Z-Spectrum analysis provides proton environment data (ZAPPED): a new two-pool technique for human gray and white matter.

Mitsue Miyazaki,Tomohisa Okada,Susumu Miyamoto,Yoshiki Arakawa,Yasutaka Fushimi,Koji Fujimoto,James B Murdoch,Kaori Togashi,Cheng Ouyang,Xiangzhi Zhou,Aki Kido

doi:10.1371/journal.pone.0119915

Mitsue Miyazaki, Tomohisa Okada + Show 9 more

Open Access

https://doi.org/10.1371/journal.pone.0119915

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Journal: PloS one	Publication Date: Mar 13, 2015
Citations: 25	License type: CC BY 4.0

Affiliation: Kyoto University, Toshiba (United States)

Abstract

A new technique – Z-spectrum Analysis Provides Proton Environment Data (ZAPPED) – was used to map cross-relaxing free and restricted protons in nine healthy subjects plus two brain tumor patients at 3T. First, MT data were acquired over a wide symmetric range of frequency offsets, and then a trio of quantitative biomarkers, i.e., the apparent spin-spin relaxation times (T2,f, T2,r) in both free and restricted proton pools as well as the restricted pool fraction Fr, were mapped by fitting the measured Z-spectra to a simple two-Lorentzian compartment model on a voxel-by-voxel basis. The mean restricted exchangeable proton fraction, Fr, was found to be 0.17 in gray matter (GM) and 0.28 in white matter (WM) in healthy subjects. Corresponding mean values for apparent spin-spin relaxation times were 785 µs (T2,f) and 17.7 µs (T2,r) in GM, 672 µs (T2,f) and 23.4 µs (T2,r) in WM. The percentages of Ff and Fr in GM are similar for all ages, whereas Fr shows a tendency to decrease with age in WM among healthy subjects. The patient ZAPPED images show higher contrast between tumor and normal tissues than traditional T2-weighted and T1-weighted images. The ZAPPED method provides a simple phenomenological approach to estimating fractions and apparent T2 values of free and restricted MT-active protons, and it may offer clinical useful information.

Highlights

Magnetization transfer contrast (MTC), a mechanism that is used to indirectly detect macromolecular properties in magnetic resonance imaging (MRI) by observing the exchange of magnetization between "free" and "restricted" water protons in macromolecules, was originally introduced over 20 years ago [1]
White matter, and cerebrospinal fluid (CSF) were successfully segmented for all nine subjects
The percentages of Ff and Fr in gray matter (GM) are similar for all ages, whereas Fr shows a tendency to decrease with age in white matter (WM) among healthy subjects

Summary

Introduction

Magnetization transfer contrast (MTC), a mechanism that is used to indirectly detect macromolecular properties in magnetic resonance imaging (MRI) by observing the exchange of magnetization between "free" and "restricted" water protons in macromolecules, was originally introduced over 20 years ago [1]. Z-Spectrum Analysis Provides Proton Environment Data (ZAPPED). NS from TMSC has helped data collection. The authors have patent applications (by MM, CO and XZ on USA13/601,723 “AUTOMATED MRI DETECTION OF TISSUE MACROMOLECULAR T2/T2Ã CHARACTERISTICS USING Z-SPECTRA”; Aug, 31, 2012, 13/705,582 “AUTOMATED MRI DETECTION OF TISSUE MACROMOLECULAR T2/T2Ã CHARACTERISTICS USING Z-SPECTRA”; Dec. 5, 2012, and 14/470137 “MAGNETIC RESONANCE IMAGING APPARATUS”; Aug. 27, 2014) for the ZAPPED technique which are still pending. There are no further patents, products in development or marketed products to declare. This does not alter the authors' adherence to all the PLOS ONE policies on sharing data and materials

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