Multiple inversion recovery reduces static tissue signal in angiograms

Dixon, William J.; Sardashti, Maziar; Castillo, Maurício; Stomp, G.P.

doi:10.1002/mrm.1910180202

Cited by 91 publications

(100 citation statements)

References 13 publications

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“…Preparative multiple inversion RF pulses were used previously either for selective simultaneous zeroing of signals from two tissues with known T 1 (8,9) or for total suppression of a background signal from a variety of tissues (10,11). The first application is based on the double-inversion technique (8,9), whereas the second group of methods includes complex preparative sequences consisting of a 90°-pulse followed by two-, three-, or four inversion pulses (10,11). Unlike these techniques, in QIR the signal to be suppressed (i.e., from blood) is subjected only to the action of the inversion pulses, but it is not affected by an imaging part of the sequence or by additional 90°-pulses.…”

Section: Discussionmentioning

confidence: 99%

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T₁‐insensitive flow suppression using quadruple inversion‐recovery

Yarnykh

Yuan

2002

Magnetic Resonance in Med

117

110

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A new flow suppression method has been proposed for the acquisition of blood-suppressed (black-blood) images in combination with administration of a positive contrast agent. The technique employs the quadruple inversion-recovery (QIR) preparative pulse sequence, which consists of two double-inversion modules followed by two delays. Within each double inversion, a nonselective RF pulse is immediately followed by a slice-selective one. The time intervals of the sequence can be calculated using an algorithm based on minimization of the variation of a signal equation over an entire range of T 1 occurring in blood before and after contrast administration. QIR is highly insensitive to variations of Contrast-enhanced, blood-suppressed (black-blood) imaging of the vessel wall was recently proposed as a promising technique intended primarily for detection of neovasculature and inflammation in atherosclerotic plzzaque (1,2). In this challenging area, the black-blood contrast between the vessel wall and the lumen needs to be maintained despite considerable shortening of T 1 in blood after injection of a positive contrast agent. In addition, the quality of pre-and postcontrast images should allow for reliable measurement of contrast enhancement (CE) within different components of atherosclerotic plzzaque (1,2). The usefulness of postcontrast blood suppression was also demonstrated in brain imaging (3), where confusing venous enhancement and flow artifacts can be avoided. In the above applications (1-3), black-blood imaging was performed using the double inversion-recovery (DIR) method (4,5). Designed initially for inversion-based suppression of the signal from blood with normal physiological T 1 , DIR results in high-quality visualization of cardiovascular anatomy and is considered to be the most efficient black-blood imaging modality to date (6,7). However, the quality of blood suppression by DIR is highly sensitive to changes of T 1 in blood after contrast administration, because this method requires a precise knowledge of T 1 to calculate the proper inversion time (TI) (4,5). Usually, information about postcontrast T 1 of blood is unavailable in clinical contrast-enhanced imaging. Moreover, this parameter strongly depends on various factors, such as the properties and dosage of a contrast agent, the time between injection and data acquisition, the injection rate, and the physiological clearance of an individual patient. All of these factors make the postcontrast application of DIR uncertain, even if an initial guess about the expected T 1 can be made. Another limitation of DIR is related to the quantitative measurements of CE. To achieve good blood suppression, preand postcontrast DIR images should be obtained with different TI. At the same time, it may impose an instrumental bias in quantitative estimates due to partial saturation of stationary tissues produced by the DIR preparation. The resulting alterations of signal intensity have to be dependent on TI, especially in T 1 -weighted imaging with short repetition times...

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Section: Discussionmentioning

confidence: 99%

“…(10,11). This approach, however, is not suitable for the postcontrast blood suppression due to the wide variety of T 1 expected.…”

Section: Discussionmentioning

confidence: 99%

T₁‐insensitive flow suppression using quadruple inversion‐recovery

Yarnykh

Yuan

2002

Magnetic Resonance in Med

117

110

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“…Multiple inversion recovery can be used to suppress tissue water signal based on the T 1 difference between blood and tissue (30). T 1 difference between blood and tissue can be enhanced by the introduction of relaxation or contrast agents into the blood (31).…”

Section: Technical Considerationsmentioning

confidence: 99%

“…In their study, albumin-bound Gd-DTPA was used to reduce the T 1 of blood water. By utilizing large T 1 differences between tissue and blood water, blood signal can be predominantly obtained by selective nulling of tissue water using double inversion methods (30,31). Since the characteristics of blood flow is invariant regardless of probing methods, e.g., 19 (31)).…”

Section: Technical Considerationsmentioning

confidence: 99%

Relative changes of cerebral arterial and venous blood volumes during increased cerebral blood flow: Implications for BOLD fMRI

Lee

Duong

Yang

et al. 2001

Magnetic Resonance in Med

257

225

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Measurement of cerebral arterial and venous blood volumes during increased cerebral blood flow can provide important information regarding hemodynamic regulation under normal, pathological, and neuronally active conditions. In particular, the change in venous blood volume induced by neural activity is one critical component of the blood oxygenation level-dependent (BOLD) signal because BOLD contrast is dependent only on venous blood, not arterial blood. Thus, relative venous and arterial blood volume (rCBV) and cerebral blood flow (rCBF) in ␣-chlorolase-anesthetized rats under hypercapnia were measured by novel diffusion-weighted 19

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“…The successful approach of background suppression [7,8] is emphasized in the article of Maleki et al [9], where suppression is optimized and used to image blood flow to the eye. Since background suppression does reduce ASL signal by a significant factor, the community remains uncertain whether or how much background suppression to use.…”

mentioning

confidence: 99%

Arterial spin labeling: its time is now

Alsop

2012

Magn Reson Mater Phy

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It has been more than two decades since arterial spin labeling (ASL) perfusion MRI was introduced [1,2], yet its impact on research and clinical studies is just starting to be broadly appreciated. ASL has gone from an infancy where it was practiced in small animals by just a few experts, to a childhood of initial experience in humans and in more laboratories, and finally through an awkward adolescence where emerging capabilities were masked by imperfect coordination of methods, analysis, and distribution. As evidenced by the richness and variety of studies in this special edition of MAGMA, ASL has become a mature technology where widespread development and testing, exploration of clinical and research applications, and movement toward consensus on approaches are occurring today.While ASL methods are now advanced enough to provide routine, quantitative sequences for brain ASL and competent methods for some organs outside the brain, remaining limitations and the ongoing spirit of innovation in the community continue to drive new developments in ASL methods. Perhaps, nowhere is this more evident than in the wide assortment of labeling methods (and associated acronyms) that continue to be introduced and improved. In this issue alone, we see a paper on an innovative approach to mixing continuous and pulsed ASL [3], an exploration of the challenges of pseudo-continuous labeling in humans at 7 Tesla [4] and an investigation into unintended effects of pulses to shape the labeling bolus [5]. The exciting and exploding area of vessel-selective labeling to map perfusion territories is represented here by the New Concept article on random vessel encoding [6].A key issue restricting the reliability of ASL studies is the effect of motion and other instabilities on noise and artifacts in ASL. The successful approach of background suppression [7,8] is emphasized in the article of Maleki et al. [9], where suppression is optimized and used to image blood flow to the eye. Since background suppression does reduce ASL signal by a significant factor, the community remains uncertain whether or how much background suppression to use. For example, neither the reproducibility study of renal blood flow [10] nor the study of pulmonary perfusion in cystic fibrosis [11] employs substantial background suppression. Integrally related to the choice of background suppression is the choice of acquisition sequence. Traditionally, single-shot imaging with echoplanar imaging was used to minimize motion sensitivity, but the improving speed of other approaches and the reduced motion sensitivity provided by background suppression have encouraged the use of RARE, balanced SSFP [12], and even 3D spiral [8,13] or GRASE [14] sequences for acquisition. A key question in the choice and design of sequences is how many different images are required for quantification. Multiple images are required when T1 and especially transit time measurements are needed.The use of ASL in broad clinical populations has stimulated interest in better understanding arterial tran...

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Multiple inversion recovery reduces static tissue signal in angiograms

Cited by 91 publications

References 13 publications

T₁‐insensitive flow suppression using quadruple inversion‐recovery

T₁‐insensitive flow suppression using quadruple inversion‐recovery

Relative changes of cerebral arterial and venous blood volumes during increased cerebral blood flow: Implications for BOLD fMRI

Arterial spin labeling: its time is now

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Multiple inversion recovery reduces static tissue signal in angiograms

Cited by 91 publications

References 13 publications

T1‐insensitive flow suppression using quadruple inversion‐recovery

T1‐insensitive flow suppression using quadruple inversion‐recovery

Relative changes of cerebral arterial and venous blood volumes during increased cerebral blood flow: Implications for BOLD fMRI

Arterial spin labeling: its time is now

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T₁‐insensitive flow suppression using quadruple inversion‐recovery

T₁‐insensitive flow suppression using quadruple inversion‐recovery