In-Channel Electrochemical Detection for Microchip Capillary Electrophoresis Using an Electrically Isolated Potentiostat

Martin, R. Scott; Ratzlaff, K.; Huynh, and Bryan H.; Lunte, Susan M.

doi:10.1021/ac011087p

Cited by 182 publications

(181 citation statements)

References 52 publications

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“…However, electrochemical detection (ECD) offers specific advantages for microfluidic systems due to its small size, portability, low cost, high sensitivity, and high selectivity using a proper choice of detection potential and/or electrode material [8]. An additional advantage of ECD is the simplicity of the instrumentation, resulting in low electrical power requirements for in-field use [9][10][11][12]. Electrochemical impedance spectroscopy (EIS) is a sensitive analysis method for biological samples [13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Polymer microchip impedance spectroscopy through two parallel planar embedded microelectrodes: Understanding the impedance contribution of the surrounding polymer on the measurement accuracy

Kechadi

Gamby

Chaal

et al. 2013

Electrochimica Acta

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a b s t r a c tThe present work describes a new methodology for contact free impedance of a solution in a polymer microchip taking into account the role played by the surrounding polymer on the impedance accuracy. Measurements were carried out using a photoablated polyethylene terephthalate (PET) microchannel above two embedded microband electrodes. The impedance diagrams exhibit a loop from high frequencies to medium frequencies (1 MHz-100 Hz) and a capacitive behavior at low frequencies (100-1 Hz). The impedance diagrams were corrected by eliminating from the global microchip response the contribution of the impedance of the PET layer between the two microband electrodes. This operation enables a clear observation of the impedance in the microchannel solution, including the bulk solution contribution and the interfacial capacitance related to the surface roughness of the photoablated microchannel. Models for the impedance of solutions of varying conductivity showed that the capacitance of the polymer-solution interface can be modeled by a constant phase element (CPE) with an exponent of 0.5. The loop diameter was found to be proportional to the microchannel resistivity, allowing a cell constant around 4.93 × 10 5 m −1 in contactless microelectrodes configuration.

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Section: Introductionmentioning

confidence: 99%

Polymer microchip impedance spectroscopy through two parallel planar embedded microelectrodes: Understanding the impedance contribution of the surrounding polymer on the measurement accuracy

Kechadi

Gamby

Chaal

et al. 2013

Electrochimica Acta

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“…There is one repot of contact-less integrated ECD with independent battery power and optical communication interface [324].…”

Section: Electrochemical Detection (Ecd)-electrochemical Detection (Ementioning

confidence: 99%

“…Interesting design of inchannel ED for microchip HPCE which uses optically isolated RS-232 port has recently been published by Martin et al [324,366]. Optimization of separation/recordings with CEECD yields overall LOD values for different analytes in the 10 −6 -10 −7 M range.…”

Section: Electrochemical Detection (Ecd)-electrochemical Detection (Ementioning

confidence: 99%

Bioanalytical profile of the l-arginine/nitric oxide pathway and its evaluation by capillary electrophoresis

Boudko

2007

Journal of Chromatography B

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This review briefly summarizes recent progress in fundamental understanding and analytical profiling of the L-arginine/nitric oxide (NO) pathway. It focuses on key analytical references of NO actions and on the experimental acquisition of these references in vivo, with capillary electrophoresis (CE) and high-performance capillary electrophoresis (HPCE) comprising one of the most flexible and technologically promising analytical platform for comprehensive high-resolution profiling of NO-related metabolites. Second aim of this review is to express demands and bridge efforts of experimental biologists, medical professionals and chemical analysis-oriented scientists who strive to understand evolution and physiological roles of NO and to develop analytical methods for use in biology and medicine.

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“…Different electrochemical detection methods have been proposed for CE, either amperometric or potentiometric with the electrodes being located either at the end of the column or directly in or on the column. In-or on-column methods are superior for maintaining the separation power of CE, and are easier to integrate for chip electrophoresis, as it is possible to integrate the detection electrodes during the microfabrication process [7,8]. The electric coupling of the high voltage necessary for the electrophoretic separation and the low electric signals used for the electrochemical detection has been a major technological hurdle and has limited the wider development and applications of electrochemical detection.…”

Section: Introductionmentioning

confidence: 99%

On‐column conductivity detection in capillary‐chip electrophoresis

Fang

Josserand

2007

Electrophoresis

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On-column conductivity detection in capillary-chip electrophoresis was achieved by actively coupling the high electric field with two sensing electrodes connected to the main capillary channel through two side detection channels. The principle of this concept was demonstrated by using a glass chip with a separation channel incorporating two double-Ts. One double-T was used for sample introduction, and the other for detection. The two electrophoresis electrodes apply the high voltage and provide the current, and the two sensing electrodes connected to the separation channel through the second double-T and probe a potential difference. This potential difference is directly related to the local resistance or the conductivity of the solution defined by the two side channels on the main separation channel. A detection limit of 15 mM (600 ppb or 900 fg) was achieved for potassium ion in a 2 mM Tris-HCl buffer (pH 8.7) with a linear range of 2 orders of magnitude without any stacking. The proposed detection method avoids integrating the sensing electrodes directly within the separation channel and prevents any direct contact of the electrodes with the sample. The baseline signal can also be used for online monitoring of the electric field strength and electroosmosis mobility characterization in the separation channel.

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In-Channel Electrochemical Detection for Microchip Capillary Electrophoresis Using an Electrically Isolated Potentiostat

Cited by 182 publications

References 52 publications

Polymer microchip impedance spectroscopy through two parallel planar embedded microelectrodes: Understanding the impedance contribution of the surrounding polymer on the measurement accuracy

Polymer microchip impedance spectroscopy through two parallel planar embedded microelectrodes: Understanding the impedance contribution of the surrounding polymer on the measurement accuracy

Bioanalytical profile of the l-arginine/nitric oxide pathway and its evaluation by capillary electrophoresis

On‐column conductivity detection in capillary‐chip electrophoresis

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