shows 3D visualization and quantification of fluorescent apoptotic body signals, from optical serial sections of porcine hepatocyte spheroids correlating them to their morphological structures. The method consists on an algorithm that counts apoptotic bodies in a spheroid structure and extracts information from them, such as their centroids in cartesian and radial coordinates, relative to the spheroid centre, and their integrated intensity. 3D visualization of the extracted information, allowed us to quantify the distribution of apoptotic bodies in three different zones of the spheroid.     

Binding of plasminogen to cultured human endothelial cells

Endothelial cells are known to release the two major forms of plasminogen activator, tissue plasminogen activator (TPA) and urokinase. We have previously demonstrated that plasminogen (PLG) immobilized on various surfaces forms a substrate for efficient conversion to plasmin by TPA (Silverstein, R. L., Nachman, R. L., Leung, L. L. K., and Harpel, P. C. (1985) J. Biol. Chem. 260, 10346-10352). We now report the binding of human PLG to cultured human umbilical vein endothelial cell (HUVEC) monolayers, utilizing a newly devised cell monolayer enzyme-linked immunosorbent assay system. PLG binding to HUVEC was concentration dependent and saturable at physiologic PLG concentration (2 microM). Binding of PLG was 70-80% inhibited by 10 mM epsilon-aminocaproic acid, suggesting that it is largely mediated by the lysine-binding sites of PLG. PLG bound at an intermediate level to human fibroblasts, poorly to human smooth muscle cells, and not at all to bovine smooth muscle or bovine endothelial cells; unrelated proteins such as human albumin and IgG failed to bind HUVEC. PLG binding to HUVEC was rapid, reaching a steady state within 20 min, and quickly reversible. 125I-PLG bound to HUVEC with an estimated Kd of 310 +/- 235 nM (S.E.); each cell contained 1,400,000 +/- 1,000,000 (S.E.) binding sites. Functional studies demonstrated that HUVEC-bound PLG is activatable by TPA according to Michaelis-Menten kinetics (Km, 5.9 nM). Importantly, surface-bound PLG was activated with a 12.7-fold greater catalytic efficiency than fluid phase PLG. These results indicate that PLG binds to HUVEC in a specific and functional manner. Binding of PLG to endothelial cells may play a pivotal role in modulating thrombotic events at the vessel surface.     

Thrombin-induced adherence of neutrophils to cultured endothelial monolayers: increased endothelial adhesiveness

We examined the effects of alpha-thrombin on the adherence of neutrophils to endothelial cell monolayers. Endothelial cells derived from the ovine pulmonary artery and ovine neutrophils were used. Thrombin (10(-8) M) resulted in a time-dependent increase in neutrophil adherence to the endothelium. The response was concentration-dependent with a maximal response at 10(-8) M. Thrombin did not induce neutrophil adherence either to plastic or to endothelial cell-derived matrix. The adherence response was inhibited in the presence of alpha-thrombin that had been inactivated with anti-thrombin III (1U:1U) or with hirudin (1 U/ml). However, the addition of either anti-thrombin III or hirudin simultaneously with alpha-thrombin to the cultured endothelial monolayers did not prevent neutrophil adherence. The monoclonal antibody MoAb 60.3, which precipitates a complex of four neutrophil surface glycoproteins (CDw18) was used to further characterize the reaction. MoAb 60.3 decreased the thrombin-induced adherence of neutrophils to the endothelial monolayer. Addition of 10(-8) M thrombin to the endothelial monolayer for 60 min, followed by washing the endothelium with fresh medium, caused resting neutrophils to adhere to the endothelial monolayers. MoAb 60.3 decreased neutrophil adherence to the washed endothelium. The factor(s) responsible for adherence was partially transferable. Medium obtained from incubating endothelial monolayers with thrombin (10(-8) M) for 60 min, adding hirudin to the medium to inactivate thrombin, and transferring it to untreated endothelial monolayers, elicited neutrophil adherence. The response was less than that obtained with thrombin alone (22.9 +/- 2.3% vs. 12.9 +/- 3.3%). The results indicate that the catalytic site of the thrombin molecule is responsible for the adherent activity. Thrombin elicits a rapid activation of endothelial cells with a response that involves the expression of endothelial adhesion sites and sites that interact with the neutrophil CDw18 adhesive glycoprotein complex. In addition, soluble transferable factor(s) which are generated by the endothelium also contribute to thrombin-induced neutrophil adherence.     

Radiation-induced changes in the cell membrane of cultured human endothelial cells

We investigated the effect of irradiation on the kinetic characteristics of amino acid and glucose transport, and the effect on the activity of the cell membrane-bound enzyme 5'-nucleotidase and on the receptor-mediated stimulation of cyclic adenosine monophosphate synthesis by prostaglandin E1. Irradiation inhibited the sodium-dependent amino acid transport by a reduced binding of the amino acid to the transport unit. The transport of glucose, which appeared to be a sodium-independent process, was temporarily stimulated by increased maximal velocity of the transport. No effect was found on the binding to the transport unit. Irradiation increased the 5'-nucleotidase activity and decreased the prostaglandin E1-stimulated cyclic adenosine monophosphate synthesis 48 h after exposure to 20 Gy. It is concluded that irradiation decreases sodium-dependent transport by impairment of the transport unit, does not impair a sodium-independent process, and has opposite effects on membrane-bound enzyme activity and a receptor-mediated process.     

3D finite element modeling of pelvic organ prolapse

Objectives: The purpose of this study is to develop a validated 3D finite element model of the pelvic floor system which can offer insights into the mechanics of anterior vaginal wall prolapse and have the ability to assess biomedical device treatment methods. The finite element results should accurately mimic the clinical findings of prolapse due to intra-abdominal pressure (IAP) and soft tissues impairment conditions. Methods: A 3D model of pelvic system was created in Creo Parametric 2.0 based on MRI Images, which included uterus, cervix, vagina, cardinal ligaments, uterosacral ligaments, and a simplified levator plate and rectum. The geometrical model was imported into ANSYS Workbench 14.5. Mechanical properties of soft tissues were based on experimental data of tensile test results from current literature. Studies were conducted for IAP loadings on the vaginal wall and uterus, increasing from lowest to extreme values. Results: Anterior vaginal wall collapse occurred at an IAP value corresponding to maximal valsalva and showed similar collapsed shape as clinical findings. Prolapse conditions exhibited high sensitivity to vaginal wall stiffness, whereas healthy tissues was found to support the vagina against prolapse. Ligament impairment was found to have only a secondary effect on prolapse.