Arterial transit artifacts observed by arterial spin labeling in Moyamoya disease

•Arterial transit artifact (ATA) cause underestimation at a low perfusion.•The ATA score moderately correlated with MRA score.•The ivy sign was the most potent factor for a high ATA score.•ATA might suggest a reduction in the cerebrovascular reserve capacity. Objectives: Arterial spin labeling (ASL)...

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Published in:Journal of stroke and cerebrovascular diseases 2020-09, Vol.29 (9), p.105058-105058, Article 105058
Main Authors: Ukai, Ryo, Mikami, Takeshi, Nagahama, Hiroshi, Wanibuchi, Masahiko, Akiyama, Yukinori, Miyata, Kei, Mikuni, Nobuhiro
Format: Article
Language:English
Subjects:
ASL
ATA
CBF
cerebral perfusion
Moyamoya disease
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Summary:•Arterial transit artifact (ATA) cause underestimation at a low perfusion.•The ATA score moderately correlated with MRA score.•The ivy sign was the most potent factor for a high ATA score.•ATA might suggest a reduction in the cerebrovascular reserve capacity. Objectives: Arterial spin labeling (ASL) is a magnetic resonance imaging (MRI) technique used to assess cerebral perfusion. When tissue perfusion is impaired, such as in Moyamoya disease, a hyperintense band called the arterial transit artifact (ATA) may occur, which interferes with accurate measurements on ASL-MRI. In this study, we evaluated the correlation of ATAs with magnetic resonance angiography (MRA) and single-photon emission computed tomography (SPECT) imaging results in Moyamoya disease. The aim of our study was to elucidate the pathophysiology of ATAs and risk factors for high ATA scores. Materials and Methods: This retrospective study included 28 patients (56 hemispheres) with Moyamoya disease treated at our institution. MRI, MRA, ASL perfusion, and N-isopropyl-[123I] b-iodoamphetamine (123I-IMP) SPECT were performed. In order to semi-quantitatively evaluate the degree of ATA, the ATA scores were measured according to the number of hyperintense signal bands in the cerebral cortex. The relationship between the ATA scores and clinical and radiological factors were analyzed. Results: Regional cerebral blood flow (rCBF) determined with ASL weakly correlated with that determined by 123I-IMP SPECT (ρ=0.31, p=0.027). There was no significant association between the ATA scores and rCBF values determined with 123I-IMP SPECT (p=0.872, 0.745, 0.743 at PLD1000 (post-labeling delay), 1500, and 2000, respectively). However, there was a significant correlation between ATA scores and MRA scores (ρ=0.427 p=0.001; ρ=0.612 p=0.001; ρ=0.563 p=0.001 at PLD1000, 1500, and 2000, respectively). An analysis of patient background characteristics revealed a significantly higher incidence of high ATA scores in female patients, patients with high MRA scores, and patients with a distinguishable ivy sign. A multivariate analysis confirmed that female sex, high MRA score, and presence of an ivy sign were risk factors for high ATA scores. Conclusion: ATA scores were moderately correlated with MRA scores, and presence of an ivy sign was the most predictive factor for high ATA scores. A high ATA score determined using ASL in a patient with Moyamoya disease might suggest an advanced disease stage and a reduction in cerebrov
ISSN:1052-3057
1532-8511
DOI:10.1016/j.jstrokecerebrovasdis.2020.105058