Correction: Measurement and Correction of Microscopic Head Motion during Magnetic Resonance Imaging of the Brain

Maclaren, Julian; Armstrong, B.; Barrows, Robert T.; Danishad, K. A.; Ernst, Thomas; Foster, Colin L.; Gümüş, Kazım; Herbst, Michael; Kusik, Todd P.; Li, Qiaotian; Lovell-Smith, Cris; Prieto, Thomas; Schulze, Peter; Speck, Oliver; Stucht, Daniel; Zaitsev, Maxim

doi:10.1371/annotation/a29733ae-6317-42ee-92c0-a49542e1b7c8

Cited by 86 publications

(155 citation statements)

References 15 publications

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“…A promising motion correction technique providing the necessary precision in the range of a 1/10th voxel size (i.e., approximately 50 μm) and speed (approximate sampling rate 100 Hz) is prospective motion correction based on optical tracking (see Fig. 2; Callaghan et al, 2015;Maclaren et al, 2012;Schulz et al, 2012). However, sophisticated hardware, like MR compatible video cameras, are necessary.…”

Section: Mri Acquisition Methods and Hardwarementioning

confidence: 99%

In-vivo magnetic resonance imaging (MRI) of laminae in the human cortex

et al. 2019

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The human neocortex is organized radially into six layers which differ in their myelination and the density and arrangement of neuronal cells. This cortical cyto-and myeloarchitecture plays a central role in the anatomical and functional neuroanatomy but is primarily accessible through invasive histology only. To overcome this limitation, several non-invasive MRI approaches have been, and are being, developed to resolve the anatomical cortical layers. As a result, recent studies on large populations and structure-function relationships at the laminar level became possible. Early proof-of-concept studies targeted conspicuous laminar structures such as the stria of Gennari in the primary visual cortex. Recent work characterized the laminar structure outside the visual cortex, investigated the relationship between laminar structure and function, and demonstrated layer-specific maturation effects. This paper reviews the methods and in-vivo MRI studies on the anatomical layers in the human cortex based on conventional and quantitative MRI (excluding diffusion imaging). A focus is on the related challenges, promises and potential future developments. The rapid development of MRI scanners, motion correction techniques, analysis methods and biophysical modeling promise to overcome the challenges of spatial resolution, precision and specificity of systematic imaging of cortical laminae. Need for non-invasive mapping of cortical laminationThe neocortex of the human brain consists of six layers which differ in their pattern of myelination (Nieuwenhuys, 2013;Vogt and Vogt, 1919) and the density and arrangement of neuronal cells (Brodmann, 1909;Zilles and Amunts, 2010). Those differences gave rise to the broad research field of myelo-and cyto-architecture, which is based on invasive histology. To facilitate studies of the human brain in large populations and longitudinally, non-invasive methods are much needed for visualizing intracortical anatomy in-vivo, since histological methods can only be applied ex-vivo. A promising approach is magnetic resonance imaging (MRI) as it is non-invasive and highly sensitive to the presence of myelin (and iron) in the cortex (Stüber et al., 2014). It is expected to reflect the myeloarchitecture rather than the cyto-architecture, although there is a strong correspondence between the two . Scope of the reviewThis paper reviews the recent in-vivo MRI studies on the anatomical layers in the human neocortex. An additional focus is on the related challenges, promises and potential future developments. Studies using diffusion weighted MRI are excluded from this review, since they are covered by Assaf et al. (2017) in the same special issue on "Prospects for cortical laminar MRI: functional and anatomical imaging of cerebral cortical layers". MRI studies of cortical layers Studies of the stria of GennariAs the cortex is only 2-4 mm thick and convoluted (Fischl and Dale, 2000), mapping cortical layers requires sub-millimeter isotropic resolution. Another challenge is that the differences in myelo-ar...

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Section: Mri Acquisition Methods and Hardwarementioning

confidence: 99%

In-vivo magnetic resonance imaging (MRI) of laminae in the human cortex

et al. 2019

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“…PMC was performed with a tracking system consisting of a single camera mounted inside the scanner bore and a tracking marker with a multilayer structure, which generates moiré patterns for accurate orientation measurement [30]. Communication with the tracking system was implemented directly on the real-time control unit of the scanner as previously described by Zaitsev et al [6].…”

Section: Methodsmentioning

confidence: 99%

Correction of B 0-induced geometric distortion variations in prospective motion correction for 7T MRI

Yarach

Luengviriya

Stucht

et al. 2016

Magn Reson Mater Phy

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Objective Prospective motion correction can effectively fix the imaging volume of interest. For large motion, this can lead to relative motion of coil sensitivities, distortions associated with imaging gradients and B0 field variations. This work accounts for the B0 field change due to subject movement, and proposes a method for correcting tissue magnetic susceptibility-related distortion in prospective motion correction. Materials and methods The B0 field shifts at the different head orientations were characterized. A volunteer performed large motion with prospective motion correction enabled. The acquired data were divided into multiple groups according to the object positions. The correction of B0-related distortion was applied to each group of data individually via augmented sensitivity encoding with additionally integrated gradient nonlinearity correction. Results The relative motion of the gradients, B0 field and coil sensitivities in prospective motion correction results in residual spatial distortion, blurring, and coil artifacts. These errors can be mitigated by the proposed method. Moreover, iterative conjugate gradient optimization with regularization provided superior results with smaller RMSE in comparison to standard conjugate gradient. Conclusion The combined correction of B0-related distortion and gradient nonlinearity leads to a reduction of residual motion artifacts in prospective motion correction data.

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“…The main artifact contributions were associated with the MRI gradients and the cardiac cycle, but while these contributions are approximately periodic, and thus more suited to temporal segmentation for averaging and subtraction, spontaneous motion does not follow regular patterns, and can thus highly benefit from an external monitoring system. Several approaches for head motion detection have been proposed, including the use of highly sensitive optical systems (Maclaren et al, 2012), piezoelectric sensors (Bonmassar et al, 2002), and conductive wire loops (Masterton et al, 2007). We opted for loop-based sensors since they share similar mechanisms of artifact generation with EEG loops, and can be directly incorporated in linear regression models for EEG signal correction (as shown in the Motion artifact generation section).…”

Section: Motion Artifact Detectionmentioning

confidence: 99%

Towards high-quality simultaneous EEG-fMRI at 7 T: Detection and reduction of EEG artifacts due to head motion

et al. 2015

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a b s t r a c t a r t i c l e i n f oThe enhanced functional sensitivity offered by ultra-high field imaging may significantly benefit simultaneous EEG-fMRI studies, but the concurrent increases in artifact contamination can strongly compromise EEG data quality. In the present study, we focus on EEG artifacts created by head motion in the static B 0 field. A novel approach for motion artifact detection is proposed, based on a simple modification of a commercial EEG cap, in which four electrodes are non-permanently adapted to record only magnetic induction effects. Simultaneous EEG-fMRI data were acquired with this setup, at 7 T, from healthy volunteers undergoing a reversingcheckerboard visual stimulation paradigm. Data analysis assisted by the motion sensors revealed that, after gradient artifact correction, EEG signal variance was largely dominated by pulse artifacts (81-93%), but contributions from spontaneous motion (4-13%) were still comparable to or even larger than those of actual neuronal activity (3-9%). Multiple approaches were tested to determine the most effective procedure for denoising EEG data incorporating motion sensor information. Optimal results were obtained by applying an initial pulse artifact correction step (AAS-based), followed by motion artifact correction (based on the motion sensors) and ICA denoising. On average, motion artifact correction (after AAS) yielded a 61% reduction in signal power and a 62% increase in VEP trial-by-trial consistency. Combined with ICA, these improvements rose to a 74% power reduction and an 86% increase in trial consistency. Overall, the improvements achieved were well appreciable at single-subject and single-trial levels, and set an encouraging quality mark for simultaneous EEG-fMRI at ultra-high field.

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Correction: Measurement and Correction of Microscopic Head Motion during Magnetic Resonance Imaging of the Brain

Cited by 86 publications

References 15 publications

In-vivo magnetic resonance imaging (MRI) of laminae in the human cortex

In-vivo magnetic resonance imaging (MRI) of laminae in the human cortex

Correction of B 0-induced geometric distortion variations in prospective motion correction for 7T MRI

Towards high-quality simultaneous EEG-fMRI at 7 T: Detection and reduction of EEG artifacts due to head motion

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