Whole‐liver flip‐angle shimming at 7 T using parallel‐transmit k_T‐point pulses and Fourier phase‐encoded DREAMB1+ mapping

Abstract: PurposeTo obtain homogeneous signal throughout the human liver at 7 T. Flip angle (FA) shimming in 7T whole‐liver imaging was performed through parallel‐transmit kT‐point pulses based on subject‐specific multichannel absolute maps from Fourier phase‐encoded dual refocusing echo acquisition mode (PE‐DREAM).MethodsThe optimal number of Fourier phase‐encoding steps for PE‐DREAM mapping was determined for a 7T eight‐channel parallel‐transmission system. FA shimming experiments were performed in the liver of 7 he… Show more

“…Furthermore, multiple sources of motion, including respiration, cardiac activity, and blood flow, exacerbate the technical challenges encountered in UHF MRI when targeting areas within the human body, such as the heart or liver. [9][10][11][12][13][14] A range of innovative solutions has been proposed to address these challenges, encompassing the integration of multi-transmit RF coils and parallel transmission (pTx) techniques [15][16][17][18][19][20][21] using volunteer-specific B + 1 information alongside motion-robust non-Cartesian acquisition schemes and advanced reconstruction approaches. 11,22,23 Dynamic pTx employs, in contrast to static pTx, temporally changing RF and gradient waveforms.…”

“…Although various approaches have been developed to address the inhomogeneous transmit field, 2,6–8 the application of UHF MRI to the human body, which is usually larger in size than the human brain, requires specialized methodologies to tackle this issue effectively. Furthermore, multiple sources of motion, including respiration, cardiac activity, and blood flow, exacerbate the technical challenges encountered in UHF MRI when targeting areas within the human body, such as the heart or liver 9–14 …”

Tailored and universal parallel transmit broadband pulses for homogeneous 3D excitation of the human heart at 7T

“…Furthermore, multiple sources of motion, including respiration, cardiac activity, and blood flow, exacerbate the technical challenges encountered in UHF MRI when targeting areas within the human body, such as the heart or liver. [9][10][11][12][13][14] A range of innovative solutions has been proposed to address these challenges, encompassing the integration of multi-transmit RF coils and parallel transmission (pTx) techniques [15][16][17][18][19][20][21] using volunteer-specific B + 1 information alongside motion-robust non-Cartesian acquisition schemes and advanced reconstruction approaches. 11,22,23 Dynamic pTx employs, in contrast to static pTx, temporally changing RF and gradient waveforms.…”

“…Although various approaches have been developed to address the inhomogeneous transmit field, 2,6–8 the application of UHF MRI to the human body, which is usually larger in size than the human brain, requires specialized methodologies to tackle this issue effectively. Furthermore, multiple sources of motion, including respiration, cardiac activity, and blood flow, exacerbate the technical challenges encountered in UHF MRI when targeting areas within the human body, such as the heart or liver 9–14 …”

Tailored and universal parallel transmit broadband pulses for homogeneous 3D excitation of the human heart at 7T