An orbital shear platform for real‐time, in vitro endothelium characterization

Velasco, Vanessa; Gruenthal, Mark J.; Zusstone, Esther; Thomas, Jonathan Michael D.; Berson, R. Eric; Keynton, Robert; Williams, Stuart J.

doi:10.1002/bit.25893

Cited by 16 publications

(16 citation statements)

References 87 publications

(105 reference statements)

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“…Starting with the work of Berson et al [ 35 ], numerical models of the orbital shaker system [ [30] , [31] , [32] , 34 , [36] , [37] , [38] , [39] , [40] , [41] , [42] , [43] , [44] , [45] , [46] ] have shown that WSS magnitude fluctuates with time, more so towards the edge of the well than at its centre, and that TAWSS is also greater towards the edge. Additionally, the direction of the instantaneous WSS vector rotates evenly through 360° at the centre of the well during each orbit whereas at the edge, vectors tend only to switch between forward and backward orientations along a line that is approximately parallel to the wall.…”

Section: Characterisation Of Flow In Swirling Wellsmentioning

confidence: 99%

Understanding mechanobiology in cultured endothelium: A review of the orbital shaker method

Warboys¹,

Ghim²,

Weinberg

2019

Atherosclerosis

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A striking feature of atherosclerosis is its highly non-uniform distribution within the arterial tree. This has been attributed to variation in the haemodynamic wall shear stress (WSS) experienced by endothelial cells, but the WSS characteristics that are important and the mechanisms by which they lead to disease remain subjects of intensive investigation despite decades of research. In vivo evidence suggests that multidirectional WSS is highly atherogenic. This possibility is increasingly being studied by culturing endothelial cells in wells that are swirled on an orbital shaker. The method is simple and cost effective, has high throughput and permits chronic exposure, but interpretation of the results can be difficult because the fluid mechanics are complex; hitherto, their description has largely been restricted to the engineering literature. Here we review the findings of such studies, which indicate that putatively atherogenic flow characteristics occur at the centre of the well whilst atheroprotective ones occur towards the edge, and we describe simple mathematical methods for choosing experimental variables that avoid resonance, wave breaking and uncovering of the cells. We additionally summarise a large number of studies showing that endothelium cultured at the centre of the well expresses more pro-inflammatory and fewer homeostatic genes, has higher permeability, proliferation, apoptosis and senescence, and shows more endothelial-to-mesenchymal transition than endothelium at the edge. This simple method, when correctly interpreted, has the potential to greatly increase our understanding of the homeostatic and pathogenic mechanobiology of endothelial cells and may help identify new therapeutic targets in vascular disease.

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Section: Characterisation Of Flow In Swirling Wellsmentioning

confidence: 99%

Understanding mechanobiology in cultured endothelium: A review of the orbital shaker method

Warboys¹,

Ghim²,

Weinberg

2019

Atherosclerosis

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“…It can be used to measure a variety of cellular properties, e.g., behavior under flow [ 52 ]. Another setup is the combination of a small impedance chip with an orbital shaker to produce oscillatory shear, which allows the measurement of trans-endothelial resistance against varying shear stress conditions [ 53 ]. Furthermore, microfluidic chips, also known as “organ-on-a-chip” technology, is a further advanced form of in vitro systems, which may contribute to our understanding of EC responses to hemodynamics [ 54 ] (reviewed in [ 55 , 56 ]).…”

Section: In Vitro Systems To Model Flow Dynamics and Endothelial Wall Shear Stress (Wss)mentioning

confidence: 99%

Investigation of Wall Shear Stress in Cardiovascular Research and in Clinical Practice—From Bench to Bedside

Urschel

Tauchi

Achenbach

et al. 2021

IJMS

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In the 1900s, researchers established animal models experimentally to induce atherosclerosis by feeding them with a cholesterol-rich diet. It is now accepted that high circulating cholesterol is one of the main causes of atherosclerosis; however, plaque localization cannot be explained solely by hyperlipidemia. A tremendous amount of studies has demonstrated that hemodynamic forces modify endothelial athero-susceptibility phenotypes. Endothelial cells possess mechanosensors on the apical surface to detect a blood stream-induced force on the vessel wall, known as “wall shear stress (WSS)”, and induce cellular and molecular responses. Investigations to elucidate the mechanisms of this process are on-going: on the one hand, hemodynamics in complex vessel systems have been described in detail, owing to the recent progress in imaging and computational techniques. On the other hand, investigations using unique in vitro chamber systems with various flow applications have enhanced the understanding of WSS-induced changes in endothelial cell function and the involvement of the glycocalyx, the apical surface layer of endothelial cells, in this process. In the clinical setting, attempts have been made to measure WSS and/or glycocalyx degradation non-invasively, for the purpose of their diagnostic utilization. An increasing body of evidence shows that WSS, as well as serum glycocalyx components, can serve as a predicting factor for atherosclerosis development and, most importantly, for the rupture of plaques in patients with high risk of coronary heart disease.

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“…Moreover, extrapolation of animal data to human conditions has been frustratingly controversial, particularly for complex diseases afflicting dynamic microenvironments prevalent with mechanochemical stimuli such as blood flow and inflammatory cytokines 13 . Overcoming traditional in vitro models that predominantly rely on static culture of vascular endothelial cells, current advanced in vitro studies on endothelial mechanotransduction have taken the magnitude and direction of OSS into consideration to complement existing animal model research 3 , 4 , 8 , 9 , 14 – 16 . The frequencies typically associated to be characteristic of disease-causing OSS are based on measured physiological values in vivo ; this value is about 5 Hz in mice, whereas in humans this level drops to approximately 1 Hz 3 , 10 , 17 .…”

Section: Introductionmentioning

confidence: 99%

Detection of frequency-dependent endothelial response to oscillatory shear stress using a microfluidic transcellular monitor

Ahn

Virtue

Kim

et al. 2017

Sci Rep

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The endothelial microenvironment is critical in maintaining the health and function of the intimal layer in vasculature. In the context of cardiovascular disease (CVD), the vascular endothelium is the layer of initiation for the progression of atherosclerosis. While laminar blood flows are known to maintain endothelial homeostasis, disturbed flow conditions including those the endothelium experiences in the carotid artery are responsible for determining the fate of CVD progression. We present a microfluidic device designed to monitor the endothelium on two fronts: the real-time monitoring of the endothelial permeability using integrated electrodes and the end-point characterization of the endothelium through immunostaining. Our key findings demonstrate endothelial monolayer permeability and adhesion protein expression change in response to oscillatory shear stress frequency. These changes were found to be significant at certain frequencies, suggesting that a frequency threshold is needed to elicit an endothelial response. Our device made possible the real-time monitoring of changes in the endothelial monolayer and its end-point inspection through a design previously absent from the literature. This system may serve as a reliable research platform to investigate the mechanisms of various inflammatory complications of endothelial disorders and screen their possible therapeutics in a mechanistic and high-throughput manner.

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An orbital shear platform for real‐time, in vitro endothelium characterization

Cited by 16 publications

References 87 publications

Understanding mechanobiology in cultured endothelium: A review of the orbital shaker method

Understanding mechanobiology in cultured endothelium: A review of the orbital shaker method

Investigation of Wall Shear Stress in Cardiovascular Research and in Clinical Practice—From Bench to Bedside

Detection of frequency-dependent endothelial response to oscillatory shear stress using a microfluidic transcellular monitor

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