Prototyping disposable electrophoresis microchips with electrochemical detection using rapid marker masking and laminar flow etching.

Two novel methods are described for the fabrication of components for microchip capillary electrophoresis with electrochemical detection (microchip CEEC) on glass substrates. First, rapid marker masking is introduced as a completely nonphotolithographic method of patterning and fabricating integrated thin-film metal electrodes onto a glass substrate. The process involves applying the pattern directly onto the metal layer with a permanent marker that masks the ensuing chemical etch.

Identification of cellular sections with imaging mass spectrometry following freeze fracture.

Freeze-fracture techniques have been used to maintain chemical heterogeneity of frozen-hydrated mammalian cells for static TOF-SIMS imaging. The effects the fracture plane has on scanning electron microscopy and dynamic SIMS images of cells have been studied, but the implications this preparation method has on static SIMS have not been addressed to date. Interestingly, the chemical specificity and surface sensitivity of TOF-SIMS have allowed the identification of unique sections of rat pheochromocytoma cells exposed to the sample surface during freeze fracture.

Imaging of freeze-fractured cells with in situ fluorescence and time-of-flight secondary ion mass spectrometry.

Bioanalytical imaging techniques have been employed to investigate cellular composition at the single-cell and subcellular regimes. Four imaging modes have been performed sequentially in situ to demonstrate the utility of a more integrated approach to imaging cells. The combination of bright-field, scanning ion, and fluorescence microscopy complements TOF-SIMS imaging of native biomolecules.

Dual fluorescence and electrochemical detection on an electrophoresis microchip.

Simultaneous amperometric and fluorescence detection in a microfabricated electrophoresis chip is reported. Detection limits of 448 nM and 1.52, 16, and 28 microM have been achieved for dopamine, catechol, NBD-arginine, and NBD-phenylalanine, respectively.