Biomimetic chemical sensors using nanoelectronic readout of olfactory receptor proteins.

We have designed and implemented a practical nanoelectronic interface to G-protein coupled receptors (GPCRs), a large family of membrane proteins whose roles in the detection of molecules outside eukaryotic cells make them important pharmaceutical targets. Specifically, we have coupled olfactory receptor proteins (ORs) with carbon nanotube transistors. The resulting devices transduce signals associated with odorant binding to ORs in the gas phase under ambient conditions and show responses that are in excellent agreement with results from established assays for OR-ligand binding. The work represents significant progress on a path toward a bioelectronic nose that can be directly compared to biological olfactory systems as well as a general method for the study of GPCR function in multiple domains using electronic readout.

Theory for the impact of basal turnover on dopamine clearance kinetics in the rat striatum after medial forebrain bundle stimulation and pressure ejection.

Although microdialysis measurements suggest that extracellular dopamine concentrations in the rat striatum are in the low nanomolar range, some recent voltammetry studies suggest that the concentration may be considerably higher, perhaps in the micromolar range. The presence of such high dopamine levels in the extracellular space has to be rationalized with the rapid, linear clearance of extracellular dopamine observed after electrical stimulation of the medial forebrain bundle. Kinetic analysis of dopamine clearance after evoked release suggests that the basal extracellular dopamine concentration is below the K(M) of dopamine uptake, which is near 0.2 microm. However, dopamine clearance after pressure ejection of dopamine into the rat striatum is slow and non-linear, which may alternatively be a sign that basal dopamine release is only slightly slower than the maximal velocity of dopamine uptake, Vmax. A high basal extracellular dopamine concentration would exist if basal dopamine release were only slightly slower than the Vmax of uptake. This report introduces a new kinetic analysis of dopamine uptake that sheds light on the possible source of the different clearance rates observed following evoked dopamine release and dopamine pressure ejection. Furthermore, the analysis rationalizes the rapid dopamine clearance after evoked release with the possibility that basal extracellular dopamine levels are above the K(M) of the transporter.