Magnetization-prepared IDEAL BSSFP: a Flow-independent Technique for Noncontrast-enhanced Peripheral Angiography

Overview

Journal J Magn Reson Imaging

Date 2011 Mar 31

PMID 21448960

Citations 8

Authors

Tolga Cukur

Ann Shimakawa

Huanzhou Yu

Brian A Hargreaves

Bob S Hu

Dwight G Nishimura

Jean H Brittain

Affiliations

Soon will be listed here.

Abstract

Purpose: To propose a new noncontrast-enhanced flow-independent angiography sequence based on balanced steady-state free precession (bSSFP) that produces reliable vessel contrast despite the reduced blood flow in the extremities.

Materials And Methods: The proposed technique addresses a variety of factors that can compromise the exam success including insufficient background suppression, field inhomogeneity, and large volumetric coverage requirements. A bSSFP sequence yields reduced signal from venous blood when long repetition times are used. Complex-sum bSSFP acquisitions decrease the sensitivity to field inhomogeneity but retain phase information, so that data can be processed with the Iterative Decomposition of Water and Fat with Echo Asymmetry and Least-Squares Estimation (IDEAL) method for robust fat suppression. Meanwhile, frequent magnetization preparation coupled with parallel imaging reduces the muscle and long-T(1) fluid signals without compromising scan efficiency.

Results: In vivo flow-independent peripheral angiograms with reliable background suppression and high spatial resolution are produced. Comparisons with phase-sensitive bSSFP angiograms (that yield out-of-phase fat and water signals, and exploit this phase difference to suppress fat) demonstrate enhanced vessel depiction with the proposed technique due to reduced partial-volume effects and improved venous suppression.

Conclusion: Magnetization-prepared complex-sum bSSFP with IDEAL fat/water separation can create reliable flow-independent angiographic contrast in the lower extremities.

Citing Articles

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Water Selective Imaging and bSSFP Banding Artifact Correction in Humans and Small Animals at 3T and 7T, Respectively.

Ribot E, Wecker D, Trotier A, Dallaudiere B, Lefrancois W, Thiaudiere E PLoS One. 2015; 10(10):e0139249.

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