Specific absorption rate reduction using nonlinear gradient fields

Kopanoğlu, Emre; Yılmaz, Uğur; Gokhalk, Yildiray; Atalar, Ergin

doi:10.1002/mrm.24478

Cited by 8 publications

(15 citation statements)

References 26 publications

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“…More recently, scan time has been reduced by spatial encoding with nonlinear magnetic fields, such as in Pat-Loc imaging (14), O-space imaging (15,16), null space imaging (17), four-dimensional radial in/out(4D-RIO) (18), echo planar imaging (EPI)-PatLoc (19)(20)(21), and others (22)(23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33)(34)(35)(36). Here we focus on O-space imaging, which encodes spatial information through a radially varying magnetic gradient field B i ¼ z 2 -1/2((x -x i ) 2 þ (y À y i ) 2 ) centered at different center placements (x i , y i ), which form a ring about the center of the field of view (15).…”

Section: Introductionmentioning

confidence: 99%

Experimental O‐space turbo spin echo imaging

Wang

Tam

Kopanoğlu

et al. 2015

Magnetic Resonance in Med

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Purpose Turbo Spin Echo (TSE) imaging reduces imaging time by acquiring multiple echoes per repetition (TR), requiring fewer TRs. O-Space also can require fewer TRs by using a combination of nonlinear magnetic gradient fields and surface coil arrays. Although to date, O-Space has only been demonstrated for gradient echo imaging, it’s valuable to combine these two techniques. However, collecting multiple O-Space echoes per TR is difficult because of the different local k-space trajectories and variable T2-weighting. Theory and Methods A practical scheme is demonstrated to combine the benefits of TSE and O-Space for highly accelerated T2-weighted images. The scheme uses a modified acquisition order and filtered projection reconstruction to reduce artifacts caused by T2-decay, while retaining T2 contrast that corresponds to a specific echo time. Results The experiments illustrate the proposed method can produce highly accelerated T2-weighted images. Moreover, the proposed method can generate multiple images with different T2 contrasts from a single dataset. Conclusions The proposed O-Space TSE imaging method requires fewer echoes than conventional TSE and fewer repetitions than conventional O-Space imaging. It retains resilience to undersampling, clearly outperforming Cartesian SENSE at high levels of undersampling, and can generate undistorted images with a range of T2 contrast from a single acquired dataset.

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Section: Introductionmentioning

confidence: 99%

Experimental O‐space turbo spin echo imaging

Wang

Tam

Kopanoğlu

et al. 2015

Magnetic Resonance in Med

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“…Kopanoglu et al have also introduced the excitation k ‐space variables for N‐SEMs . These authors used a coordinate transformation from linear spatial variables to nonlinear spatial variables by assuming that encoding fields are bijective, which is generally not the case for higher order spherical harmonics.…”

Section: Discussionmentioning

confidence: 99%

“…Some studies that include the phase accumulation due to N‐SEM channels in the RF pulse design problem already exist . Some other studies explicitly define the excitation k ‐space variables for N‐SEMs, which satisfies the Fourier transform relationship between the excitation k ‐space and transverse magnetization distribution under special conditions . In our study, the independent excitation k ‐space dimension for each N‐SEM is defined when they are simultaneously used with L‐SEMs.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous use of linear and nonlinear gradients for B₁⁺ inhomogeneity correction

Ertan

Atalar

2017

NMR in Biomedicine

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The simultaneous use of linear spatial encoding magnetic fields (L-SEMs) and nonlinear spatial encoding magnetic fields (N-SEMs) in B inhomogeneity problems is formulated and demonstrated with both simulations and experiments. Independent excitation k-space variables for N-SEMs are formulated for the simultaneous use of L-SEMs and N-SEMs by assuming a small tip angle. The formulation shows that, when N-SEMs are considered as an independent excitation k-space variable, numerous different k-space trajectories and frequency weightings differing in dimension, length, and energy can be designed for a given target transverse magnetization distribution. The advantage of simultaneous use of L-SEMs and N-SEMs is demonstrated by B inhomogeneity correction with spoke excitation. To fully utilize the independent k-space formulations, global optimizations are performed for 1D, 2D RF power limited, and 2D RF power unlimited simulations and experiments. Three different cases are compared: L-SEMs alone, N-SEMs alone, and both used simultaneously. In all cases, the simultaneous use of L-SEMs and N-SEMs leads to a decreased standard deviation in the ROI compared with using only L-SEMs or N-SEMs. The simultaneous use of L-SEMs and N-SEMs results in better B inhomogeneity correction than using only L-SEMs or N-SEMs due to the increased number of degrees of freedom.

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“…pTx methods (13,(21)(22)(23)(24)(25) provide more degrees of freedom for RF pulse design because they enable different RF waveforms being transmitted through each independent transmit coil element. Nonlinear spatial encoding magnetic fields (SEMs) have been used for selective magnetization excitation to reduce RF pulse length if the target excitation profile is a function of a linear combination of SEMs (26)(27)(28)(29)(30)(31). Driving linear and quadratic SEMs between two excitation pulses can generate a spatially dependent transverse magnetization phase distribution that counteracts B þ 1 inhomogeneities to achieve a homogeneous flip angle distribution (32).…”

Section: Introductionmentioning

confidence: 99%

Mitigation of B1+ inhomogeneity using spatially selective excitation with jointly designed quadratic spatial encoding magnetic fields and RF shimming

et al. 2016

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Purpose The inhomogeneity of flip angle distribution is one major challenge impeding the application of high field magnetic resonance imaging (MRI). Here we report a method combining SpAtially selective excitation using Generalized SEMs (SAGS) with RF shimming to achieve homogeneous excitation. This method can be an alternative approach to address the challenge of B1+ inhomogeneity using nonlinear gradients. Method We proposed a two-step algorithm, which first jointly optimizes the combination of nonlinear spatial encoding magnetic fields (SEMs) and the combination of multiple RF transmitter coils, and then optimizes the locations, RF amplitudes, and phases of the spokes. Results Our results show that jointly-designed SAGS and RF shimming can provide a more homogeneous flip angle distribution than using SAGS or RF shimming alone. Compared to RF shimming alone, our approach can reduce the relative standard deviation of flip angle by 56% and 52% using phantom and human head data, respectively. Conclusion The jointly-designed SAGS and RF shimming method can be used to achieve homogeneous flip angle distributions when fully parallel RF transmission is not available.

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Specific absorption rate reduction using nonlinear gradient fields

Cited by 8 publications

References 26 publications

Experimental O‐space turbo spin echo imaging

Experimental O‐space turbo spin echo imaging

Simultaneous use of linear and nonlinear gradients for B₁⁺ inhomogeneity correction

Mitigation of B1+ inhomogeneity using spatially selective excitation with jointly designed quadratic spatial encoding magnetic fields and RF shimming

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Specific absorption rate reduction using nonlinear gradient fields

Cited by 8 publications

References 26 publications

Experimental O‐space turbo spin echo imaging

Experimental O‐space turbo spin echo imaging

Simultaneous use of linear and nonlinear gradients for B1+ inhomogeneity correction

Mitigation of B1+ inhomogeneity using spatially selective excitation with jointly designed quadratic spatial encoding magnetic fields and RF shimming

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Simultaneous use of linear and nonlinear gradients for B₁⁺ inhomogeneity correction