128‐channel body MRI with a flexible high‐density receiver‐coil array

Hardy, Christopher J.; Giaquinto, Randy O.; Piel, Joseph E.; Rohling, Kenneth W.; Marinelli, Luca; Blezek, Daniel J.; Fiveland, Eric; Darrow, Robert D.; Foo, Thomas K.F.

doi:10.1002/jmri.21463

Cited by 110 publications

(99 citation statements)

References 16 publications

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“…Dedicated nuclear magnetic resonance (NMR) phased-array coils are required to use these imaging techniques. The recent development of MR systems with up to 128 independent receiver channels (8,9) allows for introducing phased-array coils with a likewise large number of coil elements (10)(11)(12). This way, further reductions in imaging time as well as better signal-to-noise ratios (SNRs) for standard accelerations of up to a factor of four were achieved (13,14).…”

Section: Introductionmentioning

confidence: 99%

Three‐dimensional quadrature array coil elements for improved parallel magnetic resonance imaging performance at 1.5 Tesla

Mueller¹,

Lanz²,

Breuer³

et al. 2011

Concepts Magnetic Resonance

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ABSTRACT:In this study, a special concept of 3D quadrature array coil elements is presented. It allows for doubling the number of phased-array coil elements over a localized region of interest (ROI) without the necessity of reducing the sizes of the elements below optimal dimensions and thus losing performance due to domination of the noise of the elements. In this study, a 3D quadrature array coil element is formed of a planar coil element in combination with a perpendicular orientated, geometrically decoupled, second coil element. Simulation results of such a perpendicular arrangement of single coil elements are presented demonstrating the improvement in spatial sensitivity distribution and signal-to-noise ratio (SNR) over the localized ROI. In addition, an eightchannel prototype array coil was built out of 3D quadrature array elements approving the advantageous encoding capabilities and SNR performance of the presented concept by in vivo T 2 -weighted spin-echo imaging studies on the thoracic human spinal cord.

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Section: Introductionmentioning

confidence: 99%

Three‐dimensional quadrature array coil elements for improved parallel magnetic resonance imaging performance at 1.5 Tesla

Mueller¹,

Lanz²,

Breuer³

et al. 2011

Concepts Magnetic Resonance

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show abstract

“…Unfortunately, the generation of high spatial frequencies is limited also for phase-dominated RF encoding due to the smooth shape of typical phase transmit profiles. Here, a trend toward higher channel numbers as observed for parallel imaging (see, e.g., (22,23)), probably connected with modified amplifier concepts, might play a role. A separate study shall clarify if an increased transmit channel count is able to generate higher frequencies in phase-transmit profiles.…”

Section: Discussionmentioning

confidence: 61%

RF encoding using a multielement parallel transmit system

Katscher

Lisinski

Börnert

2010

Magnetic Resonance in Med

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Radiofrequency (RF) encoding using spatially variant RF transmission fields represents an alternative to the conventional signal-encoding techniques applied in MRI, which are based on main field gradients. Thus, RF encoding might allow omitting the use of all main field gradients, alleviating acoustic noise and other main field gradient-related problems. This study investigates the potential of RF transmit encoding using spatially nonlinear RF fields generated by an eight-channel parallel transmit system equipped with the corresponding transmit array. Appropriate spatial encoding functions are determined iteratively by randomized superposition of the array element sensitivities and judging their performance. Besides RF amplitude-based signal encoding, the possibility of RF phase-dominated encoding is investigated to allow future fast imaging applications. The theoretical background is given and experimental phantom results are compared with predictions from corresponding simulations to prove the basic feasibility of the approach for low-resolution MRI. Deviations of roughly 10-15% between main field and RF encoded images were found for an in-plane resolution of 5 3 5 mm 2 . The approach of RF encode MRI does not seem to be able to replace standard main field gradient encoding completely, but a suitable combination of both concepts could find promising applications.

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“…Using a large number of RF coils can increase the SNR and significantly accelerate the imaging process [69][70][71][72]. However, placing a large number of coils in a constrained space will decrease the coil size, leading to a shallower B 1 penetration.…”

Section: Coil Geometrymentioning

confidence: 99%

In vivo sensitivity estimation and imaging acceleration with rotating RF coil arrays at 7 Tesla

Jin

Zuo

et al. 2015

Journal of Magnetic Resonance

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Using a new rotating SENSitivity Encoding (rotating-SENSE) algorithm, we have successfully demonstrated that the rotating radiofrequency coil array (RRFCA) is capable of achieving a significant reduction in scan time and a uniform image reconstruction for a homogeneous phantom at 7 Tesla. However, at 7 Tesla the in vivo with the same number of coil elements, the RRFCA was able to reconstruct good quality images at a high reduction factor. It is hoped that the proposed sensitivity estimation algorithm and the acceleration ability of the RRFCA will be particularly useful for ultra high field MRI.

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128‐channel body MRI with a flexible high‐density receiver‐coil array

Cited by 110 publications

References 16 publications

Three‐dimensional quadrature array coil elements for improved parallel magnetic resonance imaging performance at 1.5 Tesla

Three‐dimensional quadrature array coil elements for improved parallel magnetic resonance imaging performance at 1.5 Tesla

RF encoding using a multielement parallel transmit system

In vivo sensitivity estimation and imaging acceleration with rotating RF coil arrays at 7 Tesla

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