Cerebral blood flow patterns in preterm and term neonates assessed with pseudo‐continuous arterial spin labeling perfusion MRI

In preterm (PT) infants, regional cerebral blood flow (CBF) disturbances may predispose to abnormal brain maturation even without overt brain injury. Therefore, it would be informative to determine the spatial distribution of grey matter (GM) CBF in PT and full‐term (FT) newborns at term‐equivalent age (TEA) and to assess the relationship between the features of the CBF pattern and both prematurity and prematurity‐related brain lesions. In this prospective study, we obtained measures of CBF in 66 PT (51 without and 15 with prematurity‐related brain lesions) and 38 FT newborns through pseudo‐continuous arterial spin labeling (pCASL) MRI acquired at TEA. The pattern of GM CBF was characterized by combining an atlas‐based automated segmentation of structural MRI with spatial normalization and hierarchical clustering. The effects of gestational age (GA) at birth and brain injury on the CBF pattern were investigated. We identified 4 physiologically‐derived clusters of brain regions that were labeled Fronto‐Temporal, Parieto‐Occipital, Insular‐Deep GM (DGM) and Sensorimotor, from the least to the most perfused. We demonstrated that GM perfusion was associated with GA at birth in the Fronto‐Temporal and Sensorimotor clusters, positively and negatively, respectively. Moreover, the presence of periventricular leukomalacia was associated with significantly increased Fronto‐Temporal GM perfusion and decreased Insular‐DGM perfusion, while the presence of germinal matrix hemorrhage appeared to mildly decrease the Insular‐DGM perfusion. Prematurity and prematurity‐related brain injury heterogeneously affect brain perfusion. ASL MRI may, therefore, have strong potential as a noninvasive tool for the accurate stratification of individuals at risk of domain‐specific impairment.