Design and evaluation of a 32‐channel phased‐array coil for lung imaging with hyperpolarized 3‐helium

Meise, F. M.; Rivoire, Julien; Terekhov, Maxim; Wiggins, Graham C.; Keil, Boris; Karpuk, S.; Salhi, Zahir; Wald, Lawrence L.; Schreiber, Laura M.

doi:10.1002/mrm.22265

Cited by 16 publications

(18 citation statements)

References 34 publications

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“…For a given volunteer, no significant SNR difference is observed between scans with different acceleration factors along the R/L direction. This is consistent with previous findings (5,9) and highlights the fact that the SNR loss incurred due to a reduced total number of acquisitions can be compensated by an increased flip angle. The mean SNR for R ¼ 4 in the S/I direction (Fig.…”

Section: Parallel Imagingsupporting

confidence: 93%

“…In the R ¼ 4 (R/L) scan of the male volunteer, the maximum observed g-factor over all slices was g max ¼ 2.07. These g-factors are comparable with, and in some cases slightly less than those obtained with a coil design for the same application which relies on a pairwise decoupling scheme (9). While the pair-wise approach of the earlier design results in a maximum correlation of 43%, compared with 71% for the shielding decoupling scheme used here, the parallel imaging performance of the present coil does not appear to be compromised, as the mean correlation remains low.…”

Section: Parallel Imagingsupporting

confidence: 59%

“…This effect needs to be considered when performing dynamic inhalation studies using parallel imaging techniques (9). In that case, the lung will be imaged in all states of inflation and the g-factor distribution does not remain constant during the course of the experiment, which can present a confounding factor, particularly when performing a quantitative analysis of pixel intensities, e.g., to detect phenomena such as gas trapping.…”

Section: Parallel Imagingmentioning

confidence: 99%

“…This is because signal can be increased at lower N by increasing the flip angle (5,8). Initial results presented with 24, 32, and 128 channel arrays were promising, demonstrating parallel imaging of hyperpolarized gas with high SNR (5,(9)(10)(11).…”

Section: Introductionmentioning

confidence: 99%

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A flexible 32‐channel receive array combined with a homogeneous transmit coil for human lung imaging with hyperpolarized ³He at 1.5 T

Deppe¹,

Parra‐Robles²,

Marshall³

et al. 2011

Magnetic Resonance in Med

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Parallel imaging presents a promising approach for MRI of hyperpolarized nuclei, as the penalty in signal-to-noise ratio typically encountered with 1 H MRI due to a reduction in acquisition time can be offset by an increase in flip angle. The signal-to-noise ratio of hyperpolarized MRI generally exhibits a strong dependence on flip angle, which makes a homogeneous B 1 1 transmit field desirable. This paper presents a flexible 32-channel receive array for 3 He human lung imaging at 1.5T designed for insertion into an asymmetric birdcage transmit coil. While the 32-channel array allows parallel imaging at high acceleration factors, the birdcage transmit coil provides a homogeneous B 1 1 field. Decoupling between array elements is achieved by using a concentric shielding approach together with preamplifier decoupling. Coupling between transmit coil and array elements is low by virtue of a low geometric coupling coefficient, which is reduced further by the concentric shields in the array. The combination of the 32-channel array and birdcage transmit coil provides 3 He ventilation images of excellent quality with similar signal-to-noise ratio at acceleration factors R 5 2 and R 5 4, while maintaining a homogeneous B 11 .

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Section: Parallel Imagingsupporting

confidence: 93%

Section: Parallel Imagingsupporting

confidence: 59%

Section: Parallel Imagingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A flexible 32‐channel receive array combined with a homogeneous transmit coil for human lung imaging with hyperpolarized ³He at 1.5 T

Deppe¹,

Parra‐Robles²,

Marshall³

et al. 2011

Magnetic Resonance in Med

View full text Add to dashboard Cite

show abstract

“…(ii) A dedicated 32-receive channel phased array for 3 He imaging with Helmholz-type transmitting loops (24). Here, the transmit coils consist of two loops with the dimensions of 34 Â 37 cm 2 .…”

Section: Methodsmentioning

confidence: 99%

Flip‐angle measurement by magnetization inversion: Calibration of magnetization nutation angle in hyperpolarized ³He magnetic resonance imaging lung experiments

Rivoire

Terekhov

Meise

et al. 2010

Magnetic Resonance in Med

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The aim of this work was to establish a new, fast, and robust method of flip-angle calibration for magnetic resonance imaging of hyperpolarized 3 He. The method called flip-angle measurement with magnetization inversion is based on acquiring images from periodically inverted longitudinal magnetization created using the spatial modulation of magnetization technique. By measuring the width of the area where the magnetization was inverted by the spatial modulation of magnetization preparation in phase images, the flip angle can be generated using a simple equation. To validate and establish the limits of the proposed method, flip-angle measurement with magnetization inversion acquisitions were simulated and applied to proton and hyperpolarized 3 He phantoms. Then, the calibration procedure was applied during hyperpolarized 3 He magnetic resonance imaging in a healthy volunteer. The advantage of the flip-angle measurement with magnetization inversion method compared with the conventional method based on the assessment of radiofrequency-decay is that it is free of errors induced by relaxation due to oxygen, by imperfect excitation slice profile and by any diffusion of 3 He into and out of the slice. Another advantage is that it does not require image processing with external software and therefore can be performed using the implemented tools on the magnetic resonance workstation. Magn Reson Med 65:399-408,

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Hyperpolarized ¹²⁹Xe MRI of the human lung

Mugler

Altes

2013

Magnetic Resonance Imaging

308

445

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By permitting direct visualization of the airspaces of the lung, MR imaging using hyperpolarized gases provides unique strategies for evaluating pulmonary structure and function. Although the vast majority of research in humans has been performed using hyperpolarized 3He, recent contraction in the supply of 3He and consequent increases in price have turned attention to the alternative agent, hyperpolarized 129Xe. Compared to 3He, 129Xe yields reduced signal due to its smaller magnetic moment. Nonetheless, taking advantage of advances in gas-polarization technology, recent studies in humans using techniques for measuring ventilation, diffusion, and partial pressure of oxygen have demonstrated results for hyperpolarized 129Xe comparable to those previously demonstrated using hyperpolarized 3He. In addition, xenon has the advantage of readily dissolving in lung tissue and blood following inhalation, which makes hyperpolarized 129Xe particularly attractive for exploring certain characteristics of lung function, such as gas exchange and uptake, which cannot be accessed using 3He. Preliminary results from methods for imaging 129Xe dissolved in the human lung suggest that these approaches will provide new opportunities for quantifying relationships among gas delivery, exchange, and transport, and thus show substantial potential to broaden our understanding of lung disease. Finally, recent changes in the commercial landscape of the hyperpolarized-gas field now make it possible for this innovative technology to move beyond the research lab.

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Design and evaluation of a 32‐channel phased‐array coil for lung imaging with hyperpolarized 3‐helium

Cited by 16 publications

References 34 publications

A flexible 32‐channel receive array combined with a homogeneous transmit coil for human lung imaging with hyperpolarized ³He at 1.5 T

A flexible 32‐channel receive array combined with a homogeneous transmit coil for human lung imaging with hyperpolarized ³He at 1.5 T

Flip‐angle measurement by magnetization inversion: Calibration of magnetization nutation angle in hyperpolarized ³He magnetic resonance imaging lung experiments

Hyperpolarized ¹²⁹Xe MRI of the human lung

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Design and evaluation of a 32‐channel phased‐array coil for lung imaging with hyperpolarized 3‐helium

Cited by 16 publications

References 34 publications

A flexible 32‐channel receive array combined with a homogeneous transmit coil for human lung imaging with hyperpolarized 3He at 1.5 T

A flexible 32‐channel receive array combined with a homogeneous transmit coil for human lung imaging with hyperpolarized 3He at 1.5 T

Flip‐angle measurement by magnetization inversion: Calibration of magnetization nutation angle in hyperpolarized 3He magnetic resonance imaging lung experiments

Hyperpolarized 129Xe MRI of the human lung

Contact Info

Product

Resources

About

A flexible 32‐channel receive array combined with a homogeneous transmit coil for human lung imaging with hyperpolarized ³He at 1.5 T

A flexible 32‐channel receive array combined with a homogeneous transmit coil for human lung imaging with hyperpolarized ³He at 1.5 T

Flip‐angle measurement by magnetization inversion: Calibration of magnetization nutation angle in hyperpolarized ³He magnetic resonance imaging lung experiments

Hyperpolarized ¹²⁹Xe MRI of the human lung