Practical considerations for territorial perfusion mapping in the cerebral circulation using super‐selective pseudo‐continuous arterial spin labeling

Purpose This paper discusses several challenges faced by super‐selective pseudo‐continuous arterial spin labeling, which is used to quantify territorial perfusion in the cerebral circulation. The effects of off‐resonance, pulsatility, vessel movement, and label rotation scheme are investigated, and...

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Published in	Magnetic resonance in medicine Vol. 83; no. 2; pp. 492 - 504
Main Authors	Schollenberger, Jonas, Figueroa, C. Alberto, Nielsen, Jon‐Fredrik, Hernandez‐Garcia, Luis
Format	Journal Article
Language	English
Published	United States Wiley Subscription Services, Inc 01.02.2020
Subjects	Adult arterial spin labeling Arteries - diagnostic imaging Blood Flow Velocity Blood vessels Brain - diagnostic imaging Calibration cardiac triggering Cerebral blood flow Cerebrovascular Circulation Compensation Computer Simulation Efficiency Female Heart Heart - diagnostic imaging Humans Image acquisition Image contrast Image quality Labeling labeling efficiency Magnetic Resonance Angiography Male Mapping Multiphase off‐resonance Perfusion Reproducibility of Results Resonance Rotation Signal-To-Noise Ratio Spin labeling Spin Labels super‐selective territorial perfusion Territory labeling efficiency cardiac triggering off-resonance super-selective territorial perfusion arterial spin labeling
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ISSN	0740-3194 1522-2594 1522-2594
DOI	10.1002/mrm.27936

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Abstract	Purpose This paper discusses several challenges faced by super‐selective pseudo‐continuous arterial spin labeling, which is used to quantify territorial perfusion in the cerebral circulation. The effects of off‐resonance, pulsatility, vessel movement, and label rotation scheme are investigated, and methods to maximize labeling efficiency and overall image quality are evaluated. A strategy to calculate the territorial perfusion fractions of individual vessels is proposed. Methods The effects of off‐resonance, label rotation scheme, and vessel movement on labeling efficiency were simulated. Two off‐resonance compensation strategies (multiphase prescan, field map), cardiac triggering, and vessel movement were studied in vivo in a group of 10 subjects. Subsequently, a territorial perfusion fraction map was acquired in 2 subjects based on the mean vessel labeling efficiency. Results Multiphase calibration provided the highest labeling efficiency (P = .002) followed by the field map compensation (P = .037) compared with the uncompensated acquisition. Cardiac triggering resulted in a qualitative improvement of the image and an increase in signal contrast between the perfusion territory and the surrounding tissue (P = .010) but failed to show a significant change in temporal and spatial SNR. The constant clockwise label rotation scheme yielded the highest labeling efficiency. Significant vessel movement (>2 mm according to simulations) was observed in 50% of subjects. The measured territorial perfusion fractions showed good agreement with anatomical data. Conclusion Optimized labeling efficiency resulted in increased image quality and accuracy of territorial perfusion fraction maps. Labeling efficiency depends critically on off‐resonance calibration, cardiac triggering, optimal label rotation scheme, and vessel location tracking.
AbstractList	This paper discusses several challenges faced by super-selective pseudo-continuous arterial spin labeling, which is used to quantify territorial perfusion in the cerebral circulation. The effects of off-resonance, pulsatility, vessel movement, and label rotation scheme are investigated, and methods to maximize labeling efficiency and overall image quality are evaluated. A strategy to calculate the territorial perfusion fractions of individual vessels is proposed.PURPOSEThis paper discusses several challenges faced by super-selective pseudo-continuous arterial spin labeling, which is used to quantify territorial perfusion in the cerebral circulation. The effects of off-resonance, pulsatility, vessel movement, and label rotation scheme are investigated, and methods to maximize labeling efficiency and overall image quality are evaluated. A strategy to calculate the territorial perfusion fractions of individual vessels is proposed.The effects of off-resonance, label rotation scheme, and vessel movement on labeling efficiency were simulated. Two off-resonance compensation strategies (multiphase prescan, field map), cardiac triggering, and vessel movement were studied in vivo in a group of 10 subjects. Subsequently, a territorial perfusion fraction map was acquired in 2 subjects based on the mean vessel labeling efficiency.METHODSThe effects of off-resonance, label rotation scheme, and vessel movement on labeling efficiency were simulated. Two off-resonance compensation strategies (multiphase prescan, field map), cardiac triggering, and vessel movement were studied in vivo in a group of 10 subjects. Subsequently, a territorial perfusion fraction map was acquired in 2 subjects based on the mean vessel labeling efficiency.Multiphase calibration provided the highest labeling efficiency (P = .002) followed by the field map compensation (P = .037) compared with the uncompensated acquisition. Cardiac triggering resulted in a qualitative improvement of the image and an increase in signal contrast between the perfusion territory and the surrounding tissue (P = .010) but failed to show a significant change in temporal and spatial SNR. The constant clockwise label rotation scheme yielded the highest labeling efficiency. Significant vessel movement (>2 mm according to simulations) was observed in 50% of subjects. The measured territorial perfusion fractions showed good agreement with anatomical data.RESULTSMultiphase calibration provided the highest labeling efficiency (P = .002) followed by the field map compensation (P = .037) compared with the uncompensated acquisition. Cardiac triggering resulted in a qualitative improvement of the image and an increase in signal contrast between the perfusion territory and the surrounding tissue (P = .010) but failed to show a significant change in temporal and spatial SNR. The constant clockwise label rotation scheme yielded the highest labeling efficiency. Significant vessel movement (>2 mm according to simulations) was observed in 50% of subjects. The measured territorial perfusion fractions showed good agreement with anatomical data.Optimized labeling efficiency resulted in increased image quality and accuracy of territorial perfusion fraction maps. Labeling efficiency depends critically on off-resonance calibration, cardiac triggering, optimal label rotation scheme, and vessel location tracking.CONCLUSIONOptimized labeling efficiency resulted in increased image quality and accuracy of territorial perfusion fraction maps. Labeling efficiency depends critically on off-resonance calibration, cardiac triggering, optimal label rotation scheme, and vessel location tracking. This paper discusses several challenges faced by super-selective pseudo-continuous arterial spin labeling, which is used to quantify territorial perfusion in the cerebral circulation. The effects of off-resonance, pulsatility, vessel movement, and label rotation scheme are investigated, and methods to maximize labeling efficiency and overall image quality are evaluated. A strategy to calculate the territorial perfusion fractions of individual vessels is proposed. The effects of off-resonance, label rotation scheme, and vessel movement on labeling efficiency were simulated. Two off-resonance compensation strategies (multiphase prescan, field map), cardiac triggering, and vessel movement were studied in vivo in a group of 10 subjects. Subsequently, a territorial perfusion fraction map was acquired in 2 subjects based on the mean vessel labeling efficiency. Multiphase calibration provided the highest labeling efficiency (P = .002) followed by the field map compensation (P = .037) compared with the uncompensated acquisition. Cardiac triggering resulted in a qualitative improvement of the image and an increase in signal contrast between the perfusion territory and the surrounding tissue (P = .010) but failed to show a significant change in temporal and spatial SNR. The constant clockwise label rotation scheme yielded the highest labeling efficiency. Significant vessel movement (>2 mm according to simulations) was observed in 50% of subjects. The measured territorial perfusion fractions showed good agreement with anatomical data. Optimized labeling efficiency resulted in increased image quality and accuracy of territorial perfusion fraction maps. Labeling efficiency depends critically on off-resonance calibration, cardiac triggering, optimal label rotation scheme, and vessel location tracking. PurposeThis paper discusses several challenges faced by super‐selective pseudo‐continuous arterial spin labeling, which is used to quantify territorial perfusion in the cerebral circulation. The effects of off‐resonance, pulsatility, vessel movement, and label rotation scheme are investigated, and methods to maximize labeling efficiency and overall image quality are evaluated. A strategy to calculate the territorial perfusion fractions of individual vessels is proposed.MethodsThe effects of off‐resonance, label rotation scheme, and vessel movement on labeling efficiency were simulated. Two off‐resonance compensation strategies (multiphase prescan, field map), cardiac triggering, and vessel movement were studied in vivo in a group of 10 subjects. Subsequently, a territorial perfusion fraction map was acquired in 2 subjects based on the mean vessel labeling efficiency.ResultsMultiphase calibration provided the highest labeling efficiency (P = .002) followed by the field map compensation (P = .037) compared with the uncompensated acquisition. Cardiac triggering resulted in a qualitative improvement of the image and an increase in signal contrast between the perfusion territory and the surrounding tissue (P = .010) but failed to show a significant change in temporal and spatial SNR. The constant clockwise label rotation scheme yielded the highest labeling efficiency. Significant vessel movement (>2 mm according to simulations) was observed in 50% of subjects. The measured territorial perfusion fractions showed good agreement with anatomical data.ConclusionOptimized labeling efficiency resulted in increased image quality and accuracy of territorial perfusion fraction maps. Labeling efficiency depends critically on off‐resonance calibration, cardiac triggering, optimal label rotation scheme, and vessel location tracking. Purpose This paper discusses several challenges faced by super‐selective pseudo‐continuous arterial spin labeling, which is used to quantify territorial perfusion in the cerebral circulation. The effects of off‐resonance, pulsatility, vessel movement, and label rotation scheme are investigated, and methods to maximize labeling efficiency and overall image quality are evaluated. A strategy to calculate the territorial perfusion fractions of individual vessels is proposed. Methods The effects of off‐resonance, label rotation scheme, and vessel movement on labeling efficiency were simulated. Two off‐resonance compensation strategies (multiphase prescan, field map), cardiac triggering, and vessel movement were studied in vivo in a group of 10 subjects. Subsequently, a territorial perfusion fraction map was acquired in 2 subjects based on the mean vessel labeling efficiency. Results Multiphase calibration provided the highest labeling efficiency (P = .002) followed by the field map compensation (P = .037) compared with the uncompensated acquisition. Cardiac triggering resulted in a qualitative improvement of the image and an increase in signal contrast between the perfusion territory and the surrounding tissue (P = .010) but failed to show a significant change in temporal and spatial SNR. The constant clockwise label rotation scheme yielded the highest labeling efficiency. Significant vessel movement (>2 mm according to simulations) was observed in 50% of subjects. The measured territorial perfusion fractions showed good agreement with anatomical data. Conclusion Optimized labeling efficiency resulted in increased image quality and accuracy of territorial perfusion fraction maps. Labeling efficiency depends critically on off‐resonance calibration, cardiac triggering, optimal label rotation scheme, and vessel location tracking.
Author	Figueroa, C. Alberto Nielsen, Jon‐Fredrik Schollenberger, Jonas Hernandez‐Garcia, Luis
AuthorAffiliation	1 Biomedical Engineering, University of Michigan, Ann Arbor, MI, USA 2 Surgery, University of Michigan, Ann Arbor, MI, USA 3 FMRI Laboratory, University of Michigan, Ann Arbor, MI, USA
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Snippet	Purpose This paper discusses several challenges faced by super‐selective pseudo‐continuous arterial spin labeling, which is used to quantify territorial... This paper discusses several challenges faced by super-selective pseudo-continuous arterial spin labeling, which is used to quantify territorial perfusion in... PurposeThis paper discusses several challenges faced by super‐selective pseudo‐continuous arterial spin labeling, which is used to quantify territorial...
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SubjectTerms	Adult arterial spin labeling Arteries - diagnostic imaging Blood Flow Velocity Blood vessels Brain - diagnostic imaging Calibration cardiac triggering Cerebral blood flow Cerebrovascular Circulation Compensation Computer Simulation Efficiency Female Heart Heart - diagnostic imaging Humans Image acquisition Image contrast Image quality Labeling labeling efficiency Magnetic Resonance Angiography Male Mapping Multiphase off‐resonance Perfusion Reproducibility of Results Resonance Rotation Signal-To-Noise Ratio Spin labeling Spin Labels super‐selective territorial perfusion Territory
Title	Practical considerations for territorial perfusion mapping in the cerebral circulation using super‐selective pseudo‐continuous arterial spin labeling
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