Autor: |
Saucedo-Espinosa MA; Microscale Bioseparations Laboratory, Rochester Institute of Technology , Rochester, New York 14623, USA., Lapizco-Encinas BH; Microscale Bioseparations Laboratory, Rochester Institute of Technology , Rochester, New York 14623, USA. |
Jazyk: |
angličtina |
Zdroj: |
Biomicrofluidics [Biomicrofluidics] 2016 Jun 03; Vol. 10 (3), pp. 033104. Date of Electronic Publication: 2016 Jun 03 (Print Publication: 2016). |
DOI: |
10.1063/1.4953183 |
Abstrakt: |
Current monitoring is a well-established technique for the characterization of electroosmotic (EO) flow in microfluidic devices. This method relies on monitoring the time response of the electric current when a test buffer solution is displaced by an auxiliary solution using EO flow. In this scheme, each solution has a different ionic concentration (and electric conductivity). The difference in the ionic concentration of the two solutions defines the dynamic time response of the electric current and, hence, the current signal to be measured: larger concentration differences result in larger measurable signals. A small concentration difference is needed, however, to avoid dispersion at the interface between the two solutions, which can result in undesired pressure-driven flow that conflicts with the EO flow. Additional challenges arise as the conductivity of the test solution decreases, leading to a reduced electric current signal that may be masked by noise during the measuring process, making for a difficult estimation of an accurate EO mobility. This contribution presents a new scheme for current monitoring that employs multiple channels arranged in parallel, producing an increase in the signal-to-noise ratio of the electric current to be measured and increasing the estimation accuracy. The use of this parallel approach is particularly useful in the estimation of the EO mobility in systems where low conductivity mediums are required, such as insulator based dielectrophoresis devices. |
Databáze: |
MEDLINE |
Externí odkaz: |
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