Comparison of multi-delay FAIR and pCASL labeling approaches for renal perfusion quantification at 3T MRI

Harteveld, Anita A.; Boer, A de; Franklin, Suzanne L.; Leiner, Tim; Stralen, Marijn van; Bos, Clemens

doi:10.1007/s10334-019-00806-7

Cited by 18 publications

(37 citation statements)

References 43 publications

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“…We found a 3× higher tSNR for FAIR compared to pCASL. Similar differences were found in a previous study, 24 where a detailed discussion is provided on the reasons why pCASL performed worse than FAIR in kidney at 3T, given that the opposite is true for the brain. Advantages of pCASL in brain include labeling closer to the imaging region and having a longer temporal bolus.…”

Section: Discussionsupporting

confidence: 88%

Multi‐organ comparison of flow‐based arterial spin labeling techniques: Spatially non‐selective labeling for cerebral and renal perfusion imaging

Franklin

Bones

Harteveld

et al. 2020

Magnetic Resonance in Med

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Purpose Flow‐based arterial spin labeling (ASL) techniques provide a transit‐time insensitive alternative to the more conventional spatially selective ASL techniques. However, it is not clear which flow‐based ASL technique performs best and also, how these techniques perform outside the brain (taking into account eg, flow‐dynamics, field‐inhomogeneity, and organ motion). In the current study we aimed to compare 4 flow‐based ASL techniques (ie, velocity selective ASL, acceleration selective ASL, multiple velocity selective saturation ASL, and velocity selective inversion prepared ASL [VSI‐ASL]) to the current spatially selective reference techniques in brain (ie, pseudo‐continuous ASL [pCASL]) and kidney (ie, pCASL and flow alternating inversion recovery [FAIR]). Methods Brain (n = 5) and kidney (n = 6) scans were performed in healthy subjects at 3T. Perfusion‐weighted signal (PWS) maps were generated and ASL techniques were compared based on temporal SNR (tSNR), sensitivity to perfusion changes using a visual stimulus (brain) and robustness to respiratory motion by comparing scans acquired in paced‐breathing and free‐breathing (kidney). Results In brain, all flow‐based ASL techniques showed similar tSNR as pCASL, but only VSI‐ASL showed similar sensitivity to perfusion changes. In kidney, all flow‐based ASL techniques had comparable tSNR, although all lower than FAIR. In addition, VSI‐ASL showed a sensitivity to B1‐inhomogeneity. All ASL techniques were relatively robust to respiratory motion. Conclusion In both brain and kidney, flow‐based ASL techniques provide a planning‐free and transit‐time insensitive alternative to spatially selective ASL techniques. VSI‐ASL shows the most potential overall, showing similar performance as the golden standard pCASL in brain. However, in kidney, a reduction of B1‐sensitivity of VSI‐ASL is necessary to match the performance of FAIR.

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Section: Discussionsupporting

confidence: 88%

Multi‐organ comparison of flow‐based arterial spin labeling techniques: Spatially non‐selective labeling for cerebral and renal perfusion imaging

Franklin

Bones

Harteveld

et al. 2020

Magnetic Resonance in Med

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“…Recently, multiple advances in ASL perfusion imaging were achieved by developing a pseudo-continuous ASL (pCASL), resulting in an SNR increase compared to conventional ASL [ 16 , 17 , 18 , 53 ]. pCASL perfusion images have higher spatial resolution compared to the present HP 129 Xe TOF images, mainly due to their significantly better developed hardware (multichannel coils used for parallel imaging during perfusion imaging) and software available for conducting proton ASL MRI.…”

Section: Discussionmentioning

confidence: 99%

“…SNR maps were created by dividing each pixel by the standard deviation of the noise region. Based on Killian's model of dissolved Xe 18 , the mathematical theory was generalized and applied for HP 129 Xe perfusion mapping (for a detailed explanation, see Supplementary Material S1). Three SNR maps created from TOF images and acquired with different recovery times were fitted pixel-by-pixel using the linear equation of the SNR delay time dependence (see Supplementary Material S2), and slope maps were created.…”

Section: Xe Perfusion Mapping Image Processingmentioning

confidence: 99%

“…Perfusion measurements can provide vital information about the homeostasis of an organ [ 1 ] and can therefore be used as biomarkers to diagnose cardiovascular [ 2 , 3 ], renal [ 4 ], and neurological [ 5 , 6 , 7 ] diseases. Currently, the most commonly used techniques to measure perfusion are 15 O positron emission tomography (PET) [ 8 , 9 , 10 ], xenon-enhanced computed tomography (CT) [ 11 , 12 ], single photon emission computed tomography (SPECT) [ 3 , 8 , 13 ], and arterial spin labeling (ASL) magnetic resonance imaging (MRI) [ 1 , 14 , 15 , 16 , 17 , 18 ]. In addition, dynamic susceptibility contrast (DSC) and dynamic contrast enhanced (DCE) MRI are frequently used for perfusion imaging [ 19 , 20 , 21 ].…”

Section: Introductionmentioning

confidence: 99%

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Hyperpolarized 129Xe Time-of-Flight MR Imaging of Perfusion and Brain Function

et al. 2020

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Perfusion measurements can provide vital information about the homeostasis of an organ and can therefore be used as biomarkers to diagnose a variety of cardiovascular, renal, and neurological diseases. Currently, the most common techniques to measure perfusion are 15O positron emission tomography (PET), xenon-enhanced computed tomography (CT), single photon emission computed tomography (SPECT), dynamic contrast enhanced (DCE) MRI, and arterial spin labeling (ASL) MRI. Here, we show how regional perfusion can be quantitively measured with magnetic resonance imaging (MRI) using time-resolved depolarization of hyperpolarized (HP) xenon-129 (129Xe), and the application of this approach to detect changes in cerebral blood flow (CBF) due to a hemodynamic response in response to brain stimuli. The investigated HP 129Xe Time-of-Flight (TOF) technique produced perfusion images with an average signal-to-noise ratio (SNR) of 10.35. Furthermore, to our knowledge, the first hemodynamic response (HDR) map was acquired in healthy volunteers using the HP 129Xe TOF imaging. Responses to visual and motor stimuli were observed. The acquired HP TOF HDR maps correlated well with traditional proton blood oxygenation level-dependent functional MRI. Overall, this study expands the field of HP MRI with a novel dynamic imaging technique suitable for rapid and quantitative perfusion imaging.

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“…Care was taken to acquire T 1 maps, ASL images, and M 0 images using the same field of view and voxel size, since these images had to be combined for ASL quantification. For timing of the QUIPPS settings in the flow attenuated inversion recovery arterial spin labeling (FAIR‐ASL) acquisition, please refer to the previous study 13 . For the first four patients a slightly different scan protocol for T 1 mapping and FAIR‐ASL was used.…”

Section: Methodsmentioning

confidence: 99%

Multiparametric Renal MRI: An Intrasubject Test–Retest Repeatability Study

Boer

Harteveld

Stemkens

et al. 2020

Magnetic Resonance Imaging

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Background Renal multiparametric magnetic resonance imaging (MRI) is a promising tool for diagnosis, prognosis, and treatment monitoring in kidney disease. Purpose To determine intrasubject test–retest repeatability of renal MRI measurements. Study Type Prospective. Population Nineteen healthy subjects aged over 40 years. Field Strength/Sequences T1 and T2 mapping, R2* mapping or blood oxygenation level‐dependent (BOLD) MRI, diffusion tensor imaging (DTI), and intravoxel incoherent motion (IVIM) diffusion‐weighted imaging (DWI), 2D phase contrast, arterial spin labelling (ASL), dynamic contrast enhanced (DCE) MRI, and quantitative Dixon for fat quantification at 3T. Assessment Subjects were scanned twice with ~1 week between visits. Total scan time was ~1 hour. Postprocessing included motion correction, semiautomated segmentation of cortex and medulla, and fitting of the appropriate signal model. Statistical Test To assess the repeatability, a Bland–Altman analysis was performed and coefficients of variation (CoVs), repeatability coefficients, and intraclass correlation coefficients were calculated. Results CoVs for relaxometry (T1, T2, R2*/BOLD) were below 6.1%, with the lowest CoVs for T2 maps and highest for R2*/BOLD. CoVs for all diffusion analyses were below 7.2%, except for perfusion fraction (FP), with CoVs ranging from 18–24%. The CoV for renal sinus fat volume and percentage were both around 9%. Perfusion measurements were most repeatable with ASL (cortical perfusion only) and 2D phase contrast with CoVs of 10% and 13%, respectively. DCE perfusion had a CoV of 16%, while single kidney glomerular filtration rate (GFR) had a CoV of 13%. Repeatability coefficients (RCs) ranged from 7.7–87% (lowest/highest values for medullary mean diffusivity and cortical FP, respectively) and intraclass correlation coefficients (ICCs) ranged from −0.01 to 0.98 (lowest/highest values for cortical FP and renal sinus fat volume, respectively). Data Conclusion CoVs of most MRI measures of renal function and structure (with the exception of FP and perfusion as measured by DCE) were below 13%, which is comparable to standard clinical tests in nephrology. Level of Evidence 2 Technical Efficacy Stage 1

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Comparison of multi-delay FAIR and pCASL labeling approaches for renal perfusion quantification at 3T MRI

Cited by 18 publications

References 43 publications

Multi‐organ comparison of flow‐based arterial spin labeling techniques: Spatially non‐selective labeling for cerebral and renal perfusion imaging

Multi‐organ comparison of flow‐based arterial spin labeling techniques: Spatially non‐selective labeling for cerebral and renal perfusion imaging

Hyperpolarized 129Xe Time-of-Flight MR Imaging of Perfusion and Brain Function

Multiparametric Renal MRI: An Intrasubject Test–Retest Repeatability Study

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