Single-shot Echo Planar Time-resolved Imaging for multi-echo functional MRI and distortion-free diffusion imaging

Dong, Zijing; Wald, Lawrence L.; Polimeni, Jonathan R.; Wang, Fuyixue

doi:10.1101/2024.01.24.577002

Cited by 3 publications

References 89 publications

(118 reference statements)

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Romer‐EPTI: Rotating‐view motion‐robust super‐resolution EPTI for SNR‐efficient distortion‐free in‐vivo mesoscale diffusion MRI and microstructure imaging

Dong,

Reese,

Lee

et al. 2024

Magnetic Resonance in Med

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PurposeTo overcome the major challenges in diffusion MRI (dMRI) acquisition, including limited SNR, distortion/blurring, and susceptibility to motion artifacts.Theory and MethodsA novel Romer‐EPTI technique is developed to achieve SNR‐efficient acquisition while providing distortion‐free imaging, minimal spatial blurring, high motion robustness, and simultaneous multi‐TE imaging. It introduces a ROtating‐view Motion‐robust supEr‐Resolution technique (Romer) combined with a distortion/blurring‐free Echo Planar Time‐resolved Imaging (EPTI) readout. Romer enhances SNR through simultaneous multi‐thick‐slice acquisition with rotating‐view encoding, while providing high motion‐robustness via a high‐fidelity, motion‐aware super‐resolution reconstruction. Instead of EPI, the in‐plane encoding is performed using EPTI readout to prevent geometric distortion, T2/T2*‐blurring, and importantly, dynamic distortions that could introduce additional blurring/artifacts after super‐resolution reconstruction due to combining volumes with inconsistent geometries. This further improves effective spatial resolution and motion robustness. Additional developments include strategies to address slab‐boundary artifacts, achieve minimized TE and optimized readout for additional SNR gain, and increase robustness to strong phase variations at high b‐values.ResultsUsing Romer‐EPTI, we demonstrated distortion‐free whole‐brain mesoscale in‐vivo dMRI at both 3T (500‐μm isotropic [iso] resolution) and 7T (485‐μm iso resolution) for the first time. Motion experiments demonstrated the technique's motion robustness and its ability to obtain high‐resolution diffusion images in the presence of subject motion. Romer‐EPTI also demonstrated high SNR gain and robustness in high b‐value (b = 5000 s/mm2) and time‐dependent dMRI.ConclusionThe high SNR efficiency, improved image quality, and motion robustness of Romer‐EPTI make it a highly efficient acquisition for high‐resolution dMRI and microstructure imaging.

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Romer‐EPTI: Rotating‐view motion‐robust super‐resolution EPTI for SNR‐efficient distortion‐free in‐vivo mesoscale diffusion MRI and microstructure imaging

Dong,

Reese,

Lee

et al. 2024

Magnetic Resonance in Med

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Time‐resolved MR fingerprinting for T₂* signal extraction: MR fingerprinting meets echo planar time‐resolved imaging

Cui,

Liu,

Larson

et al. 2024

Magnetic Resonance in Med

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PurposeThis study leverages the echo planar time‐resolved imaging (EPTI) concept in MR fingerprinting (MRF) framework for a new time‐resolved MRF (TRMRF) approach, and explores its capability for fast simultaneous quantification of multiple MR parameters including T1, T2, T2*, proton density, off resonance, and B1+.MethodsThe proposed TRMRF method uses the concept of EPTI to track the signal change along the EPI echo train for T2* weighting with a k‐t Poisson‐based sampling order designed for acquisition. A two‐dimensional decomposition algorithm was designed for the image reconstruction, enabling fast and precise subspace modeling. The accuracy of proposed method was evaluated by a T1/T2 phantom. The feasibility was demonstrated through 5 healthy volunteer brain studies.ResultsIn the phantom studies, T1, T2, and T2* maps of TRMRF correlated strongly with gold‐standard methods. The concordance correlation coefficients are 0.9999, 0.9984 and 0.9978, and R2s are 0.9998, 0.9971, and 0.9983. In the in vivo studies, quantitative maps were acquired with 5 healthy volunteers. TRMRF was demonstrated to have comparable results with spiral MRF and gradient‐echo EPTI. TRMRF scans using 16, 10, and 6 s per slice were also evaluated to demonstrate the capability of shorter scan times.ConclusionA new approach is proposed to exploit the advantage of EPTI in the MRF framework. We demonstrate in phantom and in vivo experiments that T1, T2, T2*, proton density, off resonance, and B1+ can be simultaneously quantified within 6 s/slice by TRMRF.

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Romer-EPTI: rotating-view motion-robust super-resolution EPTI for SNR-efficient distortion-free in-vivo mesoscale dMRI and microstructure imaging

Dong,

Reese,

Lee

et al. 2024

Preprint

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PurposeTo overcome the major challenges in diffusion MRI acquisition, including low SNR, distortion/blurring, and motion vulnerability.MethodsA novel Romer-EPTI technique is developed to provide high SNR, sharp spatial resolution, high motion-robustness, images free from distortion and slab-boundary artifacts, and simultaneous multi-TE imaging. It integrates a ROtating-view Motion-robust supEr-Resolution technique (Romer) with a distortion/blurring-free self-navigated EPTI encoding. Romer enhances SNR with high-motion robustness by employing a thick-slice acquisition with rotating-view encoding, and a motion-aware super-resolution reconstruction that incorporates motion, slice-profile and real-value diffusion. The in-plane encoding of the thick-slice volumes is performed using distortion/blurring-free EPTI readout, which further improves Romer’s motion robustness by preventing detrimental blurring resulting from combination of inconsistent geometries caused by motion or eddy-current induced dynamic distortions. The Romer encoding, motion-aware reconstruction, together with T2/T2*-blurring-free EPTI readout enable effective reconstruction of the sharp spatial resolution. Furthermore, Romer-EPTI provides short TE and low SAR for 7T dMRI and high robustness to phase variations for high-b-value imaging.ResultsUsing Romer-EPTI, we demonstrate distortion-free whole-brain mesoscale in-vivo dMRI at both 3T (500μm-iso) and 7T (485μm-iso) for the first time, with high SNR efficiency (e.g., √25×), and high image quality free from distortion and slab-boundary artifacts with minimal blurring. Motion experiments demonstrate the high motion-robustness of Romer-EPTI and its ability to recover sharp images in presence of subject motion. We also demonstrate its significant SNR gain and robustness in high b-value (b=5000s/mm2) and time-dependent dMRI.ConclusionRomer-EPTI significantly improves SNR, motion-robustness, and image quality of dMRI, providing a highly efficient acquisition for high-resolution dMRI and microstructure imaging.

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Single-shot Echo Planar Time-resolved Imaging for multi-echo functional MRI and distortion-free diffusion imaging

Cited by 3 publications

References 89 publications

Romer‐EPTI: Rotating‐view motion‐robust super‐resolution EPTI for SNR‐efficient distortion‐free in‐vivo mesoscale diffusion MRI and microstructure imaging

Romer‐EPTI: Rotating‐view motion‐robust super‐resolution EPTI for SNR‐efficient distortion‐free in‐vivo mesoscale diffusion MRI and microstructure imaging

Time‐resolved MR fingerprinting for T₂* signal extraction: MR fingerprinting meets echo planar time‐resolved imaging

Romer-EPTI: rotating-view motion-robust super-resolution EPTI for SNR-efficient distortion-free in-vivo mesoscale dMRI and microstructure imaging

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Single-shot Echo Planar Time-resolved Imaging for multi-echo functional MRI and distortion-free diffusion imaging

Cited by 3 publications

References 89 publications

Romer‐EPTI: Rotating‐view motion‐robust super‐resolution EPTI for SNR‐efficient distortion‐free in‐vivo mesoscale diffusion MRI and microstructure imaging

Romer‐EPTI: Rotating‐view motion‐robust super‐resolution EPTI for SNR‐efficient distortion‐free in‐vivo mesoscale diffusion MRI and microstructure imaging

Time‐resolved MR fingerprinting for T2* signal extraction: MR fingerprinting meets echo planar time‐resolved imaging

Romer-EPTI: rotating-view motion-robust super-resolution EPTI for SNR-efficient distortion-free in-vivo mesoscale dMRI and microstructure imaging

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Time‐resolved MR fingerprinting for T₂* signal extraction: MR fingerprinting meets echo planar time‐resolved imaging