Sensitivity studies and optimization of arrangements of optically pumped magnetometers in simulated magnetoencephalography

Eichardt, Roland; Strohmeier, Daniel; Hunold, Alexander; Machts, René; Haueisen, Jens; Oelsner, G.; Schmidt, Christian B.; Schultze, V.; Stolz, R.; Graichen, Uwe

doi:10.1108/compel-09-2018-0372

Cited by 3 publications

(4 citation statements)

References 13 publications

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“…This led us to use the ABC 160 system, whose inter electrode/sensor distance allows for a full OPM array. Additional computations (Figure S1) have shown that the effect of rotating the tangential axis is negligible for whole‐head systems, in line with other studies (Eichardt et al, 2019). This flexibility in the sensor orientation facilitates the assemble of high density OPM arrays, and therefore worth exploiting.…”

Section: Discussionsupporting

confidence: 90%

“…Even more, this approach seems better suited for practical applications in which the number of sensors available at any moment may vary due to technological glitches, as we have personally experienced with state‐of‐the‐art OPMs. The use of a more thorough methodology, such as combinatorial multilevel optimisation (Eichardt et al, 2019), is planned for future development.…”

Section: Discussionmentioning

confidence: 99%

“…All these perturbations are likely to increase the CRB metrics and consequently worth exploring in more detail. What is more, although this noise model is widely adopted and accepted, it is an idealised version of the real noise found in OPMs (and sensors in general), and therefore more work is needed to represent noise depending on the sensor technology (Eichardt et al, 2019; Oelsner et al, 2019). Second, we utilised the point electrode and sensor models, which are generally adopted in E/MEG, and in OPM research in particular (Duque‐Munoz et al, 2019; Hill et al, 2020; Pfeiffer et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

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Optimal design of on‐scalp electromagnetic sensor arrays for brain source localisation

Beltrachini

Ellenrieder

Eichardt

et al. 2021

Human Brain Mapping

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Optically pumped magnetometers (OPMs) are quickly widening the scopes of noninvasive neurophysiological imaging. The possibility of placing these magnetic field sensors on the scalp allows not only to acquire signals from people in movement, but also to reduce the distance between the sensors and the brain, with a consequent gain in the signal-to-noise ratio. These advantages make the technique particularly attractive to characterise sources of brain activity in demanding populations, such as children and patients with epilepsy. However, the technology is currently in an early stage, presenting new design challenges around the optimal sensor arrangement and their complementarity with other techniques as electroencephalography (EEG). In this article, we present an optimal array design strategy focussed on minimising the brain source localisation error. The methodology is based on the Cramér-Rao bound, which provides lower error bounds on the estimation of source parameters regardless of the algorithm used. We utilise this framework to compare whole head OPM arrays with commercially available electro/magnetoencephalography (E/MEG) systems for localising brain signal generators. In addition, we study the complementarity between EEG and OPM-based MEG, and design optimal whole head systems based on OPMs only and a combination of OPMs and EEG electrodes for characterising deep and superficial sources alike. Finally, we show the usefulness of the approach to find the nearly optimal sensor positions minimising the estimation error bound in a given cortical region when a limited number of OPMs are available. This is of special interest for maximising the performance of small scale systems to ad hoc neurophysiological experiments, a common situation arising in most OPM labs.

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Section: Discussionsupporting

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Optimal design of on‐scalp electromagnetic sensor arrays for brain source localisation

Beltrachini

Ellenrieder

Eichardt

et al. 2021

Human Brain Mapping

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“…The reliable imaging of the brain for diagnostic purposes is a very significant procedure, as the early detection of possible anomalies is deemed decisive for a successful therapy. Several defects and malfunctions in the brain’s inner structure can be spotted through various non-invasive imaging techniques (Oldendorf, 1978; Wintermark et al , 2005; Shenton et al , 2012; Kraiger and Schnizer, 2013; Zhang et al , 2014; Szajerman et al , 2018; Eichardt et al , 2019) either considering the different properties of the brain tissues or through the brain activity. The former includes the popular magnetic resonance imaging (MRI) and the computed tomography (CT) scanning, while the latter is implemented in terms of functional MRI (fMRI), positron emission tomography (PET), electroencephalography (EEG) and magnetoencephalography (MEG).…”

Section: Introductionmentioning

confidence: 99%

Transcranial ultrasonic propagation and enhanced brain imaging exploiting the focusing effect of the skull

Amanatiadis

Apostolidis

Bekiari

et al. 2020

COMPEL

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Purpose The reliable transcranial imaging of brain inner structures for diagnostic purposes is deemed crucial owing to the decisive importance and contribution of the brain in human life. The purpose of this paper is to investigate the potential application of medical ultrasounds to transcranial imaging using advanced techniques, such as the total focussing method. Design/methodology/approach Initially, the fundamental details of the total focussing method are presented, while the skull properties, such as the increased acoustic velocity and scattering, are thoroughly examined. Although, these skull characteristics constitute the main drawback of typical transcranial ultrasonic propagation algorithms, they are exploited to focus the acoustic waves towards the brain. To this goal, a virtual source is designed, considering the wave refraction, to efficiently correct the reconstructed brain image. Finally, the verification of the novel method is conducted through numerical simulations of various realistic setups. Findings The theoretically designed virtual source resembles a focussed sensor; therefore, the directivity increment, owing to the propagation through the skull, is confirmed. Moreover, numerical simulations of real-world scenarios indicate that the typical artifacts of the conventional total focussing method are fully overcome because of the increased directivity of the proposed technique, while the reconstructed image is efficiently corrected when the proposed virtual source is used. Originality/value A new systematic methodology along with the design of a flexible virtual source is developed in this paper for the reliable and precise transcranial ultrasonic image reconstruction of the brain. Despite the slight degradation owing to the skull scattering, the combined application of the total focussing method and the featured virtual source can successfully detect arbitrary anomalies in the brain that cannot be spotted by conventional techniques.

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Magnetic Measurement of Electrically Evoked Muscle Responses With Optically Pumped Magnetometers

Elzenheimer

Laufs

Schulte‐Mattler

et al. 2020

IEEE Trans. Neural Syst. Rehabil. Eng.

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Sensitivity studies and optimization of arrangements of optically pumped magnetometers in simulated magnetoencephalography

Cited by 3 publications

References 13 publications

Optimal design of on‐scalp electromagnetic sensor arrays for brain source localisation

Optimal design of on‐scalp electromagnetic sensor arrays for brain source localisation

Transcranial ultrasonic propagation and enhanced brain imaging exploiting the focusing effect of the skull

Magnetic Measurement of Electrically Evoked Muscle Responses With Optically Pumped Magnetometers

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