Microelectrode Applications of Pulsed Electrochemical Detection

Pulsed electrochemical detection (PED) has been applied to the direct (i.e., requires no derivatization), sensitive and reproducible detection of numerous polar aliphatic compounds (e.g., carbohydrates, amines, and thiols). These compounds, many of which have biological significance, typically have been classified as non‐electroactive for detection under constant applied potentials and have poor optical detection properties. PED exploits the electrocatalytic activity of noble metal (e.g., Au and Pt) electrode surfaces to oxidize various polar functional groups using multi‐step potential‐time waveforms to realize amperometric/coulometric detection while maintaining uniform and reproducible electrode activity. The response mechanisms in PED are dominated by the surface properties of the electrode, and as a consequence, members of each chemical class of compounds produce virtually identical voltammetric responses. Thus, the full analytical potential is achieved when combined with an a priori separation. Although popularized in combination with high performance liquid chromatography, the combination of PED with highly efficient microseparation techniques offer the analyst unique advantages. This paper reviews the fundamental aspects of PED especially at microelectrodes, and its application in microchromatographic and electrophoretic separation techniques, including microchip devices.