Your search keyword '"Graham MS"' showing total 3 results

1. A supervised learning approach for diffusion MRI quality control with minimal training data.

Author

Graham MS, Drobnjak I, and Zhang H

Subjects

Brain Mapping standards, Connectome methods, Diffusion Magnetic Resonance Imaging methods, Diffusion Magnetic Resonance Imaging standards, Female, Humans, Image Processing, Computer-Assisted standards, Infant, Newborn, Male, Artifacts, Brain Mapping methods, Image Processing, Computer-Assisted methods, Quality Control, Supervised Machine Learning standards

Abstract

Quality control (QC) is a fundamental component of any study. Diffusion MRI has unique challenges that make manual QC particularly difficult, including a greater number of artefacts than other MR modalities and a greater volume of data. The gold standard is manual inspection of the data, but this process is time-consuming and subjective. Recently supervised learning approaches based on convolutional neural networks have been shown to be competitive with manual inspection. A drawback of these approaches is they still require a manually labelled dataset for training, which is itself time-consuming to produce and still introduces an element of subjectivity. In this work we demonstrate the need for manual labelling can be greatly reduced by training on simulated data, and using a small amount of labelled data for a final calibration step. We demonstrate its potential for the detection of severe movement artefacts, and compare performance to a classifier trained on manually-labelled real data., (Copyright © 2018 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2018

2. Susceptibility-induced distortion that varies due to motion: Correction in diffusion MR without acquiring additional data.

Author

Andersson JLR, Graham MS, Drobnjak I, Zhang H, and Campbell J

Subjects

Algorithms, Head Movements, Humans, Motion, Artifacts, Brain Mapping methods, Echo-Planar Imaging methods, Image Processing, Computer-Assisted methods

Abstract

Because of their low bandwidth in the phase-encode (PE) direction, the susceptibility-induced off-resonance field causes distortions in echo planar imaging (EPI) images. It is therefore crucial to correct for susceptibility-induced distortions when performing diffusion studies using EPI. The susceptibility-induced field is caused by the object (head) disrupting the field and it is typically assumed that it remains constant within a framework defined by the object, (i.e. it follows the object as it moves in the scanner). However, this is only approximately true. When a non-spherical object rotates around an axis other than that parallel with the magnetic flux (the z-axis) it changes the way it disrupts the field, leading to different distortions. Hence, if using a single field to correct for distortions there will be residual distortions in the volumes where the object orientation is substantially different to that when the field was measured. In this paper we present a post-processing method for estimating the field as it changes with motion during the course of an experiment. It only requires a single measured field and knowledge of the orientation of the subject when that field was acquired. The volume-to-volume changes of the field as a consequence of subject movement are estimated directly from the diffusion data without the need for any additional or special acquisitions. It uses a generative model that predicts how each volume would look predicated on field change and inverts that model to yield an estimate of the field changes. It has been validated on both simulations and experimental data. The results show that we are able to track the field with high accuracy and that we are able to correct the data for the adverse effects of the changing field., (Copyright © 2017 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2018

3. Towards a comprehensive framework for movement and distortion correction of diffusion MR images: Within volume movement.

Author

Andersson JLR, Graham MS, Drobnjak I, Zhang H, Filippini N, and Bastiani M

Subjects

Artifacts, Computer Simulation, Humans, Movement, Reproducibility of Results, Brain anatomy & histology, Brain Mapping methods, Diffusion Magnetic Resonance Imaging methods, Image Enhancement methods

Abstract

Most motion correction methods work by aligning a set of volumes together, or to a volume that represents a reference location. These are based on an implicit assumption that the subject remains motionless during the several seconds it takes to acquire all slices in a volume, and that any movement occurs in the brief moment between acquiring the last slice of one volume and the first slice of the next. This is clearly an approximation that can be more or less good depending on how long it takes to acquire one volume and in how rapidly the subject moves. In this paper we present a method that increases the temporal resolution of the motion correction by modelling movement as a piecewise continous function over time. This intra-volume movement correction is implemented within a previously presented framework that simultaneously estimates distortions, movement and movement-induced signal dropout. We validate the method on highly realistic simulated data containing all of these effects. It is demonstrated that we can estimate the true movement with high accuracy, and that scalar parameters derived from the data, such as fractional anisotropy, are estimated with greater fidelity when data has been corrected for intra-volume movement. Importantly, we also show that the difference in fidelity between data affected by different amounts of movement is much reduced when taking intra-volume movement into account. Additional validation was performed on data from a healthy volunteer scanned when lying still and when performing deliberate movements. We show an increased correspondence between the "still" and the "movement" data when the latter is corrected for intra-volume movement. Finally we demonstrate a big reduction in the telltale signs of intra-volume movement in data acquired on elderly subjects., (Copyright © 2017 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2017