Machine-learning to characterise neonatal functional connectivity in the preterm brain

Machine-learning to characterise neonatal functional connectivity in the preterm brain

Brain development is adversely affected by preterm birth. Magnetic resonance image analysis has revealed a complex fusion of structural alterations across all tissue compartments that are apparent by term-equivalent age, persistent into adolescence and adulthood, and associated with wide-ranging neu...

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Bibliographic Details
Published in:NeuroImage (Orlando, Fla.) Fla.), 2016-01, Vol.124 (Pt A), p.267-275
Main Authors: Ball, G., Aljabar, P., Arichi, T., Tusor, N., Cox, D., Merchant, N., Nongena, P., Hajnal, J.V., Edwards, A.D., Counsell, S.J.
Format: Article
Language:eng
Subjects:
Age
Babies
Brain - pathology
Brain - physiopathology
Brain development
Brain Mapping
Connectome - methods
Datasets
Female
fMRI
Humans
Infant, Newborn
Infant, Premature
Machine Learning
Magnetic Resonance Imaging
Male
NMR
Nuclear magnetic resonance
Population
Premature birth
Prematurity
Studies
Support vector machines
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Summary:Brain development is adversely affected by preterm birth. Magnetic resonance image analysis has revealed a complex fusion of structural alterations across all tissue compartments that are apparent by term-equivalent age, persistent into adolescence and adulthood, and associated with wide-ranging neurodevelopment disorders. Although functional MRI has revealed the relatively advanced organisational state of the neonatal brain, the full extent and nature of functional disruptions following preterm birth remain unclear. In this study, we apply machine-learning methods to compare whole-brain functional connectivity in preterm infants at term-equivalent age and healthy term-born neonates in order to test the hypothesis that preterm birth results in specific alterations to functional connectivity by term-equivalent age. Functional connectivity networks were estimated in 105 preterm infants and 26 term controls using group-independent component analysis and a graphical lasso model. A random forest–based feature selection method was used to identify discriminative edges within each network and a nonlinear support vector machine was used to classify subjects based on functional connectivity alone. We achieved 80% cross-validated classification accuracy informed by a small set of discriminative edges. These edges connected a number of functional nodes in subcortical and cortical grey matter, and most were stronger in term neonates compared to those born preterm. Half of the discriminative edges connected one or more nodes within the basal ganglia. These results demonstrate that functional connectivity in the preterm brain is significantly altered by term-equivalent age, confirming previous reports of altered connectivity between subcortical structures and higher-level association cortex following preterm birth. •Robust classification of preterm and term-born neonates using functional connectivity patterns.•Discriminative pattern of alterations in basal ganglia and frontal connections.•Reflects system-wide disruption of subcortical–cortical connections following preterm birth.
ISSN:1053-8119
1095-9572