Overoxidation of carbon-fiber microelectrodes enhances dopamine adsorption and increases sensitivity
Analyst, 2003•pubs.rsc.org
The voltammetric responses of carbon-fiber microelectrodes with a 1.0 V and a 1.4 V anodic
limit were compared in this study. Fast-scan cyclic voltammetry was used to characterize the
response to dopamine and several other neurochemicals. An increase in the adsorption
properties of the carbon fiber leads to an increase in sensitivity of 9 fold in vivo. However the
temporal response of the sensor is slower with the more positive anodic limit. Increased
electron transfer kinetics also causes a decrease in the relative sensitivity for dopamine vs …
limit were compared in this study. Fast-scan cyclic voltammetry was used to characterize the
response to dopamine and several other neurochemicals. An increase in the adsorption
properties of the carbon fiber leads to an increase in sensitivity of 9 fold in vivo. However the
temporal response of the sensor is slower with the more positive anodic limit. Increased
electron transfer kinetics also causes a decrease in the relative sensitivity for dopamine vs …
The voltammetric responses of carbon-fiber microelectrodes with a 1.0 V and a 1.4 V anodic limit were compared in this study. Fast-scan cyclic voltammetry was used to characterize the response to dopamine and several other neurochemicals. An increase in the adsorption properties of the carbon fiber leads to an increase in sensitivity of 9 fold in vivo. However the temporal response of the sensor is slower with the more positive anodic limit. Increased electron transfer kinetics also causes a decrease in the relative sensitivity for dopamine vs. other neurochemicals, and a change in their cyclic voltammograms. Stimulated release in the caudate-putamen was pharmacologically characterized in vivo using Ro-04-1284 and pargyline, and was consistent with that expected for dopamine.
The Royal Society of Chemistry