Laminar perfusion imaging with zoomed arterial spin labeling at 7 Tesla
•Zoomed 3D ASL technique at 7T for laminar perfusion imaging.•Quantitative CBF measurements both at baseline and during task activation.•Laminar profiles of ATT and CBF consistent with cortical microvascular density.•Two-peak CBF finger tapping activation in human motor cortex.•Predominant CBF incre...
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Veröffentlicht in: | NeuroImage (Orlando, Fla.) Fla.), 2021-12, Vol.245, p.118724-118724, Article 118724 |
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Zusammenfassung: | •Zoomed 3D ASL technique at 7T for laminar perfusion imaging.•Quantitative CBF measurements both at baseline and during task activation.•Laminar profiles of ATT and CBF consistent with cortical microvascular density.•Two-peak CBF finger tapping activation in human motor cortex.•Predominant CBF increase in deep layers by visual spatial attention.
Laminar fMRI based on BOLD and CBV contrast at ultrahigh magnetic fields has been applied for studying the dynamics of mesoscopic brain networks. However, the quantitative interpretations of BOLD/CBV fMRI results are confounded by different baseline physiology across cortical layers. Here we introduce a novel 3D zoomed pseudo-continuous arterial spin labeling (pCASL) technique at 7T that offers the capability for quantitative measurements of laminar cerebral blood flow (CBF) both at rest and during task activation with high spatial specificity and sensitivity. We found arterial transit time in superficial layers is ∼100 ms shorter than in middle/deep layers revealing the time course of labeled blood flowing from pial arteries to downstream microvasculature. Resting state CBF peaked in the middle layers which is highly consistent with microvascular density measured from human cortex specimens. Finger tapping induced a robust two-peak laminar profile of CBF increases in the superficial (somatosensory and premotor input) and deep (spinal output) layers of M1, while finger brushing task induced a weaker CBF increase in superficial layers (somatosensory input). This observation is highly consistent with reported laminar profiles of CBV activation on M1. We further demonstrated that visuospatial attention induced a predominant CBF increase in deep layers and a smaller CBF increase on top of the lower baseline CBF in superficial layers of V1 (feedback cortical input), while stimulus driven activity peaked in the middle layers (feedforward thalamic input). With the capability for quantitative CBF measurements both at baseline and during task activation, high-resolution ASL perfusion fMRI at 7T provides an important tool for in vivo assessment of neurovascular function and metabolic activities of neural circuits across cortical layers.
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ISSN: | 1053-8119 1095-9572 |
DOI: | 10.1016/j.neuroimage.2021.118724 |