VASO-based calculations of CBV change: Accounting for the dynamic CSF volume

Abstract

The goal of the vascular space occupancy (VASO) imaging technique is to use selective nulling of the blood signal to infer relative changes in cerebral blood volume (CBV). In accordance with recent work, we show that changes in the local CSF fraction (xc) with activation can significantly impact the VASO signal, thereby limiting our ability to infer ΔCBV from ΔVASO alone. Here we calculate CBV change using a VASO-based method which ACcounts for the Dynamic Cerebrospinal (ACDC) fluid fraction. By combining data from two separate VASO acquisitions that eliminate either the blood signal (VASO b) or the CSF signal (VASOc), a nonlinear least-squares optimization may then be used to simultaneously solve for the relative changes in CBV and CSF with activation. The method is applied across the whole brain during a breath-holding task, offering insight into the relationship between changes in CBV and xc associated with global vasodilatation. Calculations of mean changes in CBV in different volumes of interest obtained from the proposed method compare much better with previous (gold-standard) PET data than traditional VASO methods that do not account for a nonzero Δxc with activation. This confirms the necessity of incorporating the dynamic CSF volume into VASO-based calculations of ΔCBV. © 2008 Wiley-Liss, Inc.