Segmented spin‐echo echo‐planar imaging improves whole‐brain BOLD functional MRI in awake pigeon brains

Abstract

AbstractFunctional magnetic resonance imaging (fMRI) in awake small animals such as pigeons or songbirds opens a new window into the neural fundaments of cognitive behavior. However, high‐field fMRI in the avian brain is challenging due to strong local magnetic field inhomogeneities caused by air cavities in the skull. A spoiled gradient‐echo fMRI sequence has already been used to map the auditory network in songbirds, but due to susceptibility artifacts only 50% of the whole brain could be recorded. Since whole‐brain fMRI coverage is vital to reveal whole‐brain networks, an MRI sequence that is less susceptible to these artifacts was required. This was recently achieved in various bird species by using a rapid acquisition with relaxation enhancement (RARE) sequence. Weak blood oxygen level‐dependent (BOLD) sensitivity, low temporal resolution, and heat caused by the long train of RF refocusing pulses are the main limits of RARE fMRI at high magnetic fields. To go beyond some of these limitations, we here describe the implementation of a two‐segmented spin‐echo echo‐planar imaging (SE‐EPI). The proposed sequence covers the whole brain of awake pigeons. The sequence was applied to investigate the auditory network in awake pigeons and assessed the relative merits of this method in comparison with the single‐shot RARE sequence. At the same imaging resolution but with a volume acquisition of 3 s versus 4 s for RARE, the two‐segmented SE‐EPI provided twice the strength of BOLD activity compared with the single‐shot RARE sequence, while the image signal‐to‐noise ratio (SNR) and in particular the temporal SNR were very similar for the two sequences. In addition, the activation patterns in two‐segmented SE‐EPI data are more symmetric and larger than single‐shot RARE results. Two‐segmented SE‐EPI represents a valid alternative to the RARE sequence in avian fMRI research since it yields more than twice the BOLD sensitivity per unit of time with much less energy deposition and better temporal resolution, particularly for event‐related experiments.