Esther Zusstone scite author profile

Esther Zusstone

2Publications

16Citation Statements Received

105Citation Statements Given

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University of Louisville

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

Velasco

Gruenthal

Zusstone

et al. 2016

Biotech & Bioengineering

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Electrical impedance techniques have been used to characterize endothelium morphology, permeability, and motility in vitro. However, these impedance platforms have been limited to either static endothelium studies and/or induced laminar fluid flow at a constant, single shear stress value. In this work, we present a microfabricated impedance sensor for real-time, in vitro characterization of human umbilical vein endothelial cells (HUVECs) undergoing oscillatory hydrodynamic shear. Oscillatory shear was applied with an orbital shaker and the electrical impedance was measured by a microfabricated impedance chip with discrete electrodes positioned at radial locations of 0, 2.5, 5.0, 7.5, 10.0, and 12.5 mm from the center of the chip. Depending on their radial position within the circular orbital platform, HUVECs were exposed to shear values ranging between 0.6 and 6.71 dyne/cm(2) (according to numerical simulations) for 22 h. Impedance spectra were fit to an equivalent circuit model and the trans-endothelial resistance and monolayer's capacitance were extracted. Results demonstrated that, compared to measurements acquired before the onset of shear, cells at the center of the platform that experienced low steady shear stress (∼2.2 dyne/cm(2) ) had an average change in trans-endothelial resistance of 6.99 ± 4.06% and 1.78 ± 2.40% change in cell capacitance after 22 hours of shear exposure; cells near the periphery of the well (r = 12.5 mm) experienced transient shears (2.5-6.7 dyne/cm(2) ) and exhibited a greater change in trans-endothelial resistance (24.2 ± 10.8%) and cell capacitance (4.57 ± 5.39%). This study, demonstrates that the orbital shear platform provides a simple system that can capture and quantify the real-time cellular morphology as a result of induced shear stress. The orbital shear platform presented in this work, compared to traditional laminar platforms, subjects cells to more physiologically relevant oscillatory shear as well as exposes the sample to several shear values simultaneously. Biotechnol. Bioeng. 2016;113: 1336-1344. © 2015 Wiley Periodicals, Inc.

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Cover Image, Volume 113, Number 6, June 2016

Velasco

Gruenthal

Zusstone

et al. 2016

Biotech & Bioengineering

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Cover Legend This figure is the top view of the orbital‐shear impedance chip. Its design incorporated three arrays of 200 μm diameter sensing electrodes (small dark gray circles of inset image) and neighboring counter electrode strips. Three additional counter electrodes (large dark gray circles) were included to determine the influence of counter electrode proximity to sensing electrodes. Contact pads (bottom row) were patterned to fit into a commercial card reader. The dashed blue line indicates the perimeter of the PDMS well containing the endothelial cell monolayer. The cover image, by Stuart J. Williams et al., is based on the Article An orbital shear platform for real‐time, in vitro endothelium characterization, DOI: .

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Esther Zusstone

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

Cover Image, Volume 113, Number 6, June 2016

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