Endothelial Barrier Function under Laminar Fluid Shear Stress

Seebach, Jochen; Dieterich, Peter; Luo, Fanghong; Schillers, Hermann; Vestweber, Dietmar; Oberleithner, Hans; Galla, Hans‐Joachim; Schnittler, Hans-Joachim

doi:10.1038/labinvest.3780193

Cited by 130 publications

(167 citation statements)

References 57 publications

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“…11 In cultured vascular endothelial cell models, increasing t causes an initial rapid increase in barrier function, followed by decrease in barrier function over longer periods of time. [8][9][10] In both of the isolated venule and cultured endothelial cell models, the effects of increased t were reversed upon returning to the baseline t. [8][9][10][11] These studies demonstrate that shear stress sensing is an important property of vascular endothelium for regulating barrier function.…”

Section: Introductionmentioning

confidence: 86%

“…7 In blood vessels and in cultured vascular endothelial cell models, changes in the laminar fluid flow rate can influence barrier function. [8][9][10][11] For example, increasing the fluid flow through isolated, perfused coronary venules not only increases filtration of solutes, but also increases their diffusive permeability coefficient to albumin through a NO-related mechanism. 11 In cultured vascular endothelial cell models, increasing t causes an initial rapid increase in barrier function, followed by decrease in barrier function over longer periods of time.…”

Section: Introductionmentioning

confidence: 99%

“…Using cultured lymphatic endothelial cells, and based on evidence that step increases in t transiently increase barrier function of vascular endothelial cells. 8,9 we tested the hypothesis that a step elevation of t rapidly enhances barrier function. In addition, we evaluated whether protein kinase A (PKA) or the small GTPase Rac1, both of which have been implicated as promoters of enhanced endothelial barrier function, 12 may be involved in shear stress-induced changes in lymphatic endothelial barrier function.…”

Section: Introductionmentioning

confidence: 99%

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Lymphatic Endothelial Cells Adapt Their Barrier Function in Response to Changes in Shear Stress

Breslin

Kurtz

2009

Lymphatic Research and Biology

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Background: Lymphatic endothelial cells form an important barrier necessary for normal lymph formation and propulsion. However, little is known about how physical forces within lymphatic vessels affect endothelial barrier function. The purpose of this study was to characterize how laminar flow affects lymphatic endothelial barrier function and to test whether endothelial cells respond to flow changes by activating the intracellular actin cytoskeleton to enhance barrier function. Methods and Results: Cultured adult human dermal microlymphatic endothelial cells (HMLEC-d) were grown on small gold electrodes arranged within a flow channel, and transendothelial electrical resistance (TER), an index of barrier function, was determined. Laminar flow was applied to the cells at a baseline shear stress of 0.5 dynes=cm 2 , and was increased to 2.5, 5.0, or 9.0 dynes=cm 2 , causing a magnitude-dependent increase in barrier function that was reversed 30 min later when the shear stress was returned to baseline. This response was abolished by blockade of actin dynamics with 10 mM phalloidin, and significantly inhibited by blockade of Rac1 activity with 50 mM NSC23766. Blockade of protein kinase A (10 mM H-89) did not inhibit the response. Mathematical modeling based on our impedance data showed that the flow-induced changes in TER were primarily due to altered current flow between cells and not beneath cells. Conclusions: These results suggest that lymphatic endothelial cells dynamically alter their morphology and barrier function in response to changes in shear stress by a mechanism dependent upon Rac1-mediated actin dynamics.

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Section: Introductionmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Lymphatic Endothelial Cells Adapt Their Barrier Function in Response to Changes in Shear Stress

Breslin

Kurtz

2009

Lymphatic Research and Biology

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“…Similar permeability characteristics have been reported previously for endothelial cells when they are exposed to FSS, where the permeability increases immediately at the onset of flow and slowly plateaus to a baseline value. 42,43 The introduction of flow does bring about a transient increase in permeability for the BAOEC layer that stabilizes after about 2.5 h of flow. Thus, it is safe to assume that this study is performed on a BAOEC layer that has been primed to flow, and the study performed after 6 h of exposure to FSS will not be affected by any initial flow related changes in permeability.…”

Section: Resultsmentioning

confidence: 99%

Characterization of vascular permeability using a biomimetic microfluidic blood vessel model

et al. 2017

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The inflammatory response in endothelial cells (ECs) leads to an increase in vascular permeability through the formation of gaps. However, the dynamic nature of vascular permeability and external factors involved is still elusive. In this work, we use a biomimetic blood vessel (BBV) microfluidic model to measure in real-time the change in permeability of the EC layer under culture in physiologically relevant flow conditions. This platform studies the dynamics and characterizes vascular permeability when the EC layer is triggered with an inflammatory agent using tracer molecules of three different sizes, and the results are compared to a transwell insert study. We also apply an analytical model to compare the permeability data from the different tracer molecules to understand the physiological and bio-transport significance of endothelial permeability based on the molecule of interest. A computational model of the BBV model is also built to understand the factors influencing transport of molecules of different sizes under flow. The endothelial monolayer cultured under flow in the BBV model was treated with thrombin, a serine protease that induces a rapid and reversible increase in endothelium permeability. On analysis of permeability data, it is found that the transport characteristics for fluorescein isothiocyanate (FITC) dye and FITC Dextran 4k Da molecules are similar in both BBV and transwell models, but FITC Dextran 70k Da molecules show increased permeability in the BBV model as convection flow (Peclet number > 1) influences the molecule transport in the BBV model. We also calculated from permeability data the relative increase in intercellular gap area during thrombin treatment for ECs in the BBV and transwell insert models to be between 12% and 15%. This relative increase was found to be within range of what we quantified from F-actin stained EC layer images. The work highlights the importance of incorporating flow in in vitro vascular models, especially in studies involving transport of large size objects such as antibodies, proteins, nano/micro particles, and cells. Published by AIP Publishing.

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“…However, in vivo HBMEC are shown to interact with astrocytes and also exposed to shear stress through blood flow. Several lines of evidence suggest that non-human brain and non-brain endothelial tight junctions are enhanced when co-cultured with astrocytes or in the presence of ACM [1,5,56,61,62,69,81], and blood flow associated shear stress have been shown to modify the endothelial barrier [67,70,74].…”

Section: Introductionmentioning

confidence: 99%

Human astrocytes/astrocyte-conditioned medium and shear stress enhance the barrier properties of human brain microvascular endothelial cells

et al. 2007

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The blood-brain barrier (BBB) is a structural and functional barrier that regulates the passage of molecules into and out of the brain to maintain the neural microenvironment. We have previously developed the in vitro BBB model with human brain microvascular endothelial cells (HBMEC). However, in vivo HBMEC are shown to interact with astrocytes and also exposed to shear stress through blood flow. In an attempt to develop the BBB model to mimic the in vivo condition we constructed the flow-based in vitro BBB model using HBMEC and human fetal astrocytes (HFA). We also examined the effect of astrocyte conditioned medium (ACM) in lieu of HFA to study the role of secreted factor(s) on the BBB properties. The tightness of HBMEC monolayer was assessed by the permeability of dextran and propidium iodide as well as by measuring the transendothelial electrical resistance (TEER). We showed that the HBMEC permeability was reduced and TEER was increased by non-contact, co-cultivation with HFA and ACM. The exposure of HBMEC to shear stress also exhibited decreased permeability. Moreover, HFA/ACM and shear flow exhibited additive effect of decreasing the permeability of HBMEC monolayer. In addition, we showed that the HBMEC expression of ZO-1 (tight junction protein) was increased by co-cultivation with ACM and in response to shear stress. These findings suggest that the non-contact co-cultivation with HFA helps maintain the barrier properties of HBMEC by secreting factor(s) into the medium. Our in vitro flow model system with the cells of human origin should be useful for studying the interactions between endothelial cells, glial cells, and secreted factor(s) as well as the role of shear stress in the barrier property of HBMEC.

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Endothelial Barrier Function under Laminar Fluid Shear Stress

Cited by 130 publications

References 57 publications

Lymphatic Endothelial Cells Adapt Their Barrier Function in Response to Changes in Shear Stress

Lymphatic Endothelial Cells Adapt Their Barrier Function in Response to Changes in Shear Stress

Characterization of vascular permeability using a biomimetic microfluidic blood vessel model

Human astrocytes/astrocyte-conditioned medium and shear stress enhance the barrier properties of human brain microvascular endothelial cells

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