eprintid: 10196353
rev_number: 19
eprint_status: archive
userid: 699
dir: disk0/10/19/63/53
datestamp: 2024-09-26 11:36:02
lastmod: 2024-09-26 11:36:02
status_changed: 2024-09-26 11:36:02
type: thesis
metadata_visibility: show
sword_depositor: 699
creators_name: Goodwin-Allcock, Tobias
title: Deep learning enabled enhancement
of clinical diffusion tensor imaging for
stroke
ispublished: unpub
divisions: UCL
divisions: B04
divisions: F42
note: Copyright © The Author 2024. Original content in this thesis is licensed under the terms of the Creative Commons Attribution-NonCommercial 4.0 International (CC BY-NC 4.0) Licence (https://creativecommons.org/licenses/by-nc/4.0/).  Any third-party copyright material present remains the property of its respective owner(s) and is licensed under its existing terms.  Access may initially be restricted at the author’s request.
abstract: This thesis develops machine learning methods for obtaining diffusion tensor (DT) parameters from the sparse data acquisitions clinical scanner demands compel. Clinical management may be aided by DT characterisation of brain damage. However, accurate DT estimation with conventional model fitting (MF) techniques requires more measurements than are clinically tolerable, a problem theoretically addressable with machine learning (ML)-estimated DT estimation. The application of existing ML methods is inhibited by their large data requirements and the marked pathological, biological, and instrumental variability characteristics of the clinical context. Clinically compatible ML has not yet obtained directional information. 

The first contribution of this thesis locates the cause of certain ML model failures to ignorance of the geometry of diffusion data. I show that accounting for geometry in the ML method increases robustness while decreasing training data requirements. The second contribution develops a new ML method, Patch-CNN, able to estimate directional information from sparse, clinical-grade imaging with high fidelity. Patch-CNN employs a convolutional window to estimate directional parameters from local neighbourhood information. Window size is kept small to minimize training data demands. I show that Patch-CNN can reveal major anatomical structures, such as the corticospinal tract, in clinical scans with only a single training volume. The third and fourth contributions tests the robustness of Patch-CNN to pathology unseen during training. The model is trained on data free of stroke lesions and tested on data containing them. In the third contribution, highly sampled imaging of people who all had a stroke over 5 days before scanning are used to analyse Patch-CNN's robustness. Model fidelity is shown to be invariant to the presence of lesions, permitting reliable estimation of both normal and abnormal microstructural anatomy even without training on pathological data.
Finally we apply Patch-CNN to clinically acquired stroke data where there is no high quality ground truth diffusion parameter values. Patch-CNN estimates diffusion tensor parameters with higher signal to noise than traditional model fitting.
date: 2024-08-28
date_type: published
oa_status: green
full_text_type: other
thesis_class: doctoral_open
thesis_award: Ph.D
language: eng
primo: open
primo_central: open_green
verified: verified_manual
elements_id: 2308148
lyricists_name: Goodwin-Allcock, Tobias
lyricists_id: TGOOD98
actors_name: Goodwin-Allcock, Tobias
actors_id: TGOOD98
actors_role: owner
full_text_status: public
institution: UCL (University College London)
department: Computer Science
thesis_type: Doctoral
citation:        Goodwin-Allcock, Tobias;      (2024)    Deep learning enabled enhancement of clinical diffusion tensor imaging for stroke.                   Doctoral thesis  (Ph.D), UCL (University College London).     Green open access   
 
document_url: https://discovery.ucl.ac.uk/id/eprint/10196353/1/Goodwin-Allcock_10196353_Thesis.pdf