Sensitivity and Validation of Porous Membrane Electrical Cell Substrate Impedance Spectroscopy (PM-ECIS) for Measuring Endothelial Barrier Properties.

Measurement of endothelial and epithelial barrier integrity is important for a variety of in vitro models, including Transwell assays, cocultures, and organ-on-chip platforms. Barrier resistance is typically measured by trans-endothelial electrical resistance (TEER), but TEER is invasive and cannot accurately measure isolated monolayer resistance in coculture or most organ-on-chip devices. These limitations are addressed by porous membrane electrical cell-substrate impedance sensing (PM-ECIS), which measures barrier integrity in cell monolayers grown directly on permeable membranes patterned with electrodes. Here, we advanced the design and utility of PM-ECIS by investigating its sensitivity to working electrode size and correlation with TEER. Gold electrodes were fabricated on porous membrane inserts using hot embossing and UV lithography, with working electrode diameters of 250, 500, and 750 µm within the same insert. Sensitivity to resistance changes (4 kHz) during endothelial barrier formation was inversely proportional to electrode size, with the smallest being the most sensitive (p < 0.001). Similarly, smaller electrodes were most sensitive to changes in impedance (40 kHz) corresponding to cell spreading and proliferation (p < 0.001). Barrier disruption with both EGTA and thrombin was detectable by all electrode sizes. Resistances measured by PM-ECIS vs TEER for sodium chloride solutions were positively and significantly correlated for all electrode sizes (r > 0.9; p < 0.0001), but only with 750 µm electrodes for endothelial monolayers (r = 0.71; p = 0.058). These data inform the design and selection of PM-ECIS electrodes for specific applications and support PM-ECIS as a promising alternative to conventional TEER for direct, noninvasive, real-time assessment of cells cultured on porous membranes in conventional and organ-on-chip barrier models.

Porous Membrane Electrical Cell-Substrate Impedance Spectroscopy for Versatile Assessment of Biological Barriers In Vitro.

Cell culture models of endothelial and epithelial barriers typically use porous membrane inserts (e.g., Transwell inserts) as a permeable substrate on which barrier cells are grown, often in coculture with other cell types on the opposite side of the membrane. Current methods to characterize barrier function in porous membrane inserts can disrupt the barrier or provide bulk measurements that cannot isolate barrier cell resistance alone. Electrical cell-substrate impedance sensing (ECIS) addresses these limitations, but its implementation on porous membrane inserts has been limited by costly manufacturing, low sensitivity, and lack of validation for barrier assessment. Here, we present porous membrane ECIS (PM-ECIS), a cost-effective method to adapt ECIS technology to porous substrate-based in vitro models. We demonstrate high fidelity patterning of electrodes on porous membranes that can be incorporated into well plates of a variety of sizes with excellent cell biocompatibility with mono- and coculture set ups. PM-ECIS provided sensitive, real-time measurement of isolated changes in endothelial cell barrier impedance with cell growth and barrier disruption. Barrier function characterized by PM-ECIS resistance correlated well with permeability coefficients obtained from simultaneous molecular tracer permeability assays performed on the same cultures, validating the device. Integration of ECIS into conventional porous cell culture inserts provides a versatile, sensitive, and automated alternative to current methods to measure barrier function in vitro, including molecular tracer assays and transepithelial/endothelial electrical resistance.

Intrafamilial variability of noncompaction of the ventricular myocardium.

BACKGROUND: Noncompaction of the ventricular myocardium (NVM) is a relatively uncommon form of cardiomyopathy characterized by a highly trabeculated myocardium. This report describes the clinical and genetic evaluation of a 3-generation kindred. METHODS: Family members were initially evaluated by 2-dimensional echocardiography. Most family members with signs of NVM were further evaluated by magnetic resonance imaging. Genetic analyses included mutational screening of the taffazin (TAZ) and alpha-dystrobrevin (DTNA) genes. RESULTS: Eight family members had signs of NVM. Considerable interindividual variation was noted in terms of spatial distribution and severity of affected regions and ventricular dysfunction. Depending on which of 2 previously proposed quantitative diagnostic criteria were used and where ventricular myocardial measurements were taken, between 4 and 7 of these individuals had findings that were considered diagnostic. Magnetic resonance imaging served as a useful adjunct for confirming or establishing diagnoses in all 8 individuals. No mutation was found in TAZ or DTNA. CONCLUSIONS: This kindred demonstrates the remarkably wide phenotypic spectrum that can be seen in familial cases of NVM, ranging from prenatal/neonatal lethality to a complete lack of symptoms. The fact that all 8 affected individuals either have shown improvement in ventricular function or symptoms during childhood or have been asymptomatic indicates that NVM can have a relatively benign course. The degree and nature of cardiac involvement are also quite varied, and there is a weak correlation with ventricular function and symptoms. Evaluation of families with NVM requires careful assessment that uses a combination of imaging techniques and diagnostic criteria.

Miniaturized platform with on-chip strain sensors for compression testing of arrayed materials.

We report a microfabricated mechanical testing platform with on-chip strain sensors for in situ mechanical characterization of arrayed materials. The device is based on deformable elastomeric membranes that are actuated by pressure that is delivered through an underlying channel network. The bulging membranes compress material samples that are confined between the membranes and a rigid top-plate. Carbon nanotube-based strain sensors that exhibit strain-dependent electrical resistivity were integrated within the membranes to provide continuous read-out of membrane deflection amplitude. We used this platform to study the cyclic compression of several different silicone samples and thereby measured their elastic moduli. The results obtained using our miniaturized platform were in excellent agreement with those obtained using a commercially available mechanical testing platform and clearly demonstrated the utility of our platform for the mechanical testing of small samples in parallel. The miniaturized platform can significantly increase mechanical testing efficiency, particularly when testing of iterative sample formulations is required.