Flexible and efficient optimization of quantitative sequences using automatic differentiation of Bloch simulations

Lee, Philip K.; Watkins, Lauren; Anderson, T. W.; Buonincontri, Guido; Hargreaves, Brian A.

doi:10.1002/mrm.27832

Cited by 31 publications

(60 citation statements)

References 48 publications

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“…While here we have used a sequence with a simplified flip angle schedule, various different strategies to optimize the acquisition are possible. For instance, it is possible to optimize the Cramér-Rao Lower Bound of quantitative sequences 9 , 13 , 14 , recently demonstrated also in combination with automatic differentiation algorithms, hence without approximations or an analytical formulation 9 . It is also possible to use Bayesian design theory to define a set of optimal acquisition parameters for a particular range of tissues of interest, maximizing both parameter encoding and experimental efficiency 4 .…”

Section: Discussionmentioning

confidence: 99%

“…The local quantification accuracy depends both on the used flip angle schedule and the k -space sampling trajectory, as time-dependent point spread functions (PSF) will interfere differently in different spatiotemporal coordinates 7 . So far, the most successful implementations of transient-state imaging have relied on trajectories that oversample the k -space center, such as radial or spiral acquisitions, in combination with locally-smooth schedules of flip angle and repetition times 8 , 9 . Despite their initial success in high-resolution parameter mapping, current quantitative techniques still suffer from limitations in acquisition, reconstruction, and parameter inference efficiency.…”

Section: Introductionmentioning

confidence: 99%

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Rapid three-dimensional multiparametric MRI with quantitative transient-state imaging

Gómez

Cencini

Golbabaee

et al. 2020

Sci Rep

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Novel methods for quantitative, transient-state multiparametric imaging are increasingly being demonstrated for assessment of disease and treatment efficacy. Here, we build on these by assessing the most common Non-Cartesian readout trajectories (2D/3D radials and spirals), demonstrating efficient anti-aliasing with a k- space view-sharing technique, and proposing novel methods for parameter inference with neural networks that incorporate the estimation of proton density. Our results show good agreement with gold standard and phantom references for all readout trajectories at 1.5 T and 3 T. Parameters inferred with the neural network were within 6.58% difference from the parameters inferred with a high-resolution dictionary. Concordance correlation coefficients were above 0.92 and the normalized root mean squared error ranged between 4.2 and 12.7% with respect to gold-standard phantom references for T1 and T2. In vivo acquisitions demonstrate sub-millimetric isotropic resolution in under five minutes with reconstruction and inference times < 7 min. Our 3D quantitative transient-state imaging approach could enable high-resolution multiparametric tissue quantification within clinically acceptable acquisition and reconstruction times.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Rapid three-dimensional multiparametric MRI with quantitative transient-state imaging

Gómez

Cencini

Golbabaee

et al. 2020

Sci Rep

Self Cite

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“…Generally, while T 1 is encoded throughout the schedule after the inversion pulse, T 2 is encoded only by echoes recalled by high FAs; hence, it is harder to estimate and is more susceptible to motion artifacts. Future work including automatic optimization of the schedule might improve also on the motion‐robustness of the technique 43 …”

Section: Discussionmentioning

confidence: 99%

“…Future work including automatic optimization of the schedule might improve also on the motion-robustness of the technique. 43 Here, we used a gradient-spoiled approach, where subsequent gradients applied in the presence of motion could result in inconsistent dephasing. Therefore, simply co-registering different subsets fails to capture some distortions in the spin-dynamics, in particular when motion occurs in the direction of the spoiling gradient.…”

Section: Discussionmentioning

confidence: 99%

Retrospective rigid motion correction of three‐dimensional magnetic resonance fingerprinting of the human brain

Kurzawski

Cencini

Peretti

et al. 2020

Magnetic Resonance in Med

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Purpose To obtain three‐dimensional (3D), quantitative and motion‐robust imaging with magnetic resonance fingerprinting (MRF). Methods Our acquisition is based on a 3D spiral projection k‐space scheme. We compared different orderings of trajectory interleaves in terms of rigid motion‐correction robustness. In all tested orderings, we considered the whole dataset as a sum of 56 segments of 7‐s duration, acquired sequentially with the same flip angle schedule. We performed a separate image reconstruction for each segment, producing whole‐brain navigators that were aligned to the first segment using normalized correlation. The estimated rigid motion was used to correct the k‐space data, and the aligned data were matched with the dictionary to obtain motion‐corrected maps. Results A significant improvement on the motion‐affected maps after motion correction is evident with the suppression of motion artifacts. Correlation with the motionless baseline improved by 20% on average for both T1 and T2 estimations after motion correction. In addition, the average motion‐induced quantification bias of 70 ms for T1 and 18 ms for T2 values was reduced to 12 ms and 6 ms, respectively, improving the reliability of quantitative estimations. Conclusion We established a method that allows correcting 3D rigid motion on a 7‐s timescale during the reconstruction of MRF data using self‐navigators, improving the image quality and the quantification robustness.

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“…Novel MRF reconstruction methods including deep learning can be used for accelerating the reconstruction and obtain more stable matching progress . Optimizing the pulse sequence by a better choice of the flip angle, TE, and TR may further decrease the noise as published recently …”

Section: Discussionmentioning

confidence: 99%

Magnetic resonance fingerprinting for simultaneous renal T₁ and T₂^* mapping in a single breath‐hold

Hermann

Chacon‐Caldera

Brumer

et al. 2020

Magnetic Resonance in Med

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Purpose To evaluate the use of magnetic resonance fingerprinting (MRF) for simultaneous quantification of T1 and T2∗ in a single breath‐hold in the kidneys. Methods The proposed kidney MRF sequence was based on MRF echo‐planar imaging. Thirty‐five measurements per slice and overall 4 slices were measured in 15.4 seconds. Group matching was performed for in‐line quantification of T1 and T2∗. Images were acquired in a phantom and 8 healthy volunteers in coronal orientation. To evaluate our approach, region of interests were drawn in the kidneys to calculate mean values and standard deviations of the T1 and T2∗ times. Precision was calculated across multiple repeated MRF scans. Gaussian filtering is applied on baseline images to improve SNR and match stability. Results T1 and T2∗ times acquired with MRF in the phantom showed good agreement with reference measurements and conventional mapping methods with deviations of less than 5% for T1 and less than 10% for T2∗. Baseline images in vivo were free of artifacts and relaxation times yielded good agreement with conventional methods and literature (deviation T1:7±4%, T2∗:6±3%). Conclusions In this feasibility study, the proposed renal MRF sequence resulted in accurate T1 and T2∗ quantification in a single breath‐hold.

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Flexible and efficient optimization of quantitative sequences using automatic differentiation of Bloch simulations

Cited by 31 publications

References 48 publications

Rapid three-dimensional multiparametric MRI with quantitative transient-state imaging

Rapid three-dimensional multiparametric MRI with quantitative transient-state imaging

Retrospective rigid motion correction of three‐dimensional magnetic resonance fingerprinting of the human brain

Magnetic resonance fingerprinting for simultaneous renal T₁ and T₂^* mapping in a single breath‐hold

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Flexible and efficient optimization of quantitative sequences using automatic differentiation of Bloch simulations

Cited by 31 publications

References 48 publications

Rapid three-dimensional multiparametric MRI with quantitative transient-state imaging

Rapid three-dimensional multiparametric MRI with quantitative transient-state imaging

Retrospective rigid motion correction of three‐dimensional magnetic resonance fingerprinting of the human brain

Magnetic resonance fingerprinting for simultaneous renal T1 and T2* mapping in a single breath‐hold

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Magnetic resonance fingerprinting for simultaneous renal T₁ and T₂^* mapping in a single breath‐hold