Homogeneous B1+ for bilateral breast imaging at 7 T using a five dipole transmit array merged with a high density receive loop array

Krikken, Erwin; Steensma, Bart R.; Voogt, Ingmar J.; Luijten, Peter R.; Klomp, Dennis W. J.; Raaijmakers, Alexander J. E.; Wijnen, Jannie P.

doi:10.1002/nbm.4039

Cited by 9 publications

(13 citation statements)

References 31 publications

(69 reference statements)

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“…Note, however, that in case the true cause is not the assumed underestimation of ρ, over or under corrections can occur. Both correctable

B_{1}^{+}

ranges are too narrow to reliably correct all data gathered with the current setup used in this study, but recent results suggest that they may be compatible with the degree of homogeneity that can be achieved with a novel bilateral transmit array …”

Section: Discussionmentioning

confidence: 58%

“…The most obvious solution may be to tackle the problem at the source: improve the homogeneity of the

B_{1}^{+}

field. In recent years, progress has been made in the field of RF coil design toward that end . However, a completely homogeneous

B_{1}^{+}

field is nontrivial to achieve even with state‐of‐the‐art hardware, so some amount of field inhomogeneity is always expected.…”

Section: Introductionmentioning

confidence: 99%

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Correcting time‐intensity curves in dynamic contrast‐enhanced breast MRI for inhomogeneous excitation fields at 7T

Rijssel

Pluim

Chan

et al. 2019

Magnetic Resonance in Med

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Purpose: Inhomogeneous excitation at ultrahigh field strengths (7T and above) compromises the reliability of quantified dynamic contrast-enhanced breast MRI. This can hamper the introduction of ultrahigh field MRI into the clinic. Compensation for this non-uniformity effect can consist of both hardware improvements and postacquisition corrections. This paper investigated the correctable radiofrequency transmit (B + 1 ) range post-acquisition in both simulations and patient data for 7T MRI. Methods: Simulations were conducted to determine the minimum B + 1 level at which corrections were still beneficial because of noise amplification. Two correction strategies leading to differences in noise amplification were tested. The effect of the corrections on a 7T patient data set (N = 38) with a wide range of B + 1 levels was investigated in terms of time-intensity curve types as well as washin, washout and peak enhancement values. Results: In simulations assuming a common amount of T 1 saturation, the lowest B + 1 level at which the SNR of the corrected images was at least that of the original precontrast image was 43% of the nominal angle. After correction, time-intensity curve types changed in 24% of included patients, and the distribution of curve types corresponded better to the distribution found in literature. Additionally, the overlap between the distributions of washin, washout, and peak enhancement values for grade 1 and grade 2 tumors was slightly reduced. Conclusion: Although the correctable range varies with the amount of T 1 saturation, post-acquisition correction for inhomogeneous excitation was feasible down to B + 1 levels of 43% of the nominal angle in vivo. K E Y W O R D S 7T, B + 1 mapping, breast, DCE-MRI, flip-angle correction, RF field inhomogeneity | 1001 van RIJSSEL Et aL.

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“…Note, however, that in case the true cause is not the assumed underestimation of ρ, over or under corrections can occur. Both correctable

B_{1}^{+}

Section: Discussionmentioning

confidence: 58%

“…The most obvious solution may be to tackle the problem at the source: improve the homogeneity of the

B_{1}^{+}

field. In recent years, progress has been made in the field of RF coil design toward that end . However, a completely homogeneous

B_{1}^{+}

field is nontrivial to achieve even with state‐of‐the‐art hardware, so some amount of field inhomogeneity is always expected.…”

Section: Introductionmentioning

confidence: 99%

Correcting time‐intensity curves in dynamic contrast‐enhanced breast MRI for inhomogeneous excitation fields at 7T

Rijssel

Pluim

Chan

et al. 2019

Magnetic Resonance in Med

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“…The B + 1 inhomogeneity was measured (with the detuned array in place) by taking the SD and dividing by the mean of the same region throughout the phantoms on both sides of the bilateral coil. 15,18 SNR comparisons between the array and the volume coil were performed on an axial slice through the center of the phantoms by taking the average and maximum signal values throughout both phantoms and dividing by the SD of the noise in the noise-only image then scaling by a factor of 0.655. 32 SNR maps were generated for each image by dividing the signal intensity by the SD of a selected region in the noise-only image on a pixel-by-pixel basis.…”

Section: Discussionmentioning

confidence: 99%

“…[7][8][9][10] Several studies have reported the benefits of high-field (7T) imaging in DCE and DWI studies, [11][12][13][14] where the use of array coils is particularly beneficial to increase the achievable temporal resolution. [15][16][17][18] The challenges of high-field imaging with respect to homogeneous RF excitation and specific absorption rate are well-documented. 19,20 Our group has previously reported on the forced current excitation (FCE) technique as a way to transmit effectively at 7T, achieving homogeneous excitation in the presence of the asymmetric load presented by the patient in a prone position, while remaining within specific absorption rate regulations.…”

Section: Introductionmentioning

confidence: 99%

A 32‐channel receive array coil for bilateral breast imaging and spectroscopy at 7T

Bosque

Cui

Ogier

et al. 2020

Magnetic Resonance in Med

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This work describes the construction and evaluation of a bilateral 32-channel receive array for breast imaging at 7T. Methods: The receive array consisted of 32 receive coils, placed on two 3D-printed hemispherical formers. Each side of the receive array consisted of 16 receive loops, each loop having a corresponding detachable board with match/tune capacitors, active detuning circuitry, and a balun. Coil performance was evaluated on homogeneous canola oil phantoms using a Philips Achieva 7T system. Array coil performance was compared with a bilateral forced current excitation volume coil in transmit/ receive mode and with a previously reported 16-channel unilateral coil with a similar design. Results: The 32-channel array had an increase in average SNR throughout both phantoms by a factor of five as compared with the volume coil, with SNR increases up to 10 times along the periphery and three times in the center. Noise measurements showed low interelement noise correlation (average: 5.4%; maximum: 16.8%). Geometry factor maps were acquired for various acceleration factors and showed mean geometry factors <1.2, for combined acceleration factors of up to six. Conclusions: The improvements achieved demonstrate the clear potential for use in dynamic contrast-enhanced or diffusion-weighted MR studies, while maintaining diagnostically relevant spatial and temporal resolutions.

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“…Using eight independent RF power amplifiers (RFPAs) in pTX mode allows driving the individual 8Tx channels of the array dynamically (i.e. to vary the magnitude/phase of each channel or the RF-pulse waveforms), which enables shaping of 2D and 3D excitation profiles based on a wide-range of optimization criteria 51,52 . Another major issue is that the limited RF power given from the RFPA is distributed to both array parts.…”

mentioning

confidence: 99%

A Novel Mono-surface Antisymmetric 8Tx/16Rx Coil Array for Parallel Transmit Cardiac MRI in Pigs at 7T

Elabyad¹,

Terekhov²,

Lohr³

et al. 2020

Sci Rep

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A novel mono-surface antisymmetric 16-element transmit/receive (Tx/Rx) coil array was designed, simulated, constructed, and tested for cardiac magnetic resonance imaging (cMRI) in pigs at 7 T. The cardiac array comprised of a mono-surface 16-loops with two central elements arranged antisymmetrically and flanked by seven elements on either side. The array was configured for parallel transmit (pTx) mode to have an eight channel transmit and 16-channel receive (8Tx/16Rx) coil array. Electromagnetic (EM) simulations, bench-top measurements, phantom, and MRI experiments with two pig cadavers (68 and 46 kg) were performed. Finally, the coil was used in pilot in-vivo measurements with a 60 kg pig. Flip angle (FA), geometry factor (g-factor), signal-to-noise ratio (SNR) maps, and highresolution cardiac images were acquired with an in-plane resolution of 0.6 mm × 0.6 mm (in-vivo) and 0.3 mm × 0.3 mm (ex-vivo). The mean g-factor over the heart was 1.26 (R = 6). Static phase B 1 + shimming in a pig body phantom with the optimal phase vectors makes possible to improve the B 1 + homogeneity by factor > 2 and transmit efficiency by factor > 3 compared to zero phases (before RF shimming). Parallel imaging performed in the in-vivo measurements demonstrated well preserved diagnostic quality of the resulting images at acceleration factors up to R = 6. The described hardware design can be adapted for arrays optimized for animals and humans with a larger number of elements (32-64) while maintaining good decoupling for various MRI applications at UHF (e.g., cardiac, head, and spine).

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Homogeneous B₁⁺ for bilateral breast imaging at 7 T using a five dipole transmit array merged with a high density receive loop array

Cited by 9 publications

References 31 publications

Correcting time‐intensity curves in dynamic contrast‐enhanced breast MRI for inhomogeneous excitation fields at 7T

Correcting time‐intensity curves in dynamic contrast‐enhanced breast MRI for inhomogeneous excitation fields at 7T

A 32‐channel receive array coil for bilateral breast imaging and spectroscopy at 7T

A Novel Mono-surface Antisymmetric 8Tx/16Rx Coil Array for Parallel Transmit Cardiac MRI in Pigs at 7T

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