Spatial domain method for the design of RF pulses in multicoil parallel excitation

Grissom, William A.; Yip, Chun-Yu; Zhang, Zhenghui; Stenger, V. Andrew; Fessler, Jeffrey A.; Noll, Douglas C.

doi:10.1002/mrm.20978

Cited by 279 publications

(432 citation statements)

References 15 publications

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“…Using small tip‐angle approximation 10, spokes pulses optimization can be represented as a regularized MLS minimization problem through the spatial domain method 15:

b = arg \min_{boldb} {‖ | A b | - {| boldm | ‖}_{2}^{2} + λ {‖ boldb ‖}_{2}^{2}},

where b is a column vector of length N Tx containing the complex RF scaling factors for each of the transmit channels, A is a N vox × N Tx system matrix containing the complex transmit sensitivity from each of the N Tx transmit coils in each of the N vox region of interest voxels with the phase induced from the local B 0 offset and the spokes gradient blips, m is a column vector of length N vox representing the transverse magnetization target set in each of the N vox region of interest voxels, and

λ

is the Tikhonov regularization parameter as a means to regularize the global RF power. This problem can be solved efficiently by the multishift version of conjugate gradients for least‐squares (mCGLS) algorithm 43 together with the local variable exchange method 22.…”

Section: Theorymentioning

confidence: 99%

“…To fully benefit from the improved signal‐to‐noise ratio (SNR) and contrast‐to‐noise ratio at UHF 2, 3, 4, 5, the well‐known problem of radiofrequency (RF) transmit (

{normalB}_{1}^{+}

) inhomogeneity 6 must be overcome first. Solutions that are currently available include novel RF coil design 7, dielectric pads 8, 9, RF pulse design 10, parallel transmission (pTx) with RF shimming 11, 12, 13, 14, and transmit sensitivity encoding (SENSE) 15, 16, 17.…”

Section: Introductionmentioning

confidence: 99%

“…Static RF shim can be considered as the special case of one spoke. The phases and amplitudes required for the sinc subpulses can be found using magnitude least‐squares (MLS) optimization 22, while taking into account the subject‐specific B 0 field distribution and complex channel‐by‐channel

{normalB}_{1}^{+}

sensitivity maps with the formalism of the spatial domain method 15. For multislice acquisitions, slice‐ or slab‐specific spokes pulses have been shown to be beneficial for the overall achievable homogenization in the imaging region 11, 19, 23, 24, 25.…”

Section: Introductionmentioning

confidence: 99%

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High‐resolution gradient‐recalled echo imaging at 9.4T using 16‐channel parallel transmit simultaneous multislice spokes excitations with slice‐by‐slice flip angle homogenization

Tse

Wiggins²,

Poser

2016

Magnetic Resonance in Med

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PurposeIn order to fully benefit from the improved signal‐to‐noise and contrast‐to‐noise ratios at 9.4T, the challenges of normalB1+ inhomogeneity and the long acquisition time of high‐resolution 2D gradient‐recalled echo (GRE) imaging were addressed.Theory and MethodsFlip angle homogenized excitations were achieved by parallel transmission (pTx) of 3‐spoke pulses, designed by magnitude least‐squares optimization in a slice‐by‐slice fashion; the acquisition time reduction was achieved by simultaneous multislice (SMS) pulses. The slice‐specific spokes complex radiofrequency scaling factors were applied to sinc waveforms on a per‐channel basis and combined with the other pulses in an SMS slice group to form the final SMS‐pTX pulse. Optimal spokes locations were derived from simulations.ResultsFlip angle maps from presaturation TurboFLASH showed improvement of flip angle homogenization with 3‐spoke pulses over CP‐mode excitation (normalized root‐mean‐square error [NRMSE] 0.357) as well as comparable excitation homogeneity across the single‐band (NRMSE 0.119), SMS‐2 (NRMSE 0.137), and SMS‐3 (NRMSE 0.132) 3‐spoke pulses. The application of the 3‐spoke SMS‐3 pulses in a 48‐slice GRE protocol, which has an in‐plane resolution of 0.28 × 0.28 mm, resulted in a 50% reduction of scan duration (total acquisition time 6:52 min including reference scans).ConclusionTime‐efficient flip angle homogenized high‐resolution GRE imaging at 9.4T was accomplished by using slice‐specific SMS‐pTx spokes excitations. Magn Reson Med 78:1050–1058, 2017. © 2016 The Authors Magnetic Resonance in Medicine published by Wiley Periodicals, Inc. on behalf of International Society for Magnetic Resonance in Medicine.

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“…Using small tip‐angle approximation 10, spokes pulses optimization can be represented as a regularized MLS minimization problem through the spatial domain method 15:

b = arg \min_{boldb} {‖ | A b | - {| boldm | ‖}_{2}^{2} + λ {‖ boldb ‖}_{2}^{2}},

λ

Section: Theorymentioning

confidence: 99%

“…To fully benefit from the improved signal‐to‐noise ratio (SNR) and contrast‐to‐noise ratio at UHF 2, 3, 4, 5, the well‐known problem of radiofrequency (RF) transmit (

{normalB}_{1}^{+}

Section: Introductionmentioning

confidence: 99%

{normalB}_{1}^{+}

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

High‐resolution gradient‐recalled echo imaging at 9.4T using 16‐channel parallel transmit simultaneous multislice spokes excitations with slice‐by‐slice flip angle homogenization

Tse

Wiggins²,

Poser

2016

Magnetic Resonance in Med

View full text Add to dashboard Cite

show abstract

“…In the small flip angle regime (34), the design of pTx RF pulses corresponds to solving the linear system (8):…”

Section: Theorymentioning

confidence: 99%

“…In radiofrequency (RF) shimming, the interference of the B + 1 fields of the individual channels is optimized for excitation homogeneity (2)(3)(4)(5). Parallel transmit systems using spatially tailored RF pulses facilitate even more control of the local spin excitation within sufficiently short RF pulse durations and over a sufficient spectral range (6)(7)(8)(9). Experimental demonstrations of these techniques have been shown in recent years (10)(11)(12)(13).…”

mentioning

confidence: 99%

Fast design of local N‐gram‐specific absorption rate–optimized radiofrequency pulses for parallel transmit systems

Sbrizzi

Hoogduin

Lagendijk

et al. 2011

Magnetic Resonance in Med

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Designing multidimensional radiofrequency pulses for clinical application must take into account the local specific absorption rate (SAR) as controlling the global SAR does not guarantee suppression of hot spots. The maximum peak SAR, averaged over an N grams cube (local NgSAR), must be kept under certain safety limits. Computing the SAR over a three-dimensional domain can require several minutes and implementing this computation in a radiofrequency pulse design algorithm could slow down prohibitively the numerical process. In this article, a fast optimization algorithm is designed acting on a limited number of control points, which are strategically selected locations from the entire domain. The selection is performed by comparing the largest eigenvalues and the corresponding eigenvectors of the matrices which locally describe the tissue's amount of heating. The computation complexity is dramatically reduced. An additional critical step to accelerate the computations is to apply a multi shift conjugate gradient algorithm. Two transmit array setups are studied: a two channel 3 T birdcage body coil and a 12-channel 7 T transverse electromagnetic (TEM) head coil. In comparison with minimum power radiofrequency pulses, it is shown that a reduction of 36.5% and 35%, respectively, in the local NgSAR can be achieved within short, clinically feasible, computation times. Magn Reson Med 67:824-834, 2012. © 2011 Wiley Periodicals, Inc.Key words: parallel transmission; multidimensional RF pulse design; transmit array; ultra-high-field MRI; local SAR reduction High-field MRI faces problems with respect to B + 1 field inhomogeneity (1). These problems can be addressed by using parallel transmit systems. In radiofrequency (RF) shimming, the interference of the B + 1 fields of the individual channels is optimized for excitation homogeneity (2-5). Parallel transmit systems using spatially tailored RF pulses facilitate even more control of the local spin excitation within sufficiently short RF pulse durations and over a sufficient spectral range (6-9). Experimental demonstrations of these techniques have been shown in recent years (10-13). Their potential goes beyond the compensation for B + 1 inhomogeneity. Other applications include compensation for B 0 distortions (12) and reduced field-of-view imaging by spatially reduced excited region (inner volume excitation) (14,15). A major concern in spatially tailored parallel excitation (pTx) is the heating of the tissue being scanned. Especially for highly accelerated RF pulses, the specific absorption rate (SAR) tends to increase rapidly and can easily exceed the SAR guidelines (16-19). On the other hand, when integrated in the RF pulse design, pTx offers additional degrees of freedom to manipulate the SAR deposition for a given target excitation pattern (7).In vivo, local SAR guidelines are more likely to be exceeded than global SAR when using pTx excitation. Zelinski et al. (16) showed for 7 T head imaging how intricate the local SAR behavior can be for various target patterns an...

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Influence of diffusive processes on the formation of an interfacial layer in carbon plastics based on phenylone

Козлов¹,

Burya²,

Долбин³

et al. 2006

J of Applied Polymer Sci

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ABSTRACT:The influence of the interfacial layer structure on the intensity of diffusive processes during their formation was shown. An increase in the fractal dimension of this layer structure, which was due to macromolecular coils drawing on the smooth surface of the fiber, was determined by a transition from fast diffusion to slow. This factor was controlled by both the thickness of the interfacial layer and its strength.

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Spatial domain method for the design of RF pulses in multicoil parallel excitation

Cited by 279 publications

References 15 publications

High‐resolution gradient‐recalled echo imaging at 9.4T using 16‐channel parallel transmit simultaneous multislice spokes excitations with slice‐by‐slice flip angle homogenization

High‐resolution gradient‐recalled echo imaging at 9.4T using 16‐channel parallel transmit simultaneous multislice spokes excitations with slice‐by‐slice flip angle homogenization

Fast design of local N‐gram‐specific absorption rate–optimized radiofrequency pulses for parallel transmit systems

Influence of diffusive processes on the formation of an interfacial layer in carbon plastics based on phenylone

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