Validating Automated Segmentation Tools in the Assessment of Caudate Atrophy in Huntington's Disease

Overview

Journal Front Neurol

Specialty Neurology

Date 2021 May 3

PMID 33935934

Citations 2

Authors

Nina M Mansoor

Tishok Vanniyasingam

Ian Malone

Nicola Z Hobbs

Elin Rees

Alexandra Durr

Raymund A C Roos

Bernhard Landwehrmeyer

Sarah J Tabrizi

Eileanoir B Johnson

Rachael I Scahill

Affiliations

Soon will be listed here.

Abstract

Neuroimaging shows considerable promise in generating sensitive and objective outcome measures for therapeutic trials across a range of neurodegenerative conditions. For volumetric measures the current gold standard is manual delineation, which is unfeasible for samples sizes required for large clinical trials. Using a cohort of early Huntington's disease (HD) patients ( = 46) and controls ( = 35), we compared the performance of four automated segmentation tools (FIRST, FreeSurfer, STEPS, MALP-EM) with manual delineation for generating cross-sectional caudate volume, a region known to be vulnerable in HD. We then examined the effect of each of these baseline regions on the ability to detect change over 15 months using the established longitudinal Caudate Boundary Shift Integral (cBSI) method, an automated longitudinal pipeline requiring a baseline caudate region as an input. All tools, except Freesurfer, generated significantly smaller caudate volumes than the manually derived regions. Jaccard indices showed poorer levels of overlap between each automated segmentation and manual delineation in the HD patients compared with controls. Nevertheless, each method was able to demonstrate significant group differences in volume ( < 0.001). STEPS performed best qualitatively as well as quantitively in the baseline analysis. Caudate atrophy measures generated by the cBSI using automated baseline regions were largely consistent with those derived from a manually segmented baseline, with STEPS providing the most robust cBSI values across both control and HD groups. Atrophy measures from the cBSI were relatively robust to differences in baseline segmentation technique, suggesting that fully automated pipelines could be used to generate outcome measures for clinical trials.

Citing Articles

Neuroimaging to Facilitate Clinical Trials in Huntington's Disease: Current Opinion from the EHDN Imaging Working Group.

Hobbs N, Papoutsi M, Delva A, Kinnunen K, Nakajima M, Van Laere K J Huntingtons Dis. 2024; 13(2):163-199.

PMID: 38788082 PMC: 11307036. DOI: 10.3233/JHD-240016.

Convolutional Neural Networks Enable Robust Automatic Segmentation of the Rat Hippocampus in MRI After Traumatic Brain Injury.

De Feo R, Hamalainen E, Manninen E, Immonen R, Valverde J, Ndode-Ekane X Front Neurol. 2022; 13:820267.

PMID: 35250823 PMC: 8891699. DOI: 10.3389/fneur.2022.820267.

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