AI Article Synopsis
- Developed a single-slab 3D spiral turbo spin echo (spiral SPACE) imaging technique for 1-mm isotropic whole-brain T-weighted imaging using a 0.55T scanner focused on high scan efficiency.
- Implemented methods included gradient infidelity correction, phase error compensation during readouts, and adjusted RF pulses to achieve enhanced echo trains, leading to improved image quality.
- Results indicated a 15%-25% improvement in signal-to-noise ratio (SNR) for spiral SPACE over Cartesian SPACE, showing reduced artifacts and blurring in tested subjects.
Article Abstract
Purpose: To develop single-slab 3D spiral turbo spin echo (spiral SPACE) for 1-mm isotropic whole-brain T-weighted imaging on a high-performance 0.55T scanner, with high scan efficiency from interleaved spiral-in-out trajectories, variable-flip-angle refocusing radiofrequency (RF) pulses, echo reordering, and concomitant-field compensation.
Methods: A stack-of-spirals (in-out waveforms) turbo-spin-echo acquisition was implemented with T-weighed contrast. Gradient infidelity was corrected using the gradient impulse response function (GIRF), and concomitant-field compensation was used to correct for phase errors among echoes and during the readout windows. To maintain a long echo train (˜600 ms) within each shot, variable-flip-angle refocusing RF pulses were generated using extended-phase-graph analysis. An echo-reordering scheme provided a smooth signal variation along the echo direction in k-space. Images from spiral SPACE with and without concomitant-field compensation were compared with those from Cartesian SPACE in phantoms and 6 healthy volunteers.
Results: Phantom results demonstrated the improved performance of concomitant-field correction via sequence-based modifications and of GIRF-based trajectory estimation. Volunteer data showed that with concomitant-field correction and echo reordering, system imperfection associated image artifacts and blurring were substantially mitigated in spiral SPACE. Compared with Cartesian SPACE, spiral SPACE had an overall 15%-25% signal-to-noise ratio (SNR) improvement in both white matter and gray matter.
Conclusion: A 3D spiral-in-out SPACE acquisition with variable-flip-angles, concomitant-field compensation, and echo-reordering was demonstrated at 0.55 T, showing promising gains in SNR, compared with Cartesian SPACE.
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| http://dx.doi.org/10.1002/mrm.30380 | DOI Listing |
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