BabyMEG: A whole-head pediatric magnetoencephalography system for human brain development research

Okada, Yoshio; Hämäläinen, Matti S.; Pratt, Kevin; Mascarenas, Anthony; Miller, Paul; Han, Menglai; Robles, J I; Cavallini, Anders; Power, Bill; Sieng, Kosal; Sun, Lianna; Lew, Seok; Doshi, Chiran; Ahtam, Banu; Dinh, Christoph; Esch, Lorenz; Grant, Ellen; Nummenmaa, Aapo; Paulson, D. N.

doi:10.1063/1.4962020

Cited by 77 publications

(58 citation statements)

References 30 publications

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“…SQUID sensors operate at ~ 4 K and liquid helium is used to achieve cryogenic temperature. Regular costly maintenance is required to fill the helium reservoir and calibrate the SQUID-based MEG system, although recent advancements in helium recycling [18] is reducing maintenance costs. The main limitation of SQUID-based MEG system, which also stems from the use of cryogens, is fixed sensor position.…”

Section: Introductionmentioning

confidence: 99%

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Non-Invasive Functional-Brain-Imaging with an OPM-based Magnetoencephalography System

et al. 2020

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A non-invasive functional-brain-imaging system based on optically-pumped-magnetometers (OPM) is presented. The OPM-based magnetoencephalography (MEG) system features 20 OPM channels conforming to the subject's scalp. Due to proximity (12 mm) of the OPM channels to the brain, it is anticipated that this MEG system offers an enhanced spatial resolution as it can capture finer spatial features compared to traditional MEG systems employing superconducting quantum interference device (SQUID). We have conducted two MEG experiments on three subjects: somatosensory evoked magnetic field (SEF) and auditory evoked magnetic field (AEF) using our OPM-based MEG system and a commercial SQUID-based MEG system. We have cross validated the robustness of our system by calculating the distance between the location of the equivalent current dipole (ECD) yielded by our OPM-based MEG system and the ECD location calculated by the commercial SQUID-based MEG system. We achieved sub-centimeter accuracy for both SEF and AEF responses in all three subjects.

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Section: Introductionmentioning

confidence: 99%

“…In commercial SQUID based MEG systems, the rigid helmet is designed to fit the 95th percentile head size; this fixed helmet size degrades the signal quality for smaller heads, e.g. children [18].…”

Section: Introductionmentioning

confidence: 99%

Non-Invasive Functional-Brain-Imaging with an OPM-based Magnetoencephalography System

et al. 2020

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“…Specific MEG systems tailored for infant brain has also been recently established (e.g. Roberts et al, 2014; Edgar et al, 2015; Okada et al, 2016). …”

Section: Introductionmentioning

confidence: 99%

Short-range connections in the developmental connectome during typical and atypical brain maturation

Ouyang

Kang

Detre

et al. 2017

Neuroscience & Biobehavioral Reviews

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The human brain is remarkably complex with connectivity constituting its basic organizing principle. Although long-range connectivity has been focused on in most research, short-range connectivity is characterized by unique and spatiotemporally heterogeneous dynamics from infancy to adulthood. Alterations in the maturational dynamics of short-range connectivity has been associated with neuropsychiatric disorders, such as autism and schizophrenia. Recent advances in neuroimaging techniques, especially diffusion magnetic resonance imaging (dMRI), resting-state functional MRI (rs-fMRI), electroencephalography (EEG) and magnetoencephalography (MEG), have made quantification of short-range connectivity possible in pediatric populations. This review summarizes findings on the development of short-range functional and structural connections at the macroscale. These findings suggest an inverted U-shaped pattern of maturation from primary to higher-order brain regions, and possible “hyper-” and “hypo-” short-range connections in autism and schizophrenia, respectively. The precisely balanced short- and long-range connections contribute to the integration and segregation of the connectome during development. The mechanistic relationship among short-range connectivity maturation, the developmental connectome and emerging brain functions needs further investigation, including the refinement of methodological approaches.

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“…Magnetoencephalographic (MEG) recordings provide a well-established technique for studying the time course of brain activity during motor tasks, as well as the role of oscillatory networks in motor control (for review see, Cheyne 2013). With the introduction of customized MEG systems for smaller children, MEG can fill the current gap between our knowledge of early neural development and that of motor and cognitive abilities (Johnson et al 2010, Cheyne et al 2014, Roberts et al 2014, He et al 2015, Okada et al 2016, He and Johnson 2018). There are however, relatively few MEG studies of motor development, partly due to the challenges of recording motor responses in children and most studies to date have focused on older children and adolescents (Gaetz et al 2010, Wilson et al 2010, Huo et al 2011, Trevarrow et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Developmental Changes in Movement Related Brain Activity in Early Childhood

Johnson¹,

Jobst

Al-Loos³

et al. 2019

Preprint

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In a previous MEG study of movement-related brain activity in preschool age children, we reported that pre-movement fields and sensorimotor cortex oscillations differed from those typically observed in adults, suggesting that maturation of cortical motor networks is still incomplete by late preschool age (Cheyne et al., 2014). Here we describe the same measurements in an older group of school-aged children (6 to 8 years old) and an adult control group, in addition to repeated recordings in seven children from the original study approximately two years later. Differences were observed both longitudinally within children and between age groups. Pre-movement (readiness) fields were still not present in the oldest children, however both frequency and magnitude of movement-related mu (8-12Hz) and beta (15-30Hz) oscillations demonstrated linear increases with age. In contrast, movement-evoked gamma synchronization demonstrated a step-like transition from low to high (70-90 Hz) narrow-band oscillations, and this occurred at different ages in different children.These data provide novel evidence of linear and non-linear changes in motor cortex oscillations and delayed development of the readiness field throughout early childhood. Individual children showed large differences in maturation of movement-related brain activity, possibly reflecting differing rates of motor development.

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BabyMEG: A whole-head pediatric magnetoencephalography system for human brain development research

Cited by 77 publications

References 30 publications

Non-Invasive Functional-Brain-Imaging with an OPM-based Magnetoencephalography System

Non-Invasive Functional-Brain-Imaging with an OPM-based Magnetoencephalography System

Short-range connections in the developmental connectome during typical and atypical brain maturation

Developmental Changes in Movement Related Brain Activity in Early Childhood

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