Zero-echo time imaging achieves whole brain activity mapping without ventral signal loss in mice
Listed in
This article is not in any list yet, why not save it to one of your lists.Abstract
Functional MRI (fMRI) is an important tool for investigating functional networks. However, the widely used fMRI with T2*-weighted imaging in rodents has the problem of signal lack in the lateral ventral area of forebrain including the amygdala, which is essential for not only emotion but also noxious pain. Here, we scouted the zero-echo time (ZTE) sequence, which is robust to magnetic susceptibility and motion-derived artifacts, to image activation in the whole brain including the amygdala following the noxious stimulation to the hind paw. ZTE exhibited higher spatial and temporal signal-to-noise ratios than conventional fMRI sequences. Electrical sensory stimulation of the hind paw evoked ZTE signal increase in the primary somatosensory cortex. Formalin injection into the hind paw evoked early and latent change of ZTE signals throughout the whole brain including the subregions of amygdala.
Furthermore, resting-state fMRI using ZTE demonstrated the functional connectivity, including that of the amygdala. These results indicate the feasibility of ZTE for whole brain fMRI, including the amygdala and we first show acute and latent activity in different subnuclei of the amygdala complex after nociceptive stimulation.
Significance statement
Functional MRI (fMRI) is an important tool for investigating functional networks. However, the widely used fMRI in rodents has the problem of signal lack in the lateral ventral area of forebrain including the amygdala, which is essential for not only emotion but also noxious pain. Here, we used zero-echo time (ZTE) sequence, which was robust to susceptibility artifacts, for functional imaging in the whole brain including amygdala. We demonstrated the feasibility and advantages of using ZTE to investigate neuronal activity in mice. Furthermore, we first showed acute and latent activation in different subnuclei of the amygdala complex as well as other regions related to pain after nociceptive stimulation in mice.
