Multiplexed proteomics using two orders of magnitude enhanced dielectrophoreis: A comprehensive electrical and electrothermal design methodology

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Abstract

We present a methodological approach to analyze an enhanced dielectrophoresis (DEP) system from both a circuit analysis and an electrothermal view points. In our developed model, we have taken into account various phenomena and constraints such as voltage degradation (due to the presence of the protecting oxide layer), oxide breakdown, instrumentation limitations, and thermal effects. The results from this analysis are applicable generally to a wide variety of geometries and high voltage microsystems. Here, these design guidelines were applied to develop a robust electronic actuation system to perform a multiplexed bead-based protein assay. For proof of concept, we illustrated 16-plex actuation capability of our device to elute micron-sized beads that are bound to the surface through anti-IgG and IgG interaction which is on the same order of magnitude in strength as typical antibody-antigen interactions. In addition to its application in multiplexed protein analysis, our platform can be potentially utilized to statistically characterize the strength profile of biological bonds, since the multiplexed format allows for high throughput force spectroscopy using the array of uDEP devices, under the same buffer and assay preparation conditions.

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Emaminejad, S., Barako, M. T., Davis, R. W., Dutton, R. W., Goodson, K. E., & Javanmard, M. (2014). Multiplexed proteomics using two orders of magnitude enhanced dielectrophoreis: A comprehensive electrical and electrothermal design methodology. In Technical Digest - Solid-State Sensors, Actuators, and Microsystems Workshop (pp. 21–23). Transducer Research Foundation. https://doi.org/10.31438/trf.hh2014.6

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