Motion‐compensated fat‐water imaging for 3D cardiac MRI at ultra‐high fields

Purpose: To develop a free-running 3D radial whole-heart multiecho gradient echo (ME-GRE) framework for cardiac-and respiratory-motion-resolved fat fraction (FF) quantification. Methods: (N TE = 8) readouts optimized for water-fat separation and quantification were integrated within a continuous non-electrocardiogram-triggered free-breathing 3D radial GRE acquisition. Motion resolution was achieved with pilot tone (PT) navigation, and the extracted cardiac and respiratory signals were compared to those obtained with self-gating (SG). After extra-dimensional golden-angle radial sparse parallel-based image reconstruction, FF, R 2 *, and B 0 maps, as well as fat and water images were generated with a maximum-likelihood fitting algorithm. The framework was tested in a fat-water phantom and in 10 healthy volunteers at 1.5 T using N TE = 4 and N TE = 8 echoes. The separated images and maps were compared with a standard free-breathing electrocardiogram (ECG)-triggered acquisition. Results:The method was validated in vivo, and physiological motion was resolved over all collected echoes. Across volunteers, PT provided respiratory and cardiac signals in agreement (r = 0.91 and r = 0.72) with SG of the first echo, and a higher correlation to the ECG (0.1% of missed triggers for PT vs. 5.9% for SG). The framework enabled pericardial fat imaging and quantification throughout the cardiac cycle, revealing a decrease in FF at end-systole by 11.4% ± 3.1% across volunteers (p < 0.0001). Motion-resolved end-diastolic 3D FF maps showed good correlation with ECG-triggered measurements (FF bias of −1.06%). A significant difference in free-running FF measured with N TE = 4 and N TE = 8 was found (p < 0.0001 in sub-cutaneous fat and p < 0.01 in pericardial fat). Conclusion:Free-running fat fraction mapping was validated at 1.5 T, enabling ME-GRE-based fat quantification with N TE = 8 echoes in 6:15 min.

Section: Introductionmentioning

confidence: 99%

Motion‐resolved fat‐fraction mapping with whole‐heart free‐running multiecho GRE and pilot tone

Mackowiak

Roy

Yerly

et al. 2023

“…A potential extension of this work would be the inclusion of B 0 variations in the pulse design. Nevertheless, further investigation is required to implement and validate the impact of respiration resolved 3D B 0 ‐maps in the human body 26 …”

Section: Discussionmentioning

confidence: 99%

“…In addition to the aforementioned observations in 2D acquisitions, 14 FA variations across the respiratory cycle may further limit the flexibility and data efficiency of retrospectively binned and motion corrected 3D reconstructions. Therefore, homogeneous FAs across all respiration states in the 3D target region are essential to use the full potential of 3D free‐breathing cardiac imaging methods 25,26 …”

Section: Introductionmentioning

confidence: 99%

“…Therefore, homogeneous FAs across all respiration states in the 3D target region are essential to use the full potential of 3D free-breathing cardiac imaging methods. 25,26 Three-dimensional respiration-resolved (RR) B + 1 mapping was recently proposed in subjects performing SB and DB. 12 Such 3D RR B + 1 -maps enable analyzing and potentially correcting for the impact of respiration-related B + 1 changes with a dedicated pTx pulse design.…”

Section: Introductionmentioning

confidence: 99%

“…Nevertheless, further investigation is required to implement and validate the impact of respiration resolved 3D B 0 -maps in the human body. 26…”

mentioning

confidence: 99%

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Respiration induced B1+ changes and their impact on universal and tailored 3D kT‐point parallel transmission pulses for 7T cardiac imaging

Aigner

Dietrich

Schmitter

2022

Self Cite

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

Aigner,

Dietrich‐Conzelmann,

Lutz

et al. 2024

Self Cite

PurposeTo research and evaluate the performance of broadband tailored kT‐point pulses (TP) and universal pulses (UP) for homogeneous excitation of the human heart at 7T.MethodsRelative 3D ‐maps of the thorax were acquired from 29 healthy volunteers. TP and UP were designed using the small‐tip‐angle approximation for a different composition of up to seven resonance frequencies. TP were computed for each of the 29 ‐maps, and UPs were calculated using 22 ‐maps and tested in seven testcases. The performance of the pulses was analyzed using the coefficient of variation (CV) in the 3D heart volumes. The 3D gradient‐echo (GRE) scans were acquired for the seven testcases to qualitatively validate the ‐predictions.ResultsSingle‐ and double‐frequency optimized pulses achieved homogeneity in flip angle (FA) for the frequencies they were optimized for, while the broadband pulses achieved uniformity in FA across a 1300 Hz frequency range.ConclusionBroadband TP and UP can be used for homogeneous excitation of the heart volume across a 1300 Hz frequency range, including the water and the main six fat peaks, or with longer pulse durations and higher FAs for a smaller transmit bandwidth. Moreover, despite large inter‐volunteer variations, broadband UP can be used for calibration‐free 3D heart FA homogenization in time‐critical situations.