Increased volume of coverage for abdominal contrast‐enhanced MR angiography with two‐dimensional autocalibrating parallel imaging: Initial experience at 3.0 Tesla

Lum, Darren P.; Busse, Reed F.; François, Christopher J.; Brau, Anja C. S.; Beatty, Philip J.; Huff, Joshua; Brittain, Jean H.; Reeder, Scott B.

doi:10.1002/jmri.21964

Cited by 28 publications

(20 citation statements)

References 31 publications

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“…The navigated sequence described in this work has been implemented with an autocalibrating parallel imaging reconstruction technique, known as autocalibrating reconstruction for Cartesian acquisition (ARC), that is capable of 2D acceleration using a full 3D kernel in k -space (31,32) with effective accelerations up to 3.75 easily achievable using an 8 channel coil (32). In this work, we chose not to use parallel imaging, both to maintain high SNR performance and also to facilitate valid SNR measurements, which are known to be difficult when parallel imaging methods are used (33).…”

Section: Discussionmentioning

confidence: 99%

High resolution navigated three‐dimensional T₁‐weighted hepatobiliary MRI using gadoxetic acid optimized for 1.5 tesla

Nagle

Busse

Brau³

et al. 2012

Magnetic Resonance Imaging

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Purpose To determine optimal delay times and flip angles for T1-weighted hepatobiliary imaging at 1.5T with gadoxetic acid and to demonstrate the feasibility of using a high-resolution navigated optimized T1-weighted pulse sequence to evaluate biliary disease. Materials and Methods Eight healthy volunteers were scanned at 1.5T using a T1-weighted 3D-SPGR pulse sequence following the administration of 0.05 mmol/kg of gadoxetic acid. Navigator-gating enabled acquisition of high spatial resolution (1.2 × 1.4 × 1.8 mm3, interpolated to 0.7 × 0.7 × 0.9 mm3) images in approximately 5 minutes of free breathing. Multiple breath-held acquisitions were performed at flip angles between 15° and 45° to optimize T1 weighting. To evaluate the performance of this optimized sequence in the setting of biliary disease, the image quality and biliary excretion of 51 consecutive clinical scans performed to assess primary sclerosing cholangitis (PSC) were evaluated. Results Optimal hepatobiliary imaging occurs at 15–25 minutes, using a 40° flip angle. The image quality and visualization of biliary excretion in the PSC scans were excellent, despite the decreased liver function in some patients. Visualization of reduced excretion often provided diagnostic information that was unavailable by conventional magnetic resonance cholangiopancreatography (MRCP). Conclusion High-resolution navigated 3D-SPGR hepatobiliary imaging using gadoxetic acid and optimized scan parameters is technically feasible and can be clinically useful, even in patients with decreased hepatobiliary function.

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Section: Discussionmentioning

confidence: 99%

High resolution navigated three‐dimensional T₁‐weighted hepatobiliary MRI using gadoxetic acid optimized for 1.5 tesla

Nagle

Busse

Brau³

et al. 2012

Magnetic Resonance Imaging

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“…Zero fi lling was used to interpolate resolution to 0.75 mm 2 , providing spatial resolution comparable to that of state-of-the-art renal contrast-enhanced MR angiography at 3.0 T ( 18 ). Twodimensional autocalibrating reconstruction for cartesian sampling parallel imaging was performed with the identical eight-element phased-array coil and acceleration in both section and phase directions ( 19 ), with a net acceleration factor of 3.75. The imaging duration was 30 seconds.…”

Section: Resultsmentioning

confidence: 99%

Renal Arteries: Isotropic, High-Spatial-Resolution, Unenhanced MR Angiography with Three-dimensional Radial Phase Contrast

François¹,

Lum²,

Johnson³

et al. 2011

Radiology

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Purpose:To prospectively compare a new three-dimensional (3D) radial phase-contrast magnetic resonance (MR) angiographic method with contrast material-enhanced MR angiography for anatomic assessment of the renal arteries. Materials and Methods:An institutional review board approved this prospective HIPAA-compliant study. Informed consent was obtained. Twenty-seven subjects (mean age, 52.6 years 6 20.5 [standard deviation]) were imaged with respiratory-gated phase-contrast vastly undersampled isotropic projection reconstruction (VIPR) prior to contrast-enhanced MR angiographic acquisition with a 3.0-T clinical system. The imaging duration for phase-contrast VIPR was 10 minutes and provided magnitude and complex difference ("angiographic") images with 3D volumetric (320 mm) coverage and isotropic high spatial resolution (1.25 mm 3 ). Quantitative analysis consisted of comparing vessel diameters between the two techniques. Qualitative assessment included evaluation of the phase-contrast VIPR and contrast-enhanced MR angiographic techniques for artifacts, noise, and image quality. Bland-Altman analysis was used for comparison of quantitative measurements, and the Wilcoxon signed rank test was used for comparison of qualitative scores. Results:Phase-contrast VIPR images were successfully acquired in all subjects. The vessel diameters measured with phasecontrast VIPR were slightly greater than those measured with contrast-enhanced MR angiography (mean bias = 0.09 mm). Differences in mean artifact, quality scores for the proximal renal arteries, and overall image quality scores between phase-contrast VIPR and contrast-enhanced MR angiographic techniques were not statistically signifi cant ( P = .31 and .29, .27 and .39, and .43 and .69 for readers 1 and 2, respectively). The quality scores for the segmental renal arteries were higher for phase-contrast VIPR than for contrast-enhanced MR angiography ( P , .05).Although the noise scores were higher with phase-contrast VIPR than with contrast-enhanced MR angiography and were statistically signifi cant ( P , .05), the presence of noise did not interfere with the ability to interpret the images. Conclusion:Isotropic, high-spatial-resolution, unenhanced MR angiography of the renal arteries is feasible with 3D radial undersampling.q RSNA, 2010 1

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“…Techniques including the family of parallel imaging reconstruction methods 1–4 have been successful in reducing clinical MRI scan times by factors of two or four, or even higher in some applications 5–8 . These acceleration techniques have also been used to improve image quality or reduce artifacts while maintaining scan time 9,10 . However, the scan time reduction with parallel imaging is limited, and other ways of reconstructing images from undersampled data have been explored, including sparse reconstruction methods such as compressed sensing 11–28 .…”

Section: Introductionmentioning

confidence: 99%

Sparse Reconstruction Techniques in Magnetic Resonance Imaging

Yang

Kretzler

Sudarski

et al. 2016

Investigative Radiology

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The family of sparse reconstruction techniques, including the recently introduced compressed sensing framework, has been extensively explored to reduce scan times in Magnetic Resonance Imaging (MRI). While there are many different methods that fall under the general umbrella of sparse reconstructions, they all rely on the idea that a priori information about the sparsity of MR images can be employed to reconstruct full images from undersampled data. This review describes the basic ideas behind sparse reconstruction techniques, how they could be applied to improve MR imaging, and the open challenges to their general adoption in a clinical setting. The fundamental principles underlying different classes of sparse reconstructions techniques are examined, and the requirements that each make on the undersampled data outlined. Applications that could potentially benefit from the accelerations that sparse reconstructions could provide are described, and clinical studies using sparse reconstructions reviewed. Lastly, technical and clinical challenges to widespread implementation of sparse reconstruction techniques, including optimization, reconstruction times, artifact appearance, and comparison with current gold-standards, are discussed.

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Increased volume of coverage for abdominal contrast‐enhanced MR angiography with two‐dimensional autocalibrating parallel imaging: Initial experience at 3.0 Tesla

Cited by 28 publications

References 31 publications

High resolution navigated three‐dimensional T₁‐weighted hepatobiliary MRI using gadoxetic acid optimized for 1.5 tesla

High resolution navigated three‐dimensional T₁‐weighted hepatobiliary MRI using gadoxetic acid optimized for 1.5 tesla

Renal Arteries: Isotropic, High-Spatial-Resolution, Unenhanced MR Angiography with Three-dimensional Radial Phase Contrast

Sparse Reconstruction Techniques in Magnetic Resonance Imaging

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Increased volume of coverage for abdominal contrast‐enhanced MR angiography with two‐dimensional autocalibrating parallel imaging: Initial experience at 3.0 Tesla

Cited by 28 publications

References 31 publications

High resolution navigated three‐dimensional T1‐weighted hepatobiliary MRI using gadoxetic acid optimized for 1.5 tesla

High resolution navigated three‐dimensional T1‐weighted hepatobiliary MRI using gadoxetic acid optimized for 1.5 tesla

Renal Arteries: Isotropic, High-Spatial-Resolution, Unenhanced MR Angiography with Three-dimensional Radial Phase Contrast

Sparse Reconstruction Techniques in Magnetic Resonance Imaging

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High resolution navigated three‐dimensional T₁‐weighted hepatobiliary MRI using gadoxetic acid optimized for 1.5 tesla

High resolution navigated three‐dimensional T₁‐weighted hepatobiliary MRI using gadoxetic acid optimized for 1.5 tesla