The Arch Electrode: A Novel Dry Electrode Concept for Improved Wearing Comfort

Vasconcelos, Beatriz; Fiedler, Patrique; Machts, René; Haueisen, Jens; Fonseca, C.

doi:10.3389/fnins.2021.748100

Cited by 11 publications

(19 citation statements)

References 53 publications

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“…The corresponding measurements indicate an OCP with the on-skin electrolyte of about 38 ± 6 mV, with negligible potential drift (figure S9). This compares well with current literature using an equal input voltage of 5 mV, for example the OCP (∼58 mV) of Ag/AgCl coated polyurethane based dry electrodes [50].…”

Section: Surface Conditioning Mechanismsupporting

confidence: 89%

Non-invasive on-skin sensors for brain machine interfaces with epitaxial graphene

et al. 2021

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Brain-machine interfaces are key components for the development of hands-free, brain -controlled devices. Electroencephalogram (EEG) electrodes are particularly attractive for harvesting the neural signals in a non-invasive fashion. Here, we explore the use of epitaxial graphene grown on silicon carbide on silicon for detecting the electroencephalogram signals with high sensitivity. This dry and non-invasive approach exhibits a markedly improved skin contact impedance when benchmarked to commercial dry electrodes, as well as superior robustness, allowing prolonged and repeated use also in a highly saline environment. In addition, we report the newly -observed phenomenon of surface conditioning of the epitaxial graphene electrodes. The prolonged contact of the epitaxial graphene with the skin electrolytes functionalize the grain boundaries of the graphene, leading to the formation of a thin surface film of water through physisorption and consequently reducing its contact impedance by more than 75%. This effect is primed in highly saline environments, and could be also further tailored as pre-conditioning to enhance the performance and reliability of the epitaxial graphene sensors.

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Section: Surface Conditioning Mechanismsupporting

confidence: 89%

Non-invasive on-skin sensors for brain machine interfaces with epitaxial graphene

et al. 2021

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“…Wireless, dry EEG provides additional bene ts over wet or gel-based EEG methods. Dry EEG has a fast setup time (5-10 minutes, as in the current and previous study 14 ), can be used in environments where gels are not allowed 38 , and avoids the need for re-application of gel in prolonged experiments 39 . With the advent of EEG systems that are dry and mobile also comes the need to determine the effect of motion on EEG signal 40,41 .…”

Section: Discussionmentioning

confidence: 85%

Dry EEG measurement of P3 to evaluate cognitive load during sitting, standing, and walking

Swerdloff¹,

Hargrove

2022

Preprint

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Combining brain imaging with dual-task paradigms provides a quantitative, direct metric of cognitive load that is agnostic to the motor task. To better understand the impact of cognitive load during activities of daily living, we measured brain activity from a dry electroencephalography headset as participants attended to a stimulus paradigm eliciting event-related potentials during sitting, standing, and walking. The stimulus paradigm consisted of an auditory oddball task in which they had to report the number of oddball tones that were heard during each motor task. The P3 event-related potential, which is inversely proportional to cognitive load, was extracted from electroencephalographic signals in each condition. Results showed that P3 was significantly lower during walking compared to sitting (p = .039), indicating that cognitive load was higher during walking compared to the other activities. No significant differences in P3 were found between sitting and standing. Head motion did not have a significant impact on the measurement of cognitive load. These results encourage the use of a dry electroencephalography system to further investigate cognitive load during dynamic activities in individuals with and without motor impairments.

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“…Dry electrodes use traces of moisture and sweat as electrolytes at the skin–electrode interface, therefore they do not require gels or pastes. ,, These electrodes are less prone to change over time while causing minimal skin irritation. However, it is necessary to compensate for the lack of electrolytes by improving the skin’s contact.…”

Section: Scalp Eegmentioning

confidence: 99%

Advances in Electrode Materials for Scalp, Forehead, and Ear EEG: A Mini-Review

Petrossian

Kateb

Miquet-Westphal

et al. 2023

ACS Appl. Bio Mater.

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Electroencephalogram (EEG) records the electrical activity of neurons in the cerebral cortex and is used extensively to diagnose, treat, and monitor psychiatric and neurological conditions. Reliable contact between the skin and the electrodes is essential for achieving consistency and for obtaining electroencephalographic information. There has been an increasing demand for effective equipment and electrodes to overcome the time-consuming and cumbersome application of traditional systems. Recently, ear-centered EEG has met with growing interest since it can provide good signal quality due to the proximity of the ear to the brain. In addition, it can facilitate mobile and unobtrusive usage due to its smaller size and ease of use, since it can be used without interfering with the patient’s daily activities. The purpose of this mini-review is to first introduce the broad range of electrodes used in conventional (scalp) EEG and subsequently discuss the state-of-the-art literature about around- and in-the-ear EEG.

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The Arch Electrode: A Novel Dry Electrode Concept for Improved Wearing Comfort

Cited by 11 publications

References 53 publications

Non-invasive on-skin sensors for brain machine interfaces with epitaxial graphene

Non-invasive on-skin sensors for brain machine interfaces with epitaxial graphene

Dry EEG measurement of P3 to evaluate cognitive load during sitting, standing, and walking

Advances in Electrode Materials for Scalp, Forehead, and Ear EEG: A Mini-Review

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