2020
DOI: 10.1101/2020.05.30.125070
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Electrical properties, accuracy, and multi-day performance of gelatine phantoms for electrophysiology

Abstract: Gelatine based phantoms for electrophysiology are becoming widely used as they allow the controlled validation of new electrode and new instrumentation designs. The phantoms mimic the electrical properties of the human body and allow a pre-recorded electrophysiology signal to be played-out, giving a known signal for the novel electrode or instrumentation to collect. Such controlled testing is not possible with on-person experiments where the signal to be recorded is intrinsically unknown. However, despite the … Show more

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Cited by 15 publications
(20 citation statements)
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“…Owda and Casson: Gelatine phantoms for electrophysiology available at [39] which contains the same results.…”
Section: Introductionmentioning
confidence: 99%
“…Owda and Casson: Gelatine phantoms for electrophysiology available at [39] which contains the same results.…”
Section: Introductionmentioning
confidence: 99%
“…When constructing the phantom, we only measured the impedance magnitude of the conductive medium. In the next generation phantoms, it is recommended to measure also the impedance phase to makes sure, the phantom perfectly fulfills the quasi-static conditions (Owda and Casson, 2020). However, given the recent measurements in a NaCl based gelatin phantom (Owda and Casson, 2020), it is unlikely that the simple NaCl solution used here would show strong impedance phase within the typical operating frequency range of tACS.…”
Section: Phantom Vs Human Headmentioning
confidence: 99%
“…The main rationale behind realizing a hardware demonstrator was that it allowed to acquire data with the full instrumental chain-stimulator, electrode leads, and EEG recorder-in the actual laboratory environment, i.e., including the real power-line interferences (50 Hz and harmonics), amplifier noise and non-linearities, as well as stimulator noise and harmonics. We refrained from using a 3d multi-layer head phantom, like the ones discussed by Owda and Casson (2020) and Vosskuhl et al (2020), as our aim was to obtain sample EEG data for our testing purposes only. Furthermore, we were also not concerned with volume vs. scalp conduction or capacitive electrode impedance effects.…”
Section: Setup and Data Recordingmentioning
confidence: 99%