Spectral phase‐corrected GRAPPA reconstruction of three‐dimensional echo‐planar spectroscopic imaging (3D‐EPSI)

Zhu, Xiaoping; Ebel, Andreas; Ji, Jim; Schuff, Norbert

doi:10.1002/mrm.21217

Cited by 33 publications

(44 citation statements)

References 12 publications

(20 reference statements)

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“…A number of studies have investigated the use of SENSE and GRAPPA for 1 H MRSI were presented by Dydak et al (28,29), Tsai et al (30), Lin et al (31), Ozturk-Isik et al (32,33), Bannerjee et al (34) and Zhu et al (35). While the results demonstrated were promising, there were clearly trade-offs in terms of artifacts and reconstruction times that should be considered in using such approaches.…”

Section: Alternative Encoding Methodsmentioning

confidence: 99%

“…While this technology would clearly benefit from the use of parallel imaging with receiver coil arrays (35), there have been a relatively small number of such studies to date. This is partly due to the limited number of applications to larger animals or humans and partly to the limited availability of multi-nuclear, multi-channel rf coils.…”

Section: Acquisition Of Hyperpolarized C-13 Mrsi Datamentioning

confidence: 99%

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Strategies for rapid in vivo 1H and hyperpolarized 13C MR spectroscopic imaging

Nelson

Ozhinsky

et al. 2013

Journal of Magnetic Resonance

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In vivo MRSI is an important imaging modality that has been shown in numerous research studies to give biologically relevant information for assessing the underlying mechanisms of disease and for monitoring response to therapy. The increasing availability of high field scanners and multichannel radiofrequency coils has provided the opportunity to acquire in vivo data with significant improvements in sensitivity and signal to noise ratio. These capabilities may be used to shorten acquisition time and provide increase coverage. The ability to acquire rapid, volumetric MRSI data is critical for examining heterogeneity in metabolic profiles and for relating serial changes in metabolism within the same individual during the course of the disease. In this review we discuss the implementation of strategies that use alternative k-space sampling trajectories and parallel imaging methods in order to speed up data acquisition. The impact of such methods is demonstrated using three recent examples of how these methods have been applied. These are to the acquisition of robust 3D 1H MRSI data within 5 –10 minutes at a field strength of 3T, to obtaining higher sensitivity for 1H MRSI at 7T and to using ultrafast volumetric and dynamic 13C MRSI for monitoring the changes in signals that occur following the injection of hyperpolarized 13C agents.

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Section: Alternative Encoding Methodsmentioning

confidence: 99%

Section: Acquisition Of Hyperpolarized C-13 Mrsi Datamentioning

confidence: 99%

Strategies for rapid in vivo 1H and hyperpolarized 13C MR spectroscopic imaging

Nelson

Ozhinsky

et al. 2013

Journal of Magnetic Resonance

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“…Therefore, there have been efforts to reduce MRSI scan time using various different approaches (many of which were first developed for fast MRI experiments). Some of the fast MRI techniques that have been adapted for use in MRSI include echo train acquisition [3], echo planar techniques [4], reduced k -space acquisition [5,6] and parallel imaging methods [7,8]. …”

Section: Introductionmentioning

confidence: 99%

Quantitative SENSE-MRSI of the human brain

Bonekamp

Smith

Zhu

et al. 2010

Magnetic Resonance Imaging

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Purpose To develop a method for estimating metabolite concentrations using phased-array coils and sensitivity-encoded (SENSE) magnetic resonance spectroscopic images (MRSI) of the human brain. Materials and Methods The method is based on the phantom replacement technique and uses receive coil sensitivity maps and body-coil loading factors to account for receive B1 inhomogeneity and variable coil loading, respectively. Corrections for cerebrospinal fluid content from the MRSI voxel were also applied, and the total protocol scan time was less than 15 min. The method was applied to 10 normal human volunteers using a multislice 2D-MRSI sequence at 3 T, and seven different brain regions were quantified. Results N-Acetyl aspartate (NAA) concentrations varied from 9.7 to 14.7 mM, creatine (Cr) varied from 6.6 to 10.6 mM and choline (Cho) varied from 1.6 to 3.0 mM, in good general agreement with prior literature values. Conclusions Quantitative SENSE-MRSI of the human brain is routinely possible using an adapted phantom-replacement technique. The method may also be applied to other MRSI techniques, including conventional phase encoding, with phased-array receiver coils, provided that coil sensitivity profiles can be measured.

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“…One of the most successful methods to shorten scan time has been parallel imaging, which utilizes data from multiple receiver coils with varying spatial sensitivities to reduce aliasing artifact when sampling below the Nyquist limit (1–4). Parallel imaging has had a profound impact on all MRI techniques, including cardiac functional imaging (5,6), angiography (7,8), diffusion weighted liver imaging (9), and spectroscopy (10). …”

Section: Introductionmentioning

confidence: 99%

A radial self‐calibrated (RASCAL) generalized autocalibrating partially parallel acquisition (GRAPPA) method using weight interpolation

et al. 2010

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A generalized autocalibrating partially parallel acquisition (GRAPPA) method for radial k-space sampling is presented that calculates GRAPPA weights without synthesized or acquired calibration data. Instead, GRAPPA weights are fit to the undersampled data as if it were the calibration data itself. Because the relative k-space shifts associated with these GRAPPA weights are varying for a radial trajectory, new GRAPPA weights can be resampled for arbitrary shifts through interpolation, which is then used to generate missing projections between the acquired projections. The method is demonstrated in phantoms and in abdominal and brain imaging. Image quality is similar to radial GRAPPA using fully sampled calibration data, and improved compared to a previously described self-calibrated radial GRAPPA technique.

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Spectral phase‐corrected GRAPPA reconstruction of three‐dimensional echo‐planar spectroscopic imaging (3D‐EPSI)

Cited by 33 publications

References 12 publications

Strategies for rapid in vivo 1H and hyperpolarized 13C MR spectroscopic imaging

Strategies for rapid in vivo 1H and hyperpolarized 13C MR spectroscopic imaging

Quantitative SENSE-MRSI of the human brain

A radial self‐calibrated (RASCAL) generalized autocalibrating partially parallel acquisition (GRAPPA) method using weight interpolation

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