RT Journal Article
SR Electronic
T1 Empowering Data Sharing in Neuroscience: A Deep Learning Deidentification Method for Pediatric Brain MRIs
JF American Journal of Neuroradiology
JO Am. J. Neuroradiol.
FD American Society of Neuroradiology
SP 964
OP 972
DO 10.3174/ajnr.A8581
VO 46
IS 5
A1 Familiar, Ariana M.
A1 Khalili, Neda
A1 Khalili, Nastaran
A1 Schuman, Cassidy
A1 Grove, Evan
A1 Viswanathan, Karthik
A1 Seidlitz, Jakob
A1 Alexander-Bloch, Aaron
A1 Zapaishchykova, Anna
A1 Kann, Benjamin H.
A1 Vossough, Arastoo
A1 Storm, Phillip B.
A1 Resnick, Adam C.
A1 Kazerooni, Anahita Fathi
A1 Nabavizadeh, Ali
YR 2025
UL http://www.ajnr.org/content/46/5/964.abstract
AB BACKGROUND AND PURPOSE: Privacy concerns, such as identifiable facial features within brain scans, have hindered the availability of pediatric neuroimaging data sets for research. Consequently, pediatric neuroscience research lags adult counterparts, particularly in rare disease and under-represented populations. The removal of face regions (image defacing) can mitigate this; however, existing defacing tools often fail with pediatric cases and diverse image types, leaving a critical gap in data accessibility. Given recent National Institutes of Health data sharing mandates, novel solutions are a critical need.MATERIALS AND METHODS: To develop an artificial intelligence (AI)-powered tool for automatic defacing of pediatric brain MRIs, deep learning methodologies (nnU-Net) were used by using a large, diverse multi-institutional data set of clinical radiology images. This included multiparametric MRIs (T1-weighted [T1W], T1W-contrast-enhanced, T2-weighted [T2W], T2W-FLAIR) with 976 total images from 208 patients with brain tumor (Children’s Brain Tumor Network, CBTN) and 36 clinical control patients (Scans with Limited Imaging Pathology, SLIP) ranging in age from 7 days to 21 years old.RESULTS: Face and ear removal accuracy for withheld testing data were the primary measure of model performance. Potential influences of defacing on downstream research usage were evaluated with standard image processing and AI-based pipelines. Group-level statistical trends were compared between original (nondefaced) and defaced images. Across image types, the model had high accuracy for removing face regions (mean accuracy, 98%; n=98 subjects/392 images), with lower performance for removal of ears (73%). Analysis of global and regional brain measures (SLIP cohort) showed minimal differences between original and defaced outputs (mean rS = 0.93, all P < .0001). AI-generated whole brain and tumor volumes (CBTN cohort) and temporalis muscle metrics (volume, cross-sectional area, centile scores; SLIP cohort) were not significantly affected by image defacing (all rS > 0.9, P < .0001).CONCLUSIONS: The defacing model demonstrates efficacy in removing facial regions across multiple MRI types and exhibits minimal impact on downstream research usage. A software package with the trained model is freely provided for wider use and further development (pediatric-auto-defacer; https://github.com/d3b-center/pediatric-auto-defacer-public). By offering a solution tailored to pediatric cases and multiple MRI sequences, this defacing tool will expedite research efforts and promote broader adoption of data sharing practices within the neuroscience community.AIartificial intelligenceCBTNChildren’s Brain Tumor NetworkCEcontrast-enhancedCHOPChildren’s Hospital of PhiladelphiaCSAcross-sectional areaLHleft hemisphereNIHNational Institutes of HealthRHright hemisphereSEMstandard error of the meanSLIPScans with Limited Imaging PathologyT1WT1-weightedT2WT2-weightedTMTtemporalis muscle thickness