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Multichannel Cell Detection in Microcompartments by Means of True Parallel Measurements using the Solartron S-1260

Designing proper frontend electronics is critical in the development of highly sophisticated electrode systems. Multielectrode arrays for measuring electrical signals or impedance require multichannel readout systems. Even more challenging is the differential or ratiometric configuration with simult...

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Detalles Bibliográficos
Autores principales: Nguyen, T.A., Echtermeyer, D., Barthel, A., Urban, G., Pliquett, U.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Sciendo 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7531105/
https://www.ncbi.nlm.nih.gov/pubmed/33584903
http://dx.doi.org/10.2478/joeb-2020-0008
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author Nguyen, T.A.
Echtermeyer, D.
Barthel, A.
Urban, G.
Pliquett, U.
author_facet Nguyen, T.A.
Echtermeyer, D.
Barthel, A.
Urban, G.
Pliquett, U.
author_sort Nguyen, T.A.
collection PubMed
description Designing proper frontend electronics is critical in the development of highly sophisticated electrode systems. Multielectrode arrays for measuring electrical signals or impedance require multichannel readout systems. Even more challenging is the differential or ratiometric configuration with simultaneous assessment of measurement and reference channels. In this work, an eight-channel frontend was developed for contacting a 2×8 electrode array (8 measurement and 8 reference electrodes) with a large common electrode to the impedance gain-phase analyzer Solartron 1260 (S-1260). Using the three independent and truly parallel monitor channels of the S-1260, impedance of trapped cells and reference material was measured at the same time, thereby considerably increasing the performance of the device. The frontend electronics buffers the generator output and applies a potentiostatic signal to the common electrode of the chip. The applied voltage is monitored using the current monitor of the S-1260 via voltage/current conversion. The frontend monitors the current through the electrodes and converts it to a voltage fed into the voltage monitors of the S-1260. For assessment of the 8 electrode pairs featured by the chip, a relay-based multiplexer was implemented. Extensive characterization and calibration of the frontend were carried out in a frequency range between 100 Hz and 1 MHz. Investigating the influence of the multiplexer and the frontend electronics, direct measurement with and without frontend was compared. Although differences were evident, they have been negligible below one per cent. The significance of measurement using the complex S-1260-frontend-electrode was tested using Kohlrausch's law. The impedance of an electrolytic dilution series was measured and compared to the theoretical values. The coincidence of measured values and theoretical prediction serves as an indicator for electrode sensitivity to cell behavior. Monitoring of cell behavior on the microelectrode surface will be shown as an example.
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spelling pubmed-75311052021-02-11 Multichannel Cell Detection in Microcompartments by Means of True Parallel Measurements using the Solartron S-1260 Nguyen, T.A. Echtermeyer, D. Barthel, A. Urban, G. Pliquett, U. J Electr Bioimpedance Research Articles Designing proper frontend electronics is critical in the development of highly sophisticated electrode systems. Multielectrode arrays for measuring electrical signals or impedance require multichannel readout systems. Even more challenging is the differential or ratiometric configuration with simultaneous assessment of measurement and reference channels. In this work, an eight-channel frontend was developed for contacting a 2×8 electrode array (8 measurement and 8 reference electrodes) with a large common electrode to the impedance gain-phase analyzer Solartron 1260 (S-1260). Using the three independent and truly parallel monitor channels of the S-1260, impedance of trapped cells and reference material was measured at the same time, thereby considerably increasing the performance of the device. The frontend electronics buffers the generator output and applies a potentiostatic signal to the common electrode of the chip. The applied voltage is monitored using the current monitor of the S-1260 via voltage/current conversion. The frontend monitors the current through the electrodes and converts it to a voltage fed into the voltage monitors of the S-1260. For assessment of the 8 electrode pairs featured by the chip, a relay-based multiplexer was implemented. Extensive characterization and calibration of the frontend were carried out in a frequency range between 100 Hz and 1 MHz. Investigating the influence of the multiplexer and the frontend electronics, direct measurement with and without frontend was compared. Although differences were evident, they have been negligible below one per cent. The significance of measurement using the complex S-1260-frontend-electrode was tested using Kohlrausch's law. The impedance of an electrolytic dilution series was measured and compared to the theoretical values. The coincidence of measured values and theoretical prediction serves as an indicator for electrode sensitivity to cell behavior. Monitoring of cell behavior on the microelectrode surface will be shown as an example. Sciendo 2020-07-24 /pmc/articles/PMC7531105/ /pubmed/33584903 http://dx.doi.org/10.2478/joeb-2020-0008 Text en © 2020 T.A. Nguyen et al., published by Sciendo http://creativecommons.org/licenses/by-nc-nd/3.0 This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
spellingShingle Research Articles
Nguyen, T.A.
Echtermeyer, D.
Barthel, A.
Urban, G.
Pliquett, U.
Multichannel Cell Detection in Microcompartments by Means of True Parallel Measurements using the Solartron S-1260
title Multichannel Cell Detection in Microcompartments by Means of True Parallel Measurements using the Solartron S-1260
title_full Multichannel Cell Detection in Microcompartments by Means of True Parallel Measurements using the Solartron S-1260
title_fullStr Multichannel Cell Detection in Microcompartments by Means of True Parallel Measurements using the Solartron S-1260
title_full_unstemmed Multichannel Cell Detection in Microcompartments by Means of True Parallel Measurements using the Solartron S-1260
title_short Multichannel Cell Detection in Microcompartments by Means of True Parallel Measurements using the Solartron S-1260
title_sort multichannel cell detection in microcompartments by means of true parallel measurements using the solartron s-1260
topic Research Articles
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7531105/
https://www.ncbi.nlm.nih.gov/pubmed/33584903
http://dx.doi.org/10.2478/joeb-2020-0008
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