TY - JOUR
T1 - Learning Strategies for Contrast-agnostic Segmentation via SynthSeg for Infant MRI data
AU - Shang, Ziyao
AU - Turja, Md Asadullah
AU - Feczko, Eric
AU - Houghton, Audrey
AU - Rueter, Amanda
AU - Moore, Lucille A.
AU - Snider, Kathy
AU - Hendrickson, Timothy
AU - Reiners, Paul
AU - Stoyell, Sally
AU - Kardan, Omid
AU - Rosenberg, Monica
AU - Elison, Jed T.
AU - Fair, Damien A.
AU - Styner, Martin A.
N1 - Publisher Copyright:
© 2022 Z. Shang et al.
PY - 2022
Y1 - 2022
N2 - Longitudinal studies of infants’ brains are essential for research and clinical detection of neurodevelopmental disorders. However, for infant brain MRI scans, effective deep learning-based segmentation frameworks exist only within small age intervals due to the large image intensity and contrast changes that take place in the early postnatal stages of development. However, using different segmentation frameworks or models at different age intervals within the same longitudinal data set would cause segmentation inconsistencies and age-specific biases. Thus, an age-agnostic segmentation model for infants’ brains is needed. In this paper, we present”Infant-SynthSeg”, an extension of the contrast-agnostic SynthSeg segmentation framework applicable to MRI data of infants at ages within the first year of life. Our work mainly focuses on extending learning strategies related to synthetic data generation and augmentation, with the aim of creating a method that employs training data capturing features unique to infants’ brains during this early-stage development. Comparison across different learning strategy settings, as well as a more-traditional contrast-aware deep learning model (nnU-net) are presented. Our experiments show that our trained Infant-SynthSeg models show consistently high segmentation performance on MRI scans of infant brains throughout the first year of life. Furthermore, as the model is trained on ground truth labels at different ages, even labels that are not present at certain ages (such as cerebellar white matter at 1 month) can be appropriately segmented via Infant-SynthSeg across the whole age range. Finally, while Infant-SynthSeg shows consistent segmentation performance across the first year of life, it is outperformed by age-specific deep learning models trained for a specific narrow age range.
AB - Longitudinal studies of infants’ brains are essential for research and clinical detection of neurodevelopmental disorders. However, for infant brain MRI scans, effective deep learning-based segmentation frameworks exist only within small age intervals due to the large image intensity and contrast changes that take place in the early postnatal stages of development. However, using different segmentation frameworks or models at different age intervals within the same longitudinal data set would cause segmentation inconsistencies and age-specific biases. Thus, an age-agnostic segmentation model for infants’ brains is needed. In this paper, we present”Infant-SynthSeg”, an extension of the contrast-agnostic SynthSeg segmentation framework applicable to MRI data of infants at ages within the first year of life. Our work mainly focuses on extending learning strategies related to synthetic data generation and augmentation, with the aim of creating a method that employs training data capturing features unique to infants’ brains during this early-stage development. Comparison across different learning strategy settings, as well as a more-traditional contrast-aware deep learning model (nnU-net) are presented. Our experiments show that our trained Infant-SynthSeg models show consistently high segmentation performance on MRI scans of infant brains throughout the first year of life. Furthermore, as the model is trained on ground truth labels at different ages, even labels that are not present at certain ages (such as cerebellar white matter at 1 month) can be appropriately segmented via Infant-SynthSeg across the whole age range. Finally, while Infant-SynthSeg shows consistent segmentation performance across the first year of life, it is outperformed by age-specific deep learning models trained for a specific narrow age range.
KW - Convolutional neural networks
KW - Data augmentation
KW - Deep learning
KW - Infant brain segmentation
KW - Neurodevelopmental Disorders
KW - Neuroimaging
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M3 - Conference article
AN - SCOPUS:85175466278
SN - 2640-3498
VL - 172
SP - 1075
EP - 1084
JO - Proceedings of Machine Learning Research
JF - Proceedings of Machine Learning Research
T2 - 5th International Conference on Medical Imaging with Deep Learning, MIDL 2022
Y2 - 6 July 2022 through 8 July 2022
ER -