Impact of SQUIDs on functional imaging in neuroscience

Penna, Stefania Della; Pizzella, Vittorio; Romani, Gian Luca

doi:10.1088/0953-2048/27/4/044004

Cited by 5 publications

(1 citation statement)

References 118 publications

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“…Each sampling point consists of one (magnetometer or axial gradiometer) or multiple (magnetometer and two orthogonal planar gradiometers) detection channels. A review of the existing MEG systems can be found in Della Penna et al (2014). To reduce the contribution of the environmental magnetic field (noise) to the measured field, MEG systems are usually operated inside a magnetically shielded room.…”

Section: Box 2 -Instrumentation For Megmentioning

confidence: 99%

Magnetoencephalography in the study of brain dynamics

Pizzella¹

2014

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SummaryTo progress toward understanding of the mechanisms underlying the functional organization of the human brain, either a bottom-up or a top-down approach may be adopted. The former starts from the study of the detailed functioning of a small number of neuronal assemblies, while the latter tries to decode brain functioning by considering the brain as a whole. This review discusses the top-down approach and the use of magnetoencephalography (MEG) to describe global brain properties. The main idea behind this approach is that the concurrence of several areas is required for the brain to instantiate a specific behavior/functioning. A central issue is therefore the study of brain functional connectivity and the concept of brain networks as ensembles of distant brain areas that preferentially exchange information. Importantly, the human brain is a dynamic device, and MEG is ideally suited to investigate phenomena on behaviorally relevant timescales, also offering the possibility of capturing behaviorally-related brain connectivity dynamics.

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Section: Box 2 -Instrumentation For Megmentioning

confidence: 99%

Magnetoencephalography in the study of brain dynamics

Pizzella¹

2014

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Magnetic Sensors

Edelstein

2016

Wiley Encyclopedia of Electrical and Electronics Engineering

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The different types of vector and scalar or total field magnetic sensors and the applications of these sensors are reviewed. Some of the applications have been employed for many years, such as the compasses for navigation, while others such as the detection of magnetic nanoparticles as part of drug delivery systems are much newer. Among the new phenomena are preferential tunneling of electrons with one direction of spin to increase the magnetoresistance or to change the magnetization using MgO tunnel barrier and Bose condensates for high‐resolution magnetometry. The several points that will be emphasized are the following: (i) magnetic sensors generally differ greatly in sensitivity, cost, power, and size; (ii) many different phenomena can be employed to measure magnetic fields; (iii) there are a large number and variety of applications; and (iv) the discovery of new phenomena has opened up new ways to measure magnetic fields and applications.

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Fast Room Temperature Very Low Field-Magnetic Resonance Imaging System Compatible with MagnetoEncephaloGraphy Environment

et al. 2015

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In recent years, ultra-low field (ULF)-MRI is being given more and more attention, due to the possibility of integrating ULF-MRI and Magnetoencephalography (MEG) in the same device. Despite the signal-to-noise ratio (SNR) reduction, there are several advantages to operating at ULF, including increased tissue contrast, reduced cost and weight of the scanners, the potential to image patients that are not compatible with clinical scanners, and the opportunity to integrate different imaging modalities. The majority of ULF-MRI systems are based, until now, on magnetic field pulsed techniques for increasing SNR, using SQUID based detectors with Larmor frequencies in the kHz range. Although promising results were recently obtained with such systems, it is an open question whether similar SNR and reduced acquisition time can be achieved with simpler devices. In this work a room-temperature, MEG-compatible very-low field (VLF)-MRI device working in the range of several hundred kHz without sample pre-polarization is presented. This preserves many advantages of ULF-MRI, but for equivalent imaging conditions and SNR we achieve reduced imaging time based on preliminary results using phantoms and ex-vivo rabbits heads.

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Impact of SQUIDs on functional imaging in neuroscience

Cited by 5 publications

References 118 publications

Magnetoencephalography in the study of brain dynamics

Magnetoencephalography in the study of brain dynamics

Magnetic Sensors

Fast Room Temperature Very Low Field-Magnetic Resonance Imaging System Compatible with MagnetoEncephaloGraphy Environment

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