Stationary-state oxidized platinum microsensor for selective and on-line monitoring of nitric oxide in biological preparations.

Despite the multifaceted biomedical significance of NO, little progress has been achieved so far in the quantitative understanding of the signal transduction mechanisms where NO is involved. To help progress in this area, we propose a simple electrochemical NO sensor here, consisting of a glass sealed platinum microdisk electrode coated with cellulose acetate to reduce both surface fouling by proteins and response to potential interferences. A differential amperometry protocol is optimized to improve selectivity and provide a stationary oxidation state of the platinum surface, which prevents loss in sensitivity during long-term use. We found the oxidation of NO by O2 second order in [NO] with a rate constant of (8.0 +/- 0.4) x 10(6) M(-2) s(-1), in good agreement with literature data obtained by other than electrochemical methods. The release rates of NO detected in cultures of activated macrophages were on the order of 20 pmol/ (10(6)cells s) and correlated well with the nitrite content determined by the spectrophotometric Griess assay.

Rotating sample system: an equivalent of a rotating electrode for microliter samples.

Voltammetric experiments in sample droplets of 20 microL volume were carried out with gold ring electrodes microfabricated on Pyrex substrates. The droplet studied was centered and kept in place by a hydrophobic ring deposited on the substrate around the ring electrode, which also ensured that each sample assume a semispherical shape. A small hole in the center of the substrate filled with an agar gel membrane served as a junction. A mild jet of humidified nitrogen gas directed tangentially at the droplet caused it to rotate at a high rate. Cyclic voltammetry and constant-potential electrolysis of potassium ferricyanide were used to characterize this rotating sample system and to calculate diffusion layer thickness. The results clearly demonstrate that rotating of a semispherical microsample placed above a stationary ring electrode with a mild gas jet can be as effective as a rotating electrode system. As a practical example, voltammetric stripping analysis of 20-120 pmol mercuric nitrate samples was performed with a calibration of good linearity (r2 = 0.988) and a time constant for exhaustive electrolysis of approximately 2 min.