Microelectrodes for the measurement of catecholamines in biological systems.

Many of the molecules involved in biological signaling processes are easily oxidized and have been monitored by electrochemical methods. Temporal response, spatial considerations, and sensitivity of the electrodes must be optimized for the specific biological application. To monitor exocytosis from single cells in culture, constant potential amperometry offers the best temporal resolution, and a low-noise picoammeter improves the detection limits. Smaller electrodes, with 1-micron diameters, provided spatial resolution sufficient to identify the locations of release sites on the surface of single cells. For the study of neurotransmitter release in vivo, larger cylindrical microelectrodes are advantageous because the secreted molecules come from multiple terminals near the electrode, and the greater amounts lead to a larger signal that emerges from the Johnson noise of the current amplifier. With this approach, dopamine release elicited by two electrical stimulus pulses at 10 Hz was detected with fastscan cyclic voltammetry in vivo. Nafion-coated elliptical electrodes have previously been shown to be incapable of detecting such concentration changes without extensive signal averaging. In addition, we demonstrate that high-pass filtering (200 Hz) of cyclic voltammograms recorded at 300 V/s decreases the background current and digitization noise at these microelectrodes, leading to an improved signal. Also, high-pass filtering discriminated against ascorbic acid, DOPAC, and acidic pH changes, three common interferences in vivo.

Vesicular quantal size measured by amperometry at chromaffin, mast, pheochromocytoma, and pancreatic beta-cells.

Amperometric detection of exocytosis at single chromaffin cells has shown that the distribution of spike areas, or quantal size, is dependent on the volume and catecholamine concentration of individual secretory vesicles. The present work offers an alternate, simplified model to analyze the current spikes due to single exocytotic events. When the cube root of these spike areas is plotted as a histogram, a Gaussian distribution is obtained for chromaffin cells and also mast, pheochromocytoma, and pancreatic beta-cells. It was found that the relative SD of these distributions is similar to that for the vesicular radii, which also have a Gaussian distribution in all four cell types. In addition, this model was used to evaluate conditions where the quantal size of individual events was altered. When chromaffin cells were maintained in culture for < 6 days, spikes of approximately double the quantal size were obtained on repeated exposure to 60 mM K+. The results suggest a heterogeneous distribution of catecholamine-containing vesicles at later days in culture is responsible for this alteration.

Simultaneous amperometric measurement of ascorbate and catecholamine secretion from individual bovine adrenal medullary cells.

Secretion of ascorbate and catecholamines from single bovine adrenal medullary cells has been detected with amperometry at carbon-fiber microelectrodes. Two carbon-fiber electrodes were employed. One was beveled, and voltammograms at this electrode showed overlap of the responses for ascorbate and the catecholamines. The other was beveled and electrochemically oxidized to shift the ascorbate oxidation wave to potentials more negative than that of the catecholamines. Thus, at an applied potential of 0.05 V vs SSCE, ascorbate was selectively oxidized at the treated electrode and both catecholamines and ascorbate were oxidized at an applied potential of 0.65 V at the untreated electrode. Exocytotic release from the cell was stimulated with K+, nicotine, and digitonin. Nicotine and K+ depolarize the cell membrane and elicit vesicular release. Digitonin is a detergent that reacts with cholesterol in the plasma membrane and causes the formation of pores. Ascorbate efflux from individual cells could be induced by digitonin but not by K+ or nicotine and was observed as a single peak with a full width at half-maximum of 4 s. In contrast, catecholamine release was observed as many rapid, sequential current spikes when the cell was exposed to either digitonin, K+, or nicotine. The two different types of release show that ascorbate and catecholamines are being released from two different cellular compartments. The calcium independence of the digitonin-induced ascorbate release provides additional evidence that ascorbate is released by a nonexocytotic process.