Fast, pseudo‐continuous arterial spin labeling for functional imaging using a two‐coil system

Hernandez‐García, Luis; Lee, Gregory R.; Vazquez, Alberto L.; Noll, Douglas C.

doi:10.1002/mrm.10733

Cited by 34 publications

(48 citation statements)

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“…With Turbo-CASL one can collect samples at a much faster rate compared to standard CASL techniques, and still allow for a long labeling time. In our previous publication (1) we showed that the Turbo-CASL method also had an advantage in terms of SNR per unit of time, even though the amount of accumulated tag is not allowed to reach its steady-state maximum. The method is very sensitive to transit time changes.…”

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confidence: 98%

“…We recently presented a new two-coil approach to continuous arterial spin labeling (CASL), (dubbed Turbo-CASL) (1), that significantly enhances the temporal resolution of ASL measurements while the SNR of the measurement is maintained. An additional benefit of the technique is that its sensitivity to transit time changes can be leveraged to increase the sensitivity to brain responses.…”

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confidence: 99%

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Quantification of perfusion fMRI using a numerical model of arterial spin labeling that accounts for dynamic transit time effects

Hernandez‐García

Lee

Vazquez

et al. 2005

Magnetic Resonance in Med

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We recently presented a new two-coil approach to continuous arterial spin labeling (CASL), (dubbed Turbo-CASL) (1), that significantly enhances the temporal resolution of ASL measurements while the SNR of the measurement is maintained. An additional benefit of the technique is that its sensitivity to transit time changes can be leveraged to increase the sensitivity to brain responses. In brief, Turbo-CASL consists of a continuous labeling experiment in which the control image is collected immediately after the tagging pulse, but before the tag reaches the plane of interest. The tagged image is collected when the tissue concentration of the label reaches its maximum. With Turbo-CASL one can collect samples at a much faster rate compared to standard CASL techniques, and still allow for a long labeling time. In our previous publication (1) we showed that the Turbo-CASL method also had an advantage in terms of SNR per unit of time, even though the amount of accumulated tag is not allowed to reach its steady-state maximum. The method is very sensitive to transit time changes. This makes quantification of perfusion more difficult, but it can also serve to exaggerate the perfusion increases that occur during activation and hence improve detection power, as shown in our previous work. In this follow-up paper we address the quantification issues that arise as a result of these transit time changes.Quantification of blood flow from ASL measurements is a difficult problem that requires the measurement of many parameters. A number of models have been presented to quantify perfusion, for a number of ASL acquisition schemes. These models are largely based on the first-order kinetics of the wash-in and wash-out of the inversion label into the tissue, taking into account its T 1 decay and exchange properties. The current models aim to quantify the microvascular perfusion, and consequently the larger arterial signal is routinely suppressed by the use of crusher gradients or postinversion delays. These delays have the added benefit of desensitizing the signal to the arterial transit time (ATT) (2-4). These models were developed for the cases of steady-state flow and transit time (5-10). Under such circumstances, the uptake of the arterial tag can be modeled as a linear system.However, in addition to the flow increase, neuronal activation is also accompanied by a reduction in the ATT of approximately 10 -20%, as observed by Gonzalez-At et al. (10) and Yang et al. (11). In the case of Turbo-CASL, we have calculated (1,12) that the signal can potentially change approximately 15% by a transit time change alone using the existing models.As a result, the ASL signal observed in our Turbo-CASL approach has nonlinear characteristics that are not easily explained by existing models, and likely distort the underlying flow response. In this study we extended the general framework of the kinetics of the arterial label to the case in which flow and transit times change dynamically in a given paradigm. We then developed and implemented a method...

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confidence: 98%

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Quantification of perfusion fMRI using a numerical model of arterial spin labeling that accounts for dynamic transit time effects

Hernandez‐García

Lee

Vazquez

et al. 2005

Magnetic Resonance in Med

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“…However, for the primary cortices, such as M1, a selection of data is available. The 26% CBF change in M1 upon pressing the Yes/No button during the Stroop task can be associated with CBF changes in M1 of the order of 60 -100% observed during more demanding finger-tapping tasks (Hernandez-Garcia et al, 2004;Mildner et al, 2003). Although such differences seem reasonable, more data are required to interpret the CBF changes as ''degree of activation''.…”

Section: Discussionmentioning

confidence: 97%

“…For this purpose, we use data from a recent finger-tapping study (Hernandez-Garcia et al, 2004), which reported an arterial transit-time change of 150 ms and a signal increase of 83%, both averaged over five subjects. The relative blood-flow increase obtained from this signal increase is about 66%.…”

Section: Discussionmentioning

confidence: 99%

“…This study had utilized a post-label delay (PLD) of the order of the maximum transit time to reduce the transit-time dependence of the CASL signal change (Alsop and Detre, 1996). If short PLDs are employed, functional changes of the transit time additionally contribute to the CASL signal change upon stimulation (Gonzalez-At et al, 2000;Hernandez-Garcia et al, 2004). In the latter study, a dual-coil setup with a sampling interval of the order of the arterial transit time was employed to map CBF changes in the primary motor cortex during finger tapping.…”

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Towards quantification of blood-flow changes during cognitive task activation using perfusion-based fMRI

et al. 2005

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Multi-slice perfusion-based functional magnetic resonance imaging (pfMRI) is demonstrated with a color -word Stroop task as an established cognitive paradigm. Continuous arterial spin labeling (CASL) of the blood in the left common carotid artery was applied for all repetitions of the functional run in a quasi-continuous fashion, i.e., it was interrupted only during image acquisition. For comparison, blood oxygen level dependent (BOLD) contrast was detected using conventional gradient-recalled echo (GE) echo planar imaging (EPI). Positive activations in BOLD imaging appeared in p-fMRI as negative signal changes corresponding to an enhanced transport of inverted water spins into the region of interest, i.e., increased cerebral blood flow (CBF). Regional differences between the localization of activations and the sensitivity of p-fMRI and BOLD-fMRI were observed as, for example, in the inferior frontal sulcus and in the intraparietal sulcus. Quantification of CBF changes during cognitive task activation was performed on a multi-subject basis and yielded CBF increases of the order of 20 -30%. D 2005 Elsevier Inc. All rights reserved.Keywords: Arterial spin labeling; Cerebral blood flow; Functional perfusion imaging; Quantification; fMRI; Cognitive task activation IntroductionIn the last decade, perfusion imaging using magnetic resonance imaging (MRI) techniques with water as an endogenous tracer has been a topic of growing research. From early on, the perfusion contrast created by magnetically labeling of the blood or the tissue was also employed for mapping task-related brain activity (Edelman et al., 1994;Kwong et al., 1992). However, due to its higher sensitivity, the blood oxygen level dependent (BOLD) contrast became the standard tool for functional MRI (fMRI). Despite this fact, interest in perfusion-based fMRI (p-fMRI) remained high.Expected improvements in the localization of activation due to the capillary/tissue origin of the perfusion contrast, and in the quantification of functional signal changes were the attracting arguments (Buxton et al., 1998;Siewert et al., 1996;Yang et al., 1998;Ye et al., 1997). Techniques were developed to increase the number of slices, to reduce the transit-time sensitivity, and to improve the time resolution in p-fMRI (Alsop and Detre, 1998;Calamante et al., 1999;Pekar et al., 1996;Zhang et al., 1995). It was shown that p-fMRI has some additional advantages for multisubject studies or at low task frequencies (Wang et al., 2003). However, except for a single-slice study employing a workingmemory task , all published studies were limited to primary cortical areas, such as the visual or the motor cortex.The aim of the present work was to detect more subtle functional changes of cerebral blood flow (CBF) related to a cognitive task in different areas of the human brain. For this purpose, a continuous arterial spin labeling (CASL) approach with separate labeling and imaging coils was employed (Zaharchuk et al., 1999). With this technique, all blood entering the brain through one c...

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Choice in fertility preservation in girls and adolescent women with cancer

Nisker

Βaylis

McLeod

2006

Cancer

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With the cure rate for many pediatric malignancies now between 70% and 90%, infertility becomes an increasingly important issue. Strategies for preserving fertility in girls and adolescent women occur in two distinct phases. The first phase includes oophorectomy (usually unilateral) and cryopreservation of ovarian cortex slices or individual oocytes; ultrasound-guided needle aspiration of oocytes, with or without in vitro maturation (IVM), followed by cryopreservation; and ovarian autografting to a distant site. The second phase occurs if the woman chooses to pursue pregnancy, and includes IVM of the oocytes, followed by in vitro fertilization (IVF) and transfer of any created embryos to the woman's uterus (or to a surrogate's uterus if the cancer patient's uterus has been surgically removed or the endometrium destroyed by radiotherapy). For ovarian autografting, the woman would undergo menotropin ovarian stimulation and retrieval of matured oocytes (likely by laparotomy, but possibly by ultrasound-guided needle aspiration if the ovary is positioned in an inaccessible location). The ethical challenges with each of these phases are many of fertility preservation and include issues of informed choice (consent or refusal). The lack of proven benefit with these strategies and the associated potential physical and psychological harms require careful attention to the key elements of informed choice, which include decisional capacity, disclosure, understanding and voluntariness, and to the benefits of in-depth counseling to promote free and informed choice at a time that is emotionally difficult for the decision makers.

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Fast, pseudo‐continuous arterial spin labeling for functional imaging using a two‐coil system

Cited by 34 publications

References 27 publications

Quantification of perfusion fMRI using a numerical model of arterial spin labeling that accounts for dynamic transit time effects

Quantification of perfusion fMRI using a numerical model of arterial spin labeling that accounts for dynamic transit time effects

Towards quantification of blood-flow changes during cognitive task activation using perfusion-based fMRI

Choice in fertility preservation in girls and adolescent women with cancer

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