Three‐dimensional static and dynamic parallel transmission of the human heart at 7 T

“…Applications targeting the human body at 7T using either fixed volunteer-unspecific B + 1 shimming, 21,23 tailored B + 1 shimming, 58 or dynamic pTx techniques. 24,30 Fixed volunteer-unspecific approaches do not require additional RF management, but may lead to large B + 1 variations within the target region 23 or can lead to an extended acquisition time if the TIAMO method is used. 32 In this work, tailored B + 1 shimming was performed for three transversal slices covering the heart using channel-wise relative 3D B + 1 maps obtained within the entire thorax.…”

Section: Resultsmentioning

confidence: 99%

“…The detailed setup of the coil, as well as the applied power limits, were identical to previous publications. 24,41 The study was performed after obtaining ethical approval by the local institutional review board and after providing written informed consent from 11 healthy volunteers (age: 30 ± 5 years; max\min: 35\21 years; body mass index: 24 ± 5 kg/m 2 ; max\min: 34\19 kg/m 2 ; male\ female: 7\4). A three-lead wireless ECG was used for retrospective cardiac phase binning, following Ref.…”

Section: Methodsmentioning

confidence: 99%

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

Dietrich

Aigner

Mayer

et al. 2022

Magnetic Resonance in Med

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Purpose Respiratory motion‐compensated (MC) 3D cardiac fat‐water imaging at 7T. Methods Free‐breathing bipolar 3D triple‐echo gradient‐recalled‐echo (GRE) data with radial phase‐encoding (RPE) trajectory were acquired in 11 healthy volunteers (7M\4F, 21–35 years, mean: 30 years) with a wide range of body mass index (BMI; 19.9–34.0 kg/m2) and volunteer tailored B1+ shimming. The bipolar‐corrected triple‐echo GRE‐RPE data were binned into different respiratory phases (self‐navigation) and were used for the estimation of non‐rigid motion vector fields (MF) and respiratory resolved (RR) maps of the main magnetic field deviations (ΔB0). RR ΔB0 maps and MC ΔB0 maps were compared to a reference respiratory phase to assess respiration‐induced changes. Subsequently, cardiac binned fat‐water images were obtained using a model‐based, respiratory motion‐corrected image reconstruction. Results The 3D cardiac fat‐water imaging at 7T was successfully demonstrated. Local respiration‐induced frequency shifts in MC ΔB0 maps are small compared to the chemical shifts used in the multi‐peak model. Compared to the reference exhale ΔB0 map these changes are in the order of 10 Hz on average. Cardiac binned MC fat‐water reconstruction reduced respiration induced blurring in the fat‐water images, and flow artifacts are reduced in the end‐diastolic fat‐water separated images. Conclusion This work demonstrates the feasibility of 3D fat‐water imaging at UHF for the entire human heart despite spatial and temporal B1+ and B0 variations, as well as respiratory and cardiac motion.

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“…Respiration robustness was achieved extending the tailored‐NRR approach 9 to using multiple RR

B_{1}^{+}

‐maps of different respiration states. Code for the design of tailored‐RSpec and tailored‐RRob pulses and the used RR‐DB

B_{1}^{+}

‐maps can be downloaded from https://github.com/chaigner/tailored-RRob.…”

Section: Methodsmentioning

confidence: 99%

“…Tailored-RSpec, tailored-RRob, and UP-DB pulses were designed from RR-SB/DB B + 1 -maps and the respirationrobust UP-SBDB was designed from both, NRR-SB and RR-DB B + 1 -maps. Respiration robustness was achieved extending the tailored-NRR approach 9 to using multiple RR B + 1 -maps of different respiration states. Code for the design of tailored-RSpec and tailored-RRob pulses and the used RR-DB B + 1 -maps can be downloaded from https://github.com/chaig ner/tailo red-RRob.…”

Section: Pulse Design and Evaluationmentioning

confidence: 99%