fMRI-Based CSF Flow Quantification Identifies Cardiac Pulsatility as the Dominant Driver Over Respiratory and Slow Vasomotion Cycles

Studying cerebrospinal fluid (CSF) flow can reveal physiological and neural drivers of potential importance in brain clearance. CSF flow may be acquired in functional magnetic resonance imaging (fMRI) scans by considering the inflow effect in an edge-slice. Such measurements have large potential considering the broad availability of fMRI, and the already extensive databases focusing on e.g. aging and dementia. However, limiting factors are that the measurements are not quantitative and can rarely separate contributions from different driving mechanisms due to insufficient sampling rate. Here, we present a method that translates fMRI CSF signals into quantitative flow rates associated with cardiac, respiratory and slow-vasomotion cycles, by modeling the spin-history of an oscillating ensemble of molecules. Phantom experiments showed excellent correlations between estimated and true velocities for cardiac- and respiratory-like frequencies, and moderate correlations for a slow vasomotion-like frequency (r = 0.94, 0.97, 0.58 respectively). We also applied the method in a cohort of 48 subjects from the population (68-82 years, 19 women) to characterize CSF flow at the foramen magnum at resting state. These measurements showed a CSF stroke volume of 0.86 [0.61, 1.17] mL for the cardiac, 0.44 [0.25, 0.94] mL for the respiratory, and 0.28 [0.14, 0.45] mL for the slow vasomotion cycle. In conclusion, the method presented here enabled quantitative assessments of CSF flow compatible with typical fMRI acquisitions and showed that the cardiac cycle is a dominant driver of CSF flow.