6 results on '"Schneiderman, Justin F."'
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2. On-Scalp MEG
- Author
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Schneiderman, Justin F., Ruffieux, Silvia, Pfeiffer, Christoph, Riaz, Bushra, Supek, Selma, editor, and Aine, Cheryl J., editor
- Published
- 2019
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3. A 7-Channel High-${T}_\text{c}$ SQUID-Based On-Scalp MEG System.
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Pfeiffer, Christoph, Ruffieux, Silvia, Jonsson, Lars, Chukharkin, Maxim L., Kalaboukhov, Alexei, Xie, Minshu, Winkler, Dag, and Schneiderman, Justin F.
- Subjects
VISUAL cortex ,SUPERCONDUCTING quantum interference devices ,AUDITORY evoked response ,AUDITORY perception ,WHITE noise ,CRITICAL temperature - Abstract
Objective: To present the technical design and demonstrate the feasibility of a multi-channel on-scalp magnetoencephalography (MEG) system based on high critical temperature (high- ${T}_\text{c}$) superconducting quantum interference devices (SQUIDs). Methods: We built a liquid nitrogen-cooled cryostat that houses seven YBCO SQUID magnetometers arranged in a dense, head-aligned array with minimal distance to the room-temperature environment for all sensors. We characterize the performance of this 7-channel system in terms of on-scalp MEG utilization and present recordings of spontaneous and evoked brain activity. Results: The center-to-center spacing between adjacent SQUIDs is 12.0 and 13.4 mm and all SQUIDs are in the range of 1-3 mm of the head surface. The cryostat reaches a base temperature of $\sim$ 70 K and stays cold for $>$ 16 h with a single 0.9 L filling. The white noise levels of the magnetometers is 50–130 fT/Hz1/2 at 10 Hz and they show low sensor-to-sensor feedback flux crosstalk ($< $ 0.6%). We demonstrate evoked fields from auditory stimuli and single-shot sensitivity to alpha modulation from the visual cortex. Conclusion: All seven channels in the system sensitively sample neuromagnetic fields with mm-scale scalp standoff distances. The hold time of the cryostat furthermore is sufficient for a day of recordings. As such, our multi-channel high- ${T}_\text{c}$ SQUID-based system meets the demands of on-scalp MEG. Significance: The system presented here marks the first high- ${T}_\text{c}$ SQUID-based on-scalp MEG system with more than two channels. It enables us to further explore the benefits of on-scalp MEG in future recordings. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
4. Benchmarking for On-Scalp MEG Sensors.
- Author
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Xie, Minshu, Schneiderman, Justin F., Chukharkin, Maxim L., Kalabukhov, Alexei, Riaz, Bushra, Lundqvist, Daniel, Whitmarsh, Stephen, Hamalainen, Matti, Jousmaki, Veikko, Oostenveld, Robert, and Winkler, Dag
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MAGNETOENCEPHALOGRAPHY , *MAGNETIC sensors , *SOMATOSENSORY evoked potentials , *SUPERCONDUCTING quantum interference devices , *MAGNETOMETERS , *SUPERCONDUCTORS - Abstract
Objective: We present a benchmarking protocol for quantitatively comparing emerging on-scalp magnetoencephalography (MEG) sensor technologies to their counterparts in state-of-the-art MEG systems. Methods: As a means of validation, we compare a high-critical-temperature superconducting quantum interference device (high $T_{{c}}$ SQUID) with the low-$T_{{c}}$ SQUIDs of an Elekta Neuromag TRIUX system in MEG recordings of auditory and somatosensory evoked fields (SEFs) on one human subject. Results: We measure the expected signal gain for the auditory-evoked fields (deeper sources) and notice some unfamiliar features in the on-scalp sensor-based recordings of SEFs (shallower sources). Conclusion: The experimental results serve as a proof of principle for the benchmarking protocol. This approach is straightforward, general to various on-scalp MEG sensors, and convenient to use on human subjects. The unexpected features in the SEFs suggest on-scalp MEG sensors may reveal information about neuromagnetic sources that is otherwise difficult to extract from state-of-the-art MEG recordings. Significance: As the first systematically established on-scalp MEG benchmarking protocol, magnetic sensor developers can employ this method to prove the utility of their technology in MEG recordings. Further exploration of the SEFs with on-scalp MEG sensors may reveal unique information about their sources. [ABSTRACT FROM AUTHOR]
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- 2017
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5. Spatial suppression in visual motion perception is driven by inhibition: Evidence from MEG gamma oscillations.
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Orekhova, Elena V., Rostovtseva, Ekaterina N., Manyukhina, Viktoriya O., Prokofiev, Andrey O., Obukhova, Tatiana S., Nikolaeva, Anastasia Yu., Schneiderman, Justin F., and Stroganova, Tatiana A.
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VISUAL perception , *OSCILLATIONS , *VISUAL cortex , *NEURAL inhibition , *VISUAL fields - Abstract
Spatial suppression (SS) is a visual perceptual phenomenon that is manifest in a reduction of directional sensitivity for drifting high-contrast gratings whose size exceeds the center of the visual field. Gratings moving at faster velocities induce stronger SS. The neural processes that give rise to such size- and velocity-dependent reductions in directional sensitivity are currently unknown, and the role of surround inhibition is unclear. In magnetoencephalogram (MEG), large high-contrast drifting gratings induce a strong gamma response (GR), which also attenuates with an increase in the gratings' velocity. It has been suggested that the slope of this GR attenuation is mediated by inhibitory interactions in the primary visual cortex. Herein, we investigate whether SS is related to this inhibitory-based MEG measure. We evaluated SS and GR in two independent samples of participants: school-age boys and adult women. The slope of GR attenuation predicted inter-individual differences in SS in both samples. Test-retest reliability of the neuro-behavioral correlation was assessed in the adults, and was high between two sessions separated by several days or weeks. Neither frequencies nor absolute amplitudes of the GRs correlated with SS, which highlights the functional relevance of velocity-related changes in GR magnitude caused by augmentation of incoming input. Our findings provide evidence that links the psychophysical phenomenon of SS to inhibitory-based neural responses in the human primary visual cortex. This supports the role of inhibitory interactions as an important underlying mechanism for spatial suppression. • The role of surround inhibition in perceptual spatial suppression (SS) is debated. • Gamma response (GR) to large moving gratings reflects surround inhibition. • Stronger GR attenuation with increasing velocity is associated with stronger SS. • The neuro-behavioral correlation is replicated in school-age boys and adult women. • The surround inhibition in the V1 is an important mechanism underlying SS. [ABSTRACT FROM AUTHOR]
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- 2020
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6. On-scalp MEG sensor localization using magnetic dipole-like coils: A method for highly accurate co-registration.
- Author
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Pfeiffer, Christoph, Ruffieux, Silvia, Andersen, Lau M., Kalabukhov, Alexei, Winkler, Dag, Oostenveld, Robert, Lundqvist, Daniel, and Schneiderman, Justin F.
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SENSOR placement , *ELECTROMAGNETS , *SUPERCONDUCTING quantum interference devices , *SUPERCONDUCTING transition temperature , *SENSOR arrays - Abstract
Source modelling in magnetoencephalography (MEG) requires precise co-registration of the sensor array and the anatomical structure of the measured individual's head. In conventional MEG, the positions and orientations of the sensors relative to each other are fixed and known beforehand, requiring only localization of the head relative to the sensor array. Since the sensors in on-scalp MEG are positioned on the scalp, locations of the individual sensors depend on the subject's head shape and size. The positions and orientations of on-scalp sensors must therefore be measured at every recording. This can be achieved by inverting conventional head localization, localizing the sensors relative to the head - rather than the other way around. In this study we present a practical method for localizing sensors using magnetic dipole-like coils attached to the subject's head. We implement and evaluate the method in a set of on-scalp MEG recordings using a 7-channel on-scalp MEG system based on high critical temperature superconducting quantum interference devices (high- T c SQUIDs). The method allows individually localizing the sensor positions, orientations, and responsivities with high accuracy using only a short averaging time (≤ 2 mm, < 3° and < 3%, respectively, with 1-s averaging), enabling continuous sensor localization. Calibrating and jointly localizing the sensor array can further improve the accuracy of position and orientation (< 1 mm and < 1°, respectively, with 1-s coil recordings). We demonstrate source localization of on-scalp recorded somatosensory evoked activity based on co-registration with our method. Equivalent current dipole fits of the evoked responses corresponded well (within 4.2 mm) with those based on a commercial, whole-head MEG system. • We present and test a method that enables accurate co-registration in on-scalp MEG. • The method uses an array of dipole-like coils to localize individual or small groups of magnetometers. • We localized sensors individually with position errors below 2 mm and orientation errors below 3° with 1-s coil recordings. • We demonstrate source localization of N20m activity in a human subject using the method for co-registration. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
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