| Literature DB >> 25008959 |
Giulio Ferrazzi1, Maria Kuklisova Murgasova2, Tomoki Arichi3, Christina Malamateniou2, Matthew J Fox2, Antonios Makropoulos2, Joanna Allsop2, Mary Rutherford2, Shaihan Malik2, Paul Aljabar2, Joseph V Hajnal2.
Abstract
There is growing interest in exploring fetal functional brain development, particularly with Resting State fMRI. However, during a typical fMRI acquisition, the womb moves due to maternal respiration and the fetus may perform large-scale and unpredictable movements. Conventional fMRI processing pipelines, which assume that brain movements are infrequent or at least small, are not suitable. Previous published studies have tackled this problem by adopting conventional methods and discarding as much as 40% or more of the acquired data. In this work, we developed and tested a processing framework for fetal Resting State fMRI, capable of correcting gross motion. The method comprises bias field and spin history corrections in the scanner frame of reference, combined with slice to volume registration and scattered data interpolation to place all data into a consistent anatomical space. The aim is to recover an ordered set of samples suitable for further analysis using standard tools such as Group Independent Component Analysis (Group ICA). We have tested the approach using simulations and in vivo data acquired at 1.5 T. After full motion correction, Group ICA performed on a population of 8 fetuses extracted 20 networks, 6 of which were identified as matching those previously observed in preterm babies.Entities:
Keywords: Bias field correction; Fetal fMRI; Resting State Networks; Scattered interpolation; Slice to volume registration; Spin history correction
Mesh:
Year: 2014 PMID: 25008959 DOI: 10.1016/j.neuroimage.2014.06.074
Source DB: PubMed Journal: Neuroimage ISSN: 1053-8119 Impact factor: 6.556