Simplified current decoupler for microchip capillary electrophoresis with electrochemical and pulsed amperometric detection.

There is a need to develop broadly applicable, highly sensitive detection methods for microchip CE that do not require analyte derivatization. LIF is highly sensitive but typically requires analyte derivatization. Electrochemistry provides an alternative method for direct analyte detection; however, in its most common form, direct current (DC) amperometry, it is limited to a small number of easily oxidizable or reducible analytes. Pulsed amperometric detection (PAD) is an alternative waveform that can increase the number of electrochemically detectable analytes. Increasing sensitivity for electrochemical detection (EC) and PAD requires the isolation of detection current (nA) from the separation current (muA) in a process generally referred to as current decoupling. Here, we present the development of a simple integrated decoupler to improve sensitivity and its coupling with PAD. A Pd microwire is used as the cathode for decoupling and a second Au or Pt wire is used as the working electrode for either EC or PAD. The electrode system is easy to make, requiring no clean-room facilities or specialized metallization systems. Sensitive detection of a wide range of analytes is shown to be possible using this system. Using this system we were able to achieve detection limits as low as 5 nM for dopamine, 74 nM for glutathione, and 100 nM for glucose.

Separation of phosphorylated sugars using capillary electrophoresis with indirect photometric detection.

Adenosine monophosphate (AMP) and naphthalene disulfonate (NDS) have been characterized as electrolytes for the indirect photometric detection of phosphorylated sugars and other organophosphorus compounds of biochemical interest. This work has resulted in the CE separation on an uncoated capillary using 5 mM AMP and 100 mM boric acid at pH 7.2 of six metabolites (glucose-6-phosphate [G6P], fructose-6-phosphate [F6P]), fructose-1,6-bisphosphate [F-1,6-P], dihydroxyacetone phosphate [DHAP], glyceraldehyde-3-phosphate [G3P], and 2-phosphoglycerate [2-PG] or 3-phosphoglycerate [3-PG]) found in the glycolytic pathway. The detection limits using a 5-sec injection time were between 0.5 and 1 mg/L for these compounds, with the exception of G3P. Resolution between 3-PG and 2-PG is possible by the addition of magnesium ion, although the separation time is longer. A successful separation of five monophosphorylated sugars (G6P, F6P, ribose-5-phosphate [R5P], sucrose-6-phosphate [S6P], and 2-PG) has been performed using the same conditions as for the glycolytic pathway separation. A separation of bisphosphorylated sugars (glucose-1,6-bisphosphate [G-1,6-P],F-1,6-P, ribulose-1,5-bisphosphate [Ru-1, 5P], and sedoheptulose-1,7-bisphosphate [S-1, 7P]) could not be performed with AMP unless magnesium chloride was added. With NDS, a separation of these bisphosphorylated sugars can be obtained without the addition of magnesium chloride.