A multi-component parallel-plate flow chamber system for studying the effect of exercise-induced wall shear stress on endothelial cells

The intracellular calcium dynamics in vascular endothelial cells (VECs) in response to wall shear stress (WSS) and/or adenosine triphosphate (ATP) have been commonly regarded as an important factor in regulating VEC function and behavior including proliferation, migration and apoptosis. However, the effects of time-varying ATP signals have been usually neglected in the past investigations in the field of VEC mechanobiology. In order to investigate the combined effects of WSS and dynamic ATP signals on the intracellular calcium dynamic in VECs, a Y-shaped microfluidic device, which can provide the cultured cells on the bottom of its mixing micro-channel with stimuli of WSS signal alone and different combinations of WSS and ATP signals in one single micro-channel, is proposed. Both numerical simulation and experimental studies verify the feasibility of its application. Cellular experimental results also suggest that a combination of WSS and ATP signals rather than a WSS signal alone might play a more significant role in VEC Ca2+ signal transduction induced by blood flow.

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“…With the assumption of quasi-steady flow, the velocity profile u ( y , t ), the height-wise averaging velocity

and the shear stress τ w ( t ) can be given by [ 21 ],

where Q ( t ) is the total flow rate through the mixing micro-channel C.…”

Section: Methodsmentioning

confidence: 99%

A Y-Shaped Microfluidic Device to Study the Combined Effect of Wall Shear Stress and ATP Signals on Intracellular Calcium Dynamics in Vascular Endothelial Cells

et al. 2016

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“…With the assumption of quasi-steady flow, the velocity profile u(y,t), the height-wise averaging velocity u and the shear stress τw(t) can be given by [21],…”

Section: Equation Governing Pulsatile Flow In the Mixing Micro-channel Cmentioning

confidence: 99%

A Y-Shaped Microfluidic Device to Study the Combined Effect of Wall Shear Stress and ATP Signals on Intracellular Calcium Dynamics in Vascular Endothelial Cells

Chen

Gao

Zeng

et al. 2016

Preprint

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“…Historically, two manufacturing approaches have been used. Milling of aluminum or plastic blocks to produce chambers is a common approach, but is also often limited in its ability to produce small features, and producing chambers with interior features is extremely difficult 9 . Moreover, this approach can be expensive, especially for single-use devices as making these devices requires access to a CNC milling machine and costly machining blanks made of biocompatible materials.…”

Section: Introductionmentioning

confidence: 99%

Customizable Live-Cell Imaging Chambers for Multimodal and Multiplex Fluorescence Microscopy

Tepperman

Zheng

Taka

et al. 2020

Preprint

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While new high-resolution microscopy techniques are continually developed, adoption of these methods is often difficult due to an inability to meet the experimental conditions required for an experiment in a format which also meets the demanding optical requirements of these microscopy techniques. Although specialized imaging chambers can meet these challenges, the difficulty of manufacturing customized chambers in-house and the relatively high cost and design inflexibility of commercial chambers has limited the incorporation of imaging chambers into fluorescence and super-resolution microscopy experiments. Herein, we demonstrate the use of fused deposition modeling (3D printing) for producing inexpensive, customized imaging chambers that are compatible with long-duration live-cell imaging using fluorescence and super-resolution microscopy techniques. In this approach, biocompatible 3D printing plastics are used to generate imaging chambers designed to meet the specific needs of an experiment, followed by adhesion of the printed chamber to a glass coverslip suitable for fluorescence and super-resolution imaging. This technique produces a chamber that is impermeant to liquids that can support the growth and imaging of cells over multiple days. The utility of these chambers is then demonstrated using designs for multiplex microscopy, imaging under shear, chemotaxis, and general cellular imaging. Together, this approach represents an inexpensive yet highly customizable approach to produce imaging chambers that are compatible with many modern microscopy techniques.

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A multi-component parallel-plate flow chamber system for studying the effect of exercise-induced wall shear stress on endothelial cells

Cited by 35 publications

References 31 publications

A Y-Shaped Microfluidic Device to Study the Combined Effect of Wall Shear Stress and ATP Signals on Intracellular Calcium Dynamics in Vascular Endothelial Cells

A Y-Shaped Microfluidic Device to Study the Combined Effect of Wall Shear Stress and ATP Signals on Intracellular Calcium Dynamics in Vascular Endothelial Cells

A Y-Shaped Microfluidic Device to Study the Combined Effect of Wall Shear Stress and ATP Signals on Intracellular Calcium Dynamics in Vascular Endothelial Cells

Customizable Live-Cell Imaging Chambers for Multimodal and Multiplex Fluorescence Microscopy

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