PLoS ONE (Jan 2020)

A simultaneous optical and electrical in-vitro neuronal recording system to evaluate microelectrode performance.

  • Zaid Aqrawe,
  • Nitish Patel,
  • Yukti Vyas,
  • Mahima Bansal,
  • Johanna Montgomery,
  • Jadranka Travas-Sejdic,
  • Darren Svirskis

DOI
https://doi.org/10.1371/journal.pone.0237709
Journal volume & issue
Vol. 15, no. 8
p. e0237709

Abstract

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ObjectivesIn this paper, we aim to detail the setup of a high spatio-temporal resolution, electrical recording system utilising planar microelectrode arrays with simultaneous optical imaging suitable for evaluating microelectrode performance with a proposed 'performance factor' metric.MethodsTechniques that would facilitate low noise electrical recordings were coupled with voltage sensitive dyes and neuronal activity was recorded both electrically via a customised amplification system and optically via a high speed CMOS camera. This technique was applied to characterise microelectrode recording performance of gold and poly(3,4-ethylenedioxythiophene)/polystyrene sulfonate (PEDOT/PSS) coated electrodes through traditional signal to noise (SNR) calculations as well as the proposed performance factor.ResultsNeuronal activity was simultaneously recorded using both electrical and optical techniques and this activity was confirmed via tetrodotoxin application to inhibit action potential firing. PEDOT/PSS outperformed gold using both measurements, however, the performance factor metric estimated a 3 fold improvement in signal transduction when compared to gold, whereas SNR estimated an 8 fold improvement when compared to gold.ConclusionThe design and functionality of a system to record from neurons both electrically, through microelectrode arrays, and optically via voltage sensitive dyes was successfully achieved.SignificanceThe high spatiotemporal resolution of both electrical and optical methods will allow for an array of applications such as improved detection of subthreshold synaptic events, validation of spike sorting algorithms and a provides a robust evaluation of extracellular microelectrode performance.