Development of Specialized Magnetic Resonance Acquisition Techniques for Human Hyperpolarized [ C, N ]urea + [1- C]pyruvate Simultaneous Perfusion and Metabolic Imaging

Overview

Journal Magn Reson Med

Publisher Wiley

Specialty Radiology

Date 2022 May 8

PMID 35526263

Authors

Xiaoxi Liu

Shuyu Tang

Changhua Mu

Hecong Qin

Di Cui

Ying-Chieh Lai

Andrew M Riselli

Romelyn Delos Santos

Lucas Carvajal

Daniel Gebrezgiabhier

Robert A Bok

Hsin-Yu Chen

Robert R Flavell

Jeremy W Gordon

Daniel B Vigneron

John Kurhanewicz

Peder E Z Larson

Affiliations

Soon will be listed here.

Abstract

Purpose: This study aimed to develop and demonstrate the in vivo feasibility of a 3D stack-of-spiral balanced steady-state free precession(3D-bSSFP) urea sequence, interleaved with a metabolite-specific gradient echo (GRE) sequence for pyruvate and metabolic products, for improving the SNR and spatial resolution of the first hyperpolarized C-MRI human study with injection of co-hyperpolarized [1- C]pyruvate and [ C, N ]urea.

Methods: A metabolite-specific bSSFP urea imaging sequence was designed using a urea-specific excitation pulse, optimized TR, and 3D stack-of-spiral readouts. Simulations and phantom studies were performed to validate the spectral response of the sequence. The image quality of urea data acquired by the 3D-bSSFP sequence and the 2D-GRE sequence was evaluated with 2 identical injections of co-hyperpolarized [1- C]pyruvate and [ C, N ]urea formula in a rat. Subsequently, the feasibility of the acquisition strategy was validated in a prostate cancer patient.

Results: Simulations and phantom studies demonstrated that 3D-bSSFP sequence achieved urea-only excitation, while minimally perturbing other metabolites (<1%). An animal study demonstrated that compared to GRE, bSSFP sequence provided an ∼2.5-fold improvement in SNR without perturbing urea or pyruvate kinetics, and bSSFP approach with a shorter spiral readout reduced blurring artifacts caused by J-coupling of [ C, N ]urea. The human study demonstrated the in vivo feasibility and data quality of the acquisition strategy.

Conclusion: The 3D-bSSFP urea sequence with a stack-of-spiral acquisition demonstrated significantly increased SNR and image quality for [ C, N ]urea in co-hyperpolarized [1- C]pyruvate and [ C, N ]urea imaging studies. This work lays the foundation for future human studies to achieve high-quality and high-SNR metabolism and perfusion images.

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