Abstract
Dynamic susceptibility contrast (DSC) imaging is a widely used technique for assessment of cerebral blood volume (CBV). With combined gradient-echo and spin-echo DSC techniques, measures of the underlying vessel size and vessel architecture can be obtained from the vessel size index (VSI) and vortex area, respectively. However, how noise, and specifically the contrast-to-noise ratio (CNR), affect the estimations of these parameters has largely been overlooked. In order to address this issue, we have performed simulations to generate DSC signals with varying levels of CNR, defined by the peak of relaxation rate curve divided by the standard deviation of the baseline. Moreover, DSC data from 59 brain cancer patients were acquired at two different 3 T-scanners (N = 29 and N = 30, respectively), where CNR and relative parameter maps were obtained. Our simulations showed that the measured parameters were affected by CNR in different ways, where low CNR led to overestimations of CBV and underestimations of VSI and vortex area. In addition, a higher noise-sensitivity was found in vortex area than in CBV and VSI. Results from clinical data were consistent with simulations, and indicated that CNR < 4 gives highly unreliable measurements. Moreover, we have shown that the distribution of values in the tumour regions could change considerably when voxels with CNR below a given cut off are excluded when generating the relative parameter maps. The widespread use of CBV and attractive potential of VSI and vortex area, makes the noise-sensitivity of these parameters found in our study relevant for further use and development of the DSC imaging technique. Our results suggest that the CNR has considerable impact on the measured parameters, with the potential to affect the clinical interpretation of DSC-MRI, and should therefore be taken into account in the clinical decision-making process.
Highlights
Dynamic susceptibility contrast (DSC) magnetic resonance imaging (MRI) is widely used to assess cerebral perfusion in both clinical settings and research studies, and has proven clinically useful for various brain pathologies, including brain tumors, stroke and neurodegenerative disorders [1,2,3].DSC MRI is usually performed using either gradient-echo (GE) or spin-echo (SE) acquisitions, and measures of cerebral blood volume (CBV), cerebral blood flow (CBF) and mean transit time (MTT) are typically obtained from the relaxation rate curves
We have evaluated the contrast-to-noise ratio (CNR) in clinical GE and SE DSC from 59 patients with brain metastases (N = 29) and glioblastoma (N = 30) scanned at two different 3 T scanners, and performed simulations to investigate the effect of typical CNR levels found in clinical data
No significant difference in CNR was found in between the patient groups, except for a higher CNR in white matter (WM) for brain metastasis patients compared to glioblastoma patients (27.2 vs. 17.4, p < 0.05, Mann–Whitney U test)
Summary
DSC MRI is usually performed using either gradient-echo (GE) or spin-echo (SE) acquisitions, and measures of cerebral blood volume (CBV), cerebral blood flow (CBF) and mean transit time (MTT) are typically obtained from the relaxation rate curves. The different sensitivity to magnetic susceptibility between GE and SE read-outs leads to differences in R2GE(t) and R2SE(t), enabling the estimation of vascular parameters beyond conventional DSC. This includes the vessel size index (VSI), a measure of the weighted mean of the vessel sizes [4, 5], and the vortex area, a parameter that has been associated with the underlying vessel architecture of the tissue [6,7,8]. Several studies suggest that these parameters may hold great clinical value regarding stroke [9], tumor grading [10] and treatment response [7, 11,12,13]
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