Litcius/Paper detail

Free‐breathing multitasking multi‐echo MRI for whole‐liver water‐specific T<sub>1</sub>, proton density fat fraction, and quantification

Nan Wang, Tianle Cao, Fei Han, Yibin Xie, Xiaodong Zhong, Sen Ma, Alan C. Kwan, Zhaoyang Fan, Hui Han, Xiaoming Bi, Mazen Noureddin, Vibhas Deshpande, Anthony Christodoulou, Debiao Li

2021Magnetic Resonance in Medicine33 citationsDOIOpen Access PDF

Abstract

Purpose To develop a 3D multitasking multi‐echo (MT‐ME) technique for the comprehensive characterization of liver tissues with 5‐min free‐breathing acquisition; whole‐liver coverage; a spatial resolution of 1.5 × 1.5 × 6 mm 3 ; and simultaneous quantification of T 1 , water‐specific T 1 (T 1w ), proton density fat fraction (PDFF), and . Methods Six‐echo bipolar spoiled gradient echo readouts following inversion recovery preparation was performed to generate T 1 , water/fat, and contrast. MR multitasking was used to reconstruct the MT‐ME images with 3 spatial dimensions: 1 T 1 recovery dimension, 1 multi‐echo dimension, and 1 respiratory dimension. A basis function–based approach was developed for T 1w quantification, followed by the estimation of and T 1 ‐corrected PDFF. The intrasession repeatability and agreement against references of MT‐ME measurements were tested on a phantom and 15 clinically healthy subjects. In addition, 4 patients with confirmed liver diseases were recruited, and the agreement between MT‐ME measurements and references was assessed. Results MT‐ME produced high‐quality, coregistered T 1 , T 1w , PDFF, and maps with good intrasession repeatability and substantial agreement with references on phantom and human studies. The intra‐class coefficients of T 1 , T 1w , PDFF, and from the repeat MT‐ME measurements on clinically healthy subjects were 0.989, 0.990, 0.999, and 0.988, respectively. The intra‐class coefficients of T 1 , PDFF, and between the MT‐ME and reference measurements were 0.924, 0.987, and 0.975 in healthy subjects and 0.980, 0.999, and 0.998 in patients. The T 1w was independent to PDFF (R = −0.029, P = .904). Conclusion The proposed MT‐ME technique quantifies T 1 , T 1w , PDFF, and simultaneously and is clinically promising for the comprehensive characterization of liver tissue properties.

Topics & Concepts

RepeatabilityImaging phantomNuclear medicineNuclear magnetic resonanceMagnetic resonance imagingMaterials scienceChemistryMedicinePhysicsRadiologyChromatographyLiver Disease Diagnosis and TreatmentAdvanced MRI Techniques and ApplicationsAdvanced NMR Techniques and Applications