Yuan Le scite author profile

Purpose: To develop a new pulse sequence called timeresolved angiography with stochastic trajectories (TWIST) Dixon for dynamic contrast enhanced magnetic resonance imaging (DCE-MRI). Materials and Methods:The method combines dual-echo Dixon to generate separated water and fat images with a k-space view-sharing scheme developed for 3D TWIST. The performance of TWIST Dixon was compared with a volume interpolated breathhold examination (VIBE) sequence paired with spectrally selective adiabatic inversion Recovery (SPAIR) and quick fat-sat (QFS) fat-suppression techniques at 3.0T using quantitative measurements of fat-suppression accuracy and signal-to-noise ratio (SNR) efficiency, as well as qualitative breast image evaluations. Results:The water fraction of a uniform phantom was calculated from the following images: 0.66 6 0.03 for TWIST Dixon; 0.56 6 0.23 for VIBE-SPAIR, and 0.53 6 0.14 for VIBE-QFS, while the reference value is 0.70 measured by spectroscopy. For phantoms with contrast (Gd-BOPTA) concentration ranging from 0-6 mM, TWIST Dixon also provides consistently higher SNR efficiency (3.2-18.9) compared with VIBE-SPAIR (2.8-16.8) and VIBE-QFS (2.4-12.5). Breast images acquired with TWIST Dixon at 3.0T show more robust and uniform fat suppression and superior overall image quality compared with VIBE-SPAIR. Conclusion:The results from phantom and volunteer evaluation suggest that TWIST Dixon outperforms conventional methods in almost every aspect and it is a promising method for DCE-MRI and contrast-enhanced perfusion MRI, especially at higher field strength where fat suppression is challenging.

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Application of time‐resolved angiography with stochastic trajectories (twist)‐dixon in dynamic contrast‐enhanced (dce) breast mri

Kipfer

Majidi

et al. 2013

Magnetic Resonance Imaging

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Comparison of the Artifacts Caused by Metallic Implants in Breast MRI Using Dual-Echo Dixon Versus Conventional Fat-Suppression Techniques

Kipfer

Majidi

et al. 2014

American Journal of Roentgenology

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Improved T₁, contrast concentration, and pharmacokinetic parameter quantification in the presence of fat with two‐point dixon for dynamic contrast‐enhanced magnetic resonance imaging

Dale

Akisik

et al. 2015

Magnetic Resonance in Med

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Simultaneous myocardial strain and dark‐blood perfusion imaging using a displacement‐encoded MRI pulse sequence

Stein

Berry

et al. 2010

Magnetic Resonance in Med

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The purpose of this study is to develop and evaluate a displacement-encoded pulse sequence for simultaneous perfusion and strain imaging. Displacement-encoded images in two to three myocardial slices were repeatedly acquired using a single-shot pulse sequence for 3 to 4 min, which covers a bolus infusion of Gadolinium contrast. The magnitudes of the images were T 1 weighted and provided quantitative measures of perfusion, while the phase maps yielded strain measurements. In an acute coronary occlusion swine protocol (n 5 9), segmental perfusion measurements were validated against microsphere reference standard with a linear regression (slope 0.986, R 2 5 0.765, Bland-Altman standard deviation 5 0.15 mL/min/g). In a group of ST-elevation myocardial infarction patients (n 5 11), the scan success rate was 76%. Shortterm contrast washout rate and perfusion are highly correlated (R 2 5 0.72), and the pixelwise relationship between circumferential strain and perfusion was better described with a sigmoidal Hill curve than linear functions. This study demonstrates the feasibility of measuring strain and perfusion from a single set of images. Magn Reson Med 64:787-798, 2010. V C 2010 Wiley-Liss, Inc. Key words: ischemia; viability; myocardial perfusion; strain; first pass; DENSE Regional contractile function and perfusion are two key indices in the diagnosis and prognosis of ischemic heart disease. MRI can accurately assess myocardial wall motion and strain through several techniques, including tagged MRI (1-4), velocity-encoded MRI (5), and displacement-encoded MRI (6-8). Contrast-enhanced imaging, including first-pass (9-15) and delayed hyperenhancement MRI (16-21), provides information on the perfusion and viability status of the myocardial tissue. Whether the clinical situation is to assess the efficacy of reperfusion strategy with greater accuracy or to recognize patients who would require further therapy, the knowledge of both regional myocardial function and perfusion is helpful in differentiating among the various scenarios.An MRI pulse sequence capable of measuring myocardial perfusion and strain in a single data set, which thus far has not been generally possible in humans, would save scan time and facilitate perfusion-function correlation by eliminating the problem of registration. Imaging techniques that combine myocardial strain and delayed hyperenhancement imaging have been reported by several groups (22,23). However, these techniques employed interleaved acquisition of multiple images, which are combined into single-strain and delayed hyperenhancement images; therefore, they are not suited for first-pass perfusion imaging due to the time constraints.The purpose of this study is to develop a pulse sequence for simultaneous perfusion and strain imaging, to validate the perfusion measurement in a swine model, and to assess its performance in a group of acute myocardial infarction patients.The pulse sequence is a single-shot, multislice displacement-encoded (DENSE) (7) sequence. It was used to collect displace...

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Yuan Le

Development and evaluation of TWIST Dixon for dynamic contrast‐enhanced (DCE) MRI with improved acquisition efficiency and fat suppression

Application of time‐resolved angiography with stochastic trajectories (twist)‐dixon in dynamic contrast‐enhanced (dce) breast mri

Comparison of the Artifacts Caused by Metallic Implants in Breast MRI Using Dual-Echo Dixon Versus Conventional Fat-Suppression Techniques

Improved T₁, contrast concentration, and pharmacokinetic parameter quantification in the presence of fat with two‐point dixon for dynamic contrast‐enhanced magnetic resonance imaging

Simultaneous myocardial strain and dark‐blood perfusion imaging using a displacement‐encoded MRI pulse sequence

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Yuan Le

Development and evaluation of TWIST Dixon for dynamic contrast‐enhanced (DCE) MRI with improved acquisition efficiency and fat suppression

Application of time‐resolved angiography with stochastic trajectories (twist)‐dixon in dynamic contrast‐enhanced (dce) breast mri

Comparison of the Artifacts Caused by Metallic Implants in Breast MRI Using Dual-Echo Dixon Versus Conventional Fat-Suppression Techniques

Improved T1, contrast concentration, and pharmacokinetic parameter quantification in the presence of fat with two‐point dixon for dynamic contrast‐enhanced magnetic resonance imaging

Simultaneous myocardial strain and dark‐blood perfusion imaging using a displacement‐encoded MRI pulse sequence

Contact Info

Product

Resources

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Improved T₁, contrast concentration, and pharmacokinetic parameter quantification in the presence of fat with two‐point dixon for dynamic contrast‐enhanced magnetic resonance imaging