Your search keyword '"Neonatal imaging"' showing total 4 results

1. Scattered slice SHARD reconstruction for motion correction in multi-shell diffusion MRI.

Author

Christiaens D, Cordero-Grande L, Pietsch M, Hutter J, Price AN, Hughes EJ, Vecchiato K, Deprez M, Edwards AD, Hajnal JV, and Tournier JD

Subjects

Connectome, Humans, Infant, Newborn, Brain diagnostic imaging, Diffusion Magnetic Resonance Imaging methods, Image Processing, Computer-Assisted methods, Movement

Abstract

Diffusion MRI offers a unique probe into neural microstructure and connectivity in the developing brain. However, analysis of neonatal brain imaging data is complicated by inevitable subject motion, leading to a series of scattered slices that need to be aligned within and across diffusion-weighted contrasts. Here, we develop a reconstruction method for scattered slice multi-shell high angular resolution diffusion imaging (HARDI) data, jointly estimating an uncorrupted data representation and motion parameters at the slice or multiband excitation level. The reconstruction relies on data-driven representation of multi-shell HARDI data using a bespoke spherical harmonics and radial decomposition (SHARD), which avoids imposing model assumptions, thus facilitating to compare various microstructure imaging methods in the reconstructed output. Furthermore, the proposed framework integrates slice-level outlier rejection, distortion correction, and slice profile correction. We evaluate the method in the neonatal cohort of the developing Human Connectome Project (650 scans). Validation experiments demonstrate accurate slice-level motion correction across the age range and across the range of motion in the population. Results in the neonatal data show successful reconstruction even in severely motion-corrupted subjects. In addition, we illustrate how local tissue modelling can extract advanced microstructure features such as orientation distribution functions from the motion-corrected reconstructions., (Copyright © 2020 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

2. A data-driven approach to optimising the encoding for multi-shell diffusion MRI with application to neonatal imaging.

Author

Tournier JD, Christiaens D, Hutter J, Price AN, Cordero-Grande L, Hughes E, Bastiani M, Sotiropoulos SN, Smith SM, Rueckert D, Counsell SJ, Edwards AD, and Hajnal JV

Subjects

Algorithms, Anisotropy, Contrast Media chemistry, Humans, Infant, Newborn, Signal Processing, Computer-Assisted, Diffusion Magnetic Resonance Imaging

Abstract

Diffusion MRI has the potential to provide important information about the connectivity and microstructure of the human brain during normal and abnormal development, noninvasively and in vivo. Recent developments in MRI hardware and reconstruction methods now permit the acquisition of large amounts of data within relatively short scan times. This makes it possible to acquire more informative multi-shell data, with diffusion sensitisation applied along many directions over multiple b-value shells. Such schemes are characterised by the number of shells acquired, and the specific b-value and number of directions sampled for each shell. However, there is currently no clear consensus as to how to optimise these parameters. In this work, we propose a means of optimising multi-shell acquisition schemes by estimating the information content of the diffusion MRI signal, and optimising the acquisition parameters for sensitivity to the observed effects, in a manner agnostic to any particular diffusion analysis method that might subsequently be applied to the data. This method was used to design the acquisition scheme for the neonatal diffusion MRI sequence used in the developing Human Connectome Project (dHCP), which aims to acquire high quality data and make it freely available to the research community. The final protocol selected by the algorithm, and currently in use within the dHCP, consists of 20 b=0 images and diffusion-weighted images at b = 400, 1000 and 2600 s/mm 2 with 64, 88 and 128 directions per shell, respectively., (© 2020 The Authors. NMR in Biomedicine published by John Wiley & Sons Ltd.)

Published

2020

3. A data‐driven approach to optimising the encoding for multi‐shell diffusion MRI with application to neonatal imaging

Author

Jacques-Donald Tournier, Stamatios N. Sotiropoulos, Daniel Rueckert, Lucilio Cordero-Grande, Serena J. Counsell, Jana Hutter, Anthony N. Price, Stephen M. Smith, Elaine Hughes, Alexander D. Edwards, Joseph V. Hajnal, Matteo Bastiani, and Daan Christiaens

Subjects

Technology, FIBER ORIENTATIONS, Computer science, Contrast Media, computer.software_genre, Signal, 030218 nuclear medicine & medical imaging, diffusion MRI, 0302 clinical medicine, HARDI, ORIENTATION DISPERSION, Diffusion (business), BRAIN, Spectroscopy, Human Connectome Project, Radiology, Nuclear Medicine & Medical Imaging, Signal Processing, Computer-Assisted, WATER DIFFUSION, MAP-MRI, Molecular Medicine, Data mining, Life Sciences & Biomedicine, TISSUE MICROSTRUCTURE, Algorithms, neonatal imaging, Biophysics, Article, Data-driven, 03 medical and health sciences, Encoding (memory), Humans, Radiology, Nuclear Medicine and imaging, RECONSTRUCTION, Sensitivity (control systems), Science & Technology, Dynamic Host Configuration Protocol, business.industry, Infant, Newborn, Pattern recognition, SIGNAL, Diffusion Magnetic Resonance Imaging, Data quality, DENSITY, Anisotropy, multi-shell, BALL, Artificial intelligence, business, computer, 030217 neurology & neurosurgery, Diffusion MRI

Abstract

Diffusion MRI has the potential to provide important information about the connectivity and microstructure of the human brain during normal and abnormal development, non-invasively and in vivo. Recent developments in MRI hardware and reconstruction methods now permit the acquisition of large amounts of data within relatively short scan times. This makes it possible to acquire more informative multi-shell data, with diffusion-sensitisation applied along many directions over multiple b-value shells. Such schemes are characterised by the number of shells acquired, and the specific b-value and number of directions sampled for each shell. However, there is currently no clear consensus as to how to optimise these parameters. In this work, we propose a means of optimising multi-shell acquisition schemes by estimating the information content of the diffusion MRI signal, and optimising the acquisition parameters for sensitivity to the observed effects, in a manner agnostic to any particular diffusion analysis method that might subsequently be applied to the data. This method was used to design the acquisition scheme for the neonatal diffusion MRI sequence used in the developing Human Connectome Project, which aims to acquire high quality data and make it freely available to the research community. The final protocol selected by the algorithm, and currently in use within the dHCP, consists of b = 0, 400, 1000, 2600 s/mm2 with 20, 64, 88 & 128 DW directions per shell respectively.HighlightsA data driven method is presented to design multi-shell diffusion MRI acquisition schemes (b-values and no. directions).This method optimises the multi-shell scheme for maximum sensitivity to the information content in the signal.When applied in neonates, the data suggest that a b=0 + 3 shell strategy is appropriate

Published

2021

4. Scattered slice SHARD reconstruction for motion correction in multi-shell diffusion MRI

Author

A. David Edwards, Daan Christiaens, Jana Hutter, Joseph V. Hajnal, Lucilio Cordero-Grande, Jacques-Donald Tournier, Maximilian Pietsch, Maria Deprez, Anthony N. Price, Katy Vecchiato, and Emer Hughes

Subjects

RMSE, root-mean-square error, Computer science, Cognitive Neuroscience, Movement, FOS: Physical sciences, 050105 experimental psychology, Article, Diffusion MRI, lcsh:RC321-571, FWHM, full width half maximum, 03 medical and health sciences, ODF, orientation distribution function, 0302 clinical medicine, dMRI, diffusion magnetic resonance imaging, GMM, Gaussian mixture model, Connectome, Image Processing, Computer-Assisted, Humans, 0501 psychology and cognitive sciences, Computer vision, Angular resolution, Neonatal imaging, Slice-to-volume reconstruction, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, SH, spherical harmonics, Human Connectome Project, Orientation (computer vision), business.industry, 05 social sciences, Multi-shell, Infant, Newborn, Spherical harmonics, Brain, SNR, signal-to-noise ratio, Physics - Medical Physics, EPI, echo planar imaging, SHARD, spherical harmonics and radial decomposition, Shard, Diffusion Magnetic Resonance Imaging, Neurology, dHCP, developing Human Connectome Project, SSP, slice sensitivity profile, Motion correction, Medical Physics (physics.med-ph), Artificial intelligence, business, 030217 neurology & neurosurgery, SVD, singular value decomposition

Abstract

Diffusion MRI offers a unique probe into neural microstructure and connectivity in the developing brain. However, analysis of neonatal brain imaging data is complicated by inevitable subject motion, leading to a series of scattered slices that need to be aligned within and across diffusion-weighted contrasts. Here, we develop a reconstruction method for scattered slice multi-shell high angular resolution diffusion imaging (HARDI) data, jointly estimating an uncorrupted data representation and motion parameters at the slice or multiband excitation level. The reconstruction relies on data-driven representation of multi-shell HARDI data using a bespoke spherical harmonics and radial decomposition (SHARD), which avoids imposing model assumptions, thus facilitating to compare various microstructure imaging methods in the reconstructed output. Furthermore, the proposed framework integrates slice-level outlier rejection, distortion correction, and slice profile correction. We evaluate the method in the neonatal cohort of the developing Human Connectome Project (650 scans). Validation experiments demonstrate accurate slice-level motion correction across the age range and across the range of motion in the population. Results in the neonatal data show successful reconstruction even in severely motion-corrupted subjects. In addition, we illustrate how local tissue modelling can extract advanced microstructure features such as orientation distribution functions from the motion-corrected reconstructions., revision. 15 pages, 10 figures, 2 tables

Published

2021