Extended sawhorse waveform for stable zinc detection with fast-scan cyclic voltammetry

• Published in: Analytical and bioanalytical chemistry Vol. 413; no. 27; pp. 6727 - 6735
• Main Authors: Perry, Anntonette N., Cryan, Michael T., Ross, Ashley E.
• Format: Journal Article
• Language: English
• Published: Berlin/Heidelberg Springer Berlin Heidelberg 01.11.2021; Springer; Springer Nature B.V
• Subjects: Analysis; Analytical Chemistry; Biochemistry; Brain; Carbon; Characterization and Evaluation of Materials; Chemistry; Chemistry and Materials Science; Cleaning; Divalent cations; Electrochemistry; Electrochemistry for Neurochemical Analysis; Electrodes; Food Science; Frames; Gene expression; Heterogeneity; Intracellular; Laboratory Medicine; Methods; Microelectrodes; Monitoring; Monitoring/Environmental Analysis; Neural plasticity; Neurotransmitters; Research Paper; Sawing; Signal transduction; Signaling; Spatial heterogeneity; Synaptic plasticity; Voltammetry; Waveforms; Zinc; United States; Metallotransmitter; Electrochemistry; Carbon-fiber microelectrodes; Metals
• ISSN: 1618-2642; 1618-2650
• DOI: 10.1007/s00216-021-03529-8

Zinc (Zn(II)) is a divalent cation involved in regulating intracellular signal transduction and gene expression through transcription factor activity, and can act as a metal neurotransmitter by modulating synaptic activity and neuronal plasticity. Previous research has demonstrated spatial heterogeneity of Zn(II) in the brain, has estimated extracellular concentrations of Zn(II) across various brain regions, and has measured rapid intracellular changes in Zn(II) concentration during glutamate flux. Despite this work, quantification of rapid extracellular Zn(II) release from neurons, on a millisecond time scale, in real time has remained difficult with existing technologies. Here, we have developed an electrochemical waveform, called the “extended sawhorse waveform (ESW),” for fast-scan cyclic voltammetry detection at carbon-fiber microelectrodes which enabled rapid and stable Zn(II) monitoring over time. This waveform was developed to overcome existing challenges in monitoring metallotransmitters stably over time electrochemically by introducing a brief cleaning step to facilitate rapid cleaning of the electrode surface in between scans. The ESW scans from 0.5 V down to −1.0 V, up to 1.45 V for 3 ms (cleaning step), and back to 0.5 V at a scan rate of 400 V/s. Repeated introductions of Zn(II) at the electrode using a traditional waveform cause plating which ultimately deteriorates the sensitivity over time; however, using the ESW, significant improvements in stability were observed. Overall, we provide a unique approach to monitor and quantitate rapid Zn(II) signaling in the brain at carbon electrodes which will impact our ability to advance fundamental knowledge of Zn(II) involvement in extracellular signaling pathways in the brain. Graphical abstract