Evaluation of left ventricular ejection fraction using through-time radial GRAPPA

Aandal, Gunhild; Nadig, Vidya; Yeh, Victoria; Rajiah, Prabhakar; Jenkins, Trevor; Sattar, Abdus; Griswold, Mark A.; Gulani, Vikas; Gilkeson, Robert C.; Seiberlich, Nicole

doi:10.1186/s12968-014-0079-8

Cited by 30 publications

(39 citation statements)

References 29 publications

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“…23,24 CS real-time cine MRI is a useful approach in such patients because single-shot acquisition is inherently insensitive to motion artefacts caused by arrhythmia or breathing. 11, 12 We believe that the CS tech- Data given as mean ± SD. Abbreviations as in Tables 2,3.…”

Section: Discussionmentioning

confidence: 99%

“…10 To overcome this limitation, imaging data have been acquired over 2 heart beats, thus capturing the complete end-diastole between the first and second heart beats. 10 Given that CS cine MRI has the advantage of being inherently insensitive to respiratory motion because of single-shot acquisition, 11,12 it is suitable for free-breathing (FB) imaging. The purpose of this study was therefore to compare the accuracy of FB full cardiac cycle CS and BH standard cine MRI at 3.0 T for LV volume assessment in patients with cardiac conditions.…”

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confidence: 99%

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Assessment of Left Ventricular Function and Mass on Free-Breathing Compressed Sensing Real-Time Cine Imaging

Kido

Nakamura

Watanabe

et al. 2017

Circ J

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stolic volume (EDV) and, consequently, variations in stroke volume (SV) and ejection fraction (EF) relative to ECG-gated retrospective standard cine MRI. 10 To overcome this limitation, imaging data have been acquired over 2 heart beats, thus capturing the complete end-diastole between the first and second heart beats. 10 Given that CS cine MRI has the advantage of being inherently insensitive to respiratory motion because of single-shot acquisition, 11,12 it is suitable for free-breathing (FB) imaging. The purpose of this study was therefore to compare the accuracy of FB full cardiac cycle CS and BH standard cine MRI at 3.0 T for LV volume assessment in patients with cardiac conditions. Methods SubjectsThis prospective study was approved by the ethics review board of Saiseikai Matsuyama Hospital. All participants gave written consent for participation in the study. Seventy-one consecutive patients who were scheduled to R etrospective electrocardiogram (ECG)-gated cine magnetic resonance imaging (MRI) with breath hold (BH) is generally considered the standard method for assessment of left ventricular (LV) function. 1,2 This imaging sequence, however, requires multiple BH scans to cover the entire LV, thus prolonging the duration of cardiovascular MRI (CMR). In addition, many patients who undergo CMR have dyspnea, and difficulty tolerating BH. Poor BH technique can lead to poor image quality and low accuracy of LV functional assessment. Several acceleration techniques have been developed to reduce the BH duration in cine MRI. 3-5 Recently, compressed sensing (CS) with sparse sampling and iterative reconstruction was proven to reduce MRI acquisition time drastically. 6 Clinical studies have reported the utility of this technique in cine MRI for assessment of LV function with 1.5-T and 3.0-T MRI scanners. 7-10 Prospective ECG-triggered CS cine MRI, however, might be unable to capture the first and last phases of the cardiac cycle, because the acquisition window is set to a fixed length at the beginning of the scan.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Assessment of Left Ventricular Function and Mass on Free-Breathing Compressed Sensing Real-Time Cine Imaging

Kido

Nakamura

Watanabe

et al. 2017

Circ J

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“…SENSE with spiral sampling has been used to accelerate velocity-encoded MRI [81]. Through-time non-Cartesian GRAPPA has been used to collect real-time cardiac data without breathholds or electrocardiogram gating in 45ms per 2D frame with radial sampling (Figure 12) [70,82] and 35ms per frame with spiral sampling [71]. Non-Cartesian GRAPPA has also been applied for renal MRA [72], myocardial [83] and liver perfusion [84], and abdominal T 1 mapping [85].…”

Section: Non-cartesian Parallel Imagingmentioning

confidence: 99%

Recent advances in parallel imaging for MRI

Hamilton

Franson

Seiberlich

2017

Progress in Nuclear Magnetic Resonance Spectroscopy

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Magnetic Resonance Imaging (MRI) is an essential technology in modern medicine. However, one of its main drawbacks is the long scan time needed to localize the MR signal in space to generate an image. This review article summarizes some basic principles and recent developments in parallel imaging, a class of image reconstruction techniques for shortening scan time. First, the fundamentals of MRI data acquisition are covered, including the concepts of k-space, undersampling, and aliasing. It is demonstrated that scan time can be reduced by sampling a smaller number of phase encoding lines in k-space; however, without further processing, the resulting images will be degraded by aliasing artifacts. Nearly all modern clinical scanners acquire data from multiple independent receiver coil arrays. Parallel imaging methods exploit properties of these coil arrays to separate aliased pixels in the image domain or to estimate missing k-space data using knowledge of nearby acquired k-space points. Three parallel imaging methods—SENSE, GRAPPA, and SPIRiT—are described in detail, since they are employed clinically and form the foundation for more advanced methods. These techniques can be extended to non-Cartesian sampling patterns, where the collected k-space points do not fall on a rectangular grid. Non-Cartesian acquisitions have several beneficial properties, the most important being the appearance of incoherent aliasing artifacts. Recent advances in simultaneous multi-slice imaging are presented next, which use parallel imaging to disentangle images of several slices that have been acquired at once. Parallel imaging can also be employed to accelerate 3D MRI, in which a contiguous volume is scanned rather than sequential slices. Another class of phase-constrained parallel imaging methods takes advantage of both image magnitude and phase to achieve better reconstruction performance. Finally, some applications are presented of parallel imaging being used to accelerate MR Spectroscopic Imaging.

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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 .…”

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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Evaluation of left ventricular ejection fraction using through-time radial GRAPPA

Cited by 30 publications

References 29 publications

Assessment of Left Ventricular Function and Mass on Free-Breathing Compressed Sensing Real-Time Cine Imaging

Assessment of Left Ventricular Function and Mass on Free-Breathing Compressed Sensing Real-Time Cine Imaging

Recent advances in parallel imaging for MRI

Sparse Reconstruction Techniques in Magnetic Resonance Imaging

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