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A reproducibility evaluation of the effects of MRI defacing on brain segmentation

PURPOSE: Recent advances in magnetic resonance (MR) scanner quality and the rapidly improving nature of facial recognition software have necessitated the introduction of MR defacing algorithms to protect patient privacy. As a result, there are a number of MR defacing algorithms available to the neur...

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Autores principales: Gao, Chenyu, Landman, Bennett A., Prince, Jerry L., Carass, Aaron
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Cold Spring Harbor Laboratory 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10246049/
https://www.ncbi.nlm.nih.gov/pubmed/37293070
http://dx.doi.org/10.1101/2023.05.15.23289995
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author Gao, Chenyu
Landman, Bennett A.
Prince, Jerry L.
Carass, Aaron
author_facet Gao, Chenyu
Landman, Bennett A.
Prince, Jerry L.
Carass, Aaron
author_sort Gao, Chenyu
collection PubMed
description PURPOSE: Recent advances in magnetic resonance (MR) scanner quality and the rapidly improving nature of facial recognition software have necessitated the introduction of MR defacing algorithms to protect patient privacy. As a result, there are a number of MR defacing algorithms available to the neuroimaging community, with several appearing in just the last five years. While some qualities of these defacing algorithms, such as patient identifiability, have been explored in previous works, the potential impact of defacing on neuroimage processing has yet to be explored. APPROACH: We qualitatively evaluate eight MR defacing algorithms on 179 subjects from the OASIS-3 cohort and the 21 subjects from the Kirby-21 dataset. We also evaluate the effects of defacing on two neuroimaging pipelines—SLANT and FreeSurfer—by comparing the segmentation consistency between the original and defaced images. RESULTS: Defacing can alter brain segmentation and even lead to catastrophic failures, which are more frequent with some algorithms such as Quickshear, MRI_Deface, and FSL_deface. Compared to FreeSurfer, SLANT is less affected by defacing. On outputs that pass the quality check, the effects of defacing are less pronounced than those of rescanning, as measured by the Dice similarity coefficient. CONCLUSIONS: The effects of defacing are noticeable and should not be disregarded. Extra attention, in particular, should be paid to the possibility of catastrophic failures. It is crucial to adopt a robust defacing algorithm and perform a thorough quality check before releasing defaced datasets. To improve the reliability of analysis in scenarios involving defaced MRIs, it’s encouraged to include multiple brain segmentation pipelines.
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spelling pubmed-102460492023-06-08 A reproducibility evaluation of the effects of MRI defacing on brain segmentation Gao, Chenyu Landman, Bennett A. Prince, Jerry L. Carass, Aaron medRxiv Article PURPOSE: Recent advances in magnetic resonance (MR) scanner quality and the rapidly improving nature of facial recognition software have necessitated the introduction of MR defacing algorithms to protect patient privacy. As a result, there are a number of MR defacing algorithms available to the neuroimaging community, with several appearing in just the last five years. While some qualities of these defacing algorithms, such as patient identifiability, have been explored in previous works, the potential impact of defacing on neuroimage processing has yet to be explored. APPROACH: We qualitatively evaluate eight MR defacing algorithms on 179 subjects from the OASIS-3 cohort and the 21 subjects from the Kirby-21 dataset. We also evaluate the effects of defacing on two neuroimaging pipelines—SLANT and FreeSurfer—by comparing the segmentation consistency between the original and defaced images. RESULTS: Defacing can alter brain segmentation and even lead to catastrophic failures, which are more frequent with some algorithms such as Quickshear, MRI_Deface, and FSL_deface. Compared to FreeSurfer, SLANT is less affected by defacing. On outputs that pass the quality check, the effects of defacing are less pronounced than those of rescanning, as measured by the Dice similarity coefficient. CONCLUSIONS: The effects of defacing are noticeable and should not be disregarded. Extra attention, in particular, should be paid to the possibility of catastrophic failures. It is crucial to adopt a robust defacing algorithm and perform a thorough quality check before releasing defaced datasets. To improve the reliability of analysis in scenarios involving defaced MRIs, it’s encouraged to include multiple brain segmentation pipelines. Cold Spring Harbor Laboratory 2023-05-21 /pmc/articles/PMC10246049/ /pubmed/37293070 http://dx.doi.org/10.1101/2023.05.15.23289995 Text en https://creativecommons.org/licenses/by-nc-nd/4.0/This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (https://creativecommons.org/licenses/by-nc-nd/4.0/) , which allows reusers to copy and distribute the material in any medium or format in unadapted form only, for noncommercial purposes only, and only so long as attribution is given to the creator.
spellingShingle Article
Gao, Chenyu
Landman, Bennett A.
Prince, Jerry L.
Carass, Aaron
A reproducibility evaluation of the effects of MRI defacing on brain segmentation
title A reproducibility evaluation of the effects of MRI defacing on brain segmentation
title_full A reproducibility evaluation of the effects of MRI defacing on brain segmentation
title_fullStr A reproducibility evaluation of the effects of MRI defacing on brain segmentation
title_full_unstemmed A reproducibility evaluation of the effects of MRI defacing on brain segmentation
title_short A reproducibility evaluation of the effects of MRI defacing on brain segmentation
title_sort reproducibility evaluation of the effects of mri defacing on brain segmentation
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10246049/
https://www.ncbi.nlm.nih.gov/pubmed/37293070
http://dx.doi.org/10.1101/2023.05.15.23289995
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