Carbon Nanotube-Based Microelectrodes for Enhanced Neurochemical Detection.

Carbon nanotube (CNT) fiber microelectrodes have been developed as electrode materials for the detection of neurotransmitters using fast scan cyclic voltammetry (FSCV). We have used acid-wet spinning to create "neat" carbon nanotube fibers and utilized them as electrode materials. Thirty-forty micron diameter acid spun CNT fiber microelectrodes were more sensitive than PEI-CNT fiber microelectrodes, with a 3 nM limit of detection. They also had faster electron transfer kinetics and a greater reversibility for the oxidation of dopamine using FSCV than CFMEs and other carbon nanomaterials. The acid spun CNT fiber microelectrodes also displayed a frequency independent response for the peak oxidation current of dopamine. This property was also seen in other CNT materials such as PEI-CNT fiber microelectrodes and CNT-Yarn microelectrodes. Upon varying the frequency from 10 Hz to 100 Hz, there was no decrease in sensitivity. When scanning at 2,000 V/s, there was no decrease in sensitivity upon changing the frequency from 10 Hz to 500 Hz. This could potentially allow for a 2 ms sampling rate for FSCV, comparable to those used with amperometry as opposed to 100 ms temporal resolution of traditional FSCV, an almost two orders of magnitude difference. Since the frequency independent response is seen with many CNT fibers/yarns, it suggests it is a fundamental property of the CNTs shared by many types of CNT fibers and yarns.

A1 receptors self-regulate adenosine release in the striatum: evidence of autoreceptor characteristics.

Adenosine A(1) receptors are inhibitory G-protein coupled receptors that presynaptically regulate neurotransmitter release, but their role in self-regulating adenosine release is not known. In this study, we examined the modulation of evoked adenosine and dopamine efflux by A(1) receptors and studied whether D(1) receptors mediate these effects. Fast-scan cyclic voltammetry at carbon-fiber microelectrodes was used for the simultaneous detection of adenosine and dopamine efflux on a subsecond time scale. Short electrical stimulation trains delivered to the substantia nigra (60 pulses, 60 Hz) were used to evoke dopamine and adenosine release in the striatum. The adenosine A(1) receptor agonist N(6)-cyclopentyladenosine (CPA, 1 mg/kg, i.p.) decreased both adenosine and dopamine efflux, although the effect for adenosine occurred more quickly than for dopamine. The A(1) antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX, 6 mg/kg, i.p.) increased stimulated adenosine release. The effects of CPA were partially attenuated by the dopamine D(1) receptor antagonist SCH-23390. Thus, A(1) and D(1) receptors have a synergistic interaction that modulates both stimulated adenosine and dopamine. The decrease in adenosine is not a downstream effect of lowered dopamine release, as decreasing dopamine synthesis and release with α-methyl-p-tyrosine or increasing release with haloperidol had no effect on adenosine release. This study shows that A(1) receptors have some characteristics of an autoreceptor, including self-regulation of adenosine release.

A role for presynaptic mechanisms in the actions of nomifensine and haloperidol.

Psychomotor stimulants and neuroleptics exert multiple effects on dopaminergic signaling and produce the dopamine (DA)-related behaviors of motor activation and catalepsy, respectively. However, a clear relationship between dopaminergic activity and behavior has been very difficult to demonstrate in the awake animal, thus challenging existing notions about the mechanism of these drugs. The present study examined whether the drug-induced behaviors are linked to a presynaptic site of action, the DA transporter (DAT) for psychomotor stimulants and the DA autoreceptor for neuroleptics. Doses of nomifensine (7 mg/kg i.p.), a DA uptake inhibitor, and haloperidol (0.5 mg/kg i.p.), a dopaminergic antagonist, were selected to examine characteristic behavioral patterns for each drug: stimulant-induced motor activation in the case of nomifensine and neuroleptic-induced catalepsy in the case of haloperidol. Presynaptic mechanisms were quantified in situ from extracellular DA dynamics evoked by electrical stimulation and recorded by voltammetry in the freely moving animal. In the first experiment, the maximal concentration of electrically evoked DA ([DA](max)) measured in the caudate-putamen was found to reflect the local, instantaneous change in presynaptic DAT or DA autoreceptor activity according to the ascribed action of the drug injected. A positive temporal association was found between [DA](max) and motor activation following nomifensine (r=0.99) and a negative correlation was found between [DA](max) and catalepsy following haloperidol (r=-0.96) in the second experiment. Taken together, the results suggest that a dopaminergic presynaptic site is a target of systemically applied psychomotor stimulants and regulates the postsynaptic action of neuroleptics during behavior. This finding was made possible by a voltammetric microprobe with millisecond temporal resolution and its use in the awake animal to assess release and uptake, two key mechanisms of dopaminergic neurotransmission. Moreover, the results indicate that presynaptic mechanisms may play a more important role in DA-behavior relationships than is currently thought.