In vitro singlet state and zero-quantum encoded magnetic resonance spectroscopy: Illustration with N-acetyl-aspartate.

Andrey N Pravdivtsev,Jan-Bernd Hövener,Frank D Sönnichsen,Patrick Van Der Wel

doi:10.1371/journal.pone.0239982

Andrey N Pravdivtsev, Jan-Bernd Hövener + Show 2 more

Open Access

https://doi.org/10.1371/journal.pone.0239982

Copy DOI

Journal: PloS one	Publication Date: Oct 1, 2020
Citations: 8	License type: CC BY 4.0

Affiliation: Clinical Research Center Kiel, Kiel University

Abstract

Magnetic resonance spectroscopy (MRS) allows the analysis of biochemical processes non-invasively and in vivo. Still, its application in clinical diagnostics is rare. Routine MRS is limited to spatial, chemical and temporal resolutions of cubic centimetres, mM and minutes. In fact, the signal of many metabolites is strong enough for detection, but the resonances significantly overlap, exacerbating identification and quantification. Besides, the signals of water and lipids are much stronger and dominate the entire spectrum. To suppress the background and isolate selected signals, usually, relaxation times, J-coupling and chemical shifts are used. Here, we propose methods to isolate the signals of selected molecular groups within endogenous metabolites by using long-lived spin states (LLS). We exemplify the method by preparing the LLSs of coupled protons in the endogenous molecules N-acetyl-L-aspartic acid (NAA). First, we store polarization in long-lived, double spin states, followed by saturation pulses before the spin order is converted back to observable magnetization or double quantum filters to suppress background signals. We show that LLS and zero-quantum coherences can be used to selectively prepare and measure the signals of chosen metabolites or drugs in the presence of water, inhomogeneous field and highly concentrated fatty solutions. The strong suppression of unwanted signals achieved allowed us to measure pH as a function of chemical shift difference.

Highlights

Magnetic resonance (MR) has found a multitude of applications in medical imaging, from anatomy to motion, function and metabolism [1,2,3]
Each of the substrates listed above was dissolved in D2O (Deutero GmbH, 00506) to yield a concentration of 10 mmol/L. pH was adjusted to the desired value by adding NaOD (Deutero GmbH, 03703) or DCl (Sigma Aldrich, 543047); pH-dependent NMR spectra of all substrates are given in supporting materials (SM)
The chemical shift difference DdCH2 was encoded into the signal by variation of τ2, and determined by Fourier transforming the summed amplitudes of the singlet-state encoded MR” (SISTEM)-II signal acquired for different τ2 (D)

Summary

Introduction

Magnetic resonance (MR) has found a multitude of applications in medical imaging, from anatomy to motion, function and metabolism [1,2,3]. One of the most promising, yet least delivering applications is in vivo MR spectroscopy (MRS). MRS provides a non-invasive window into the biochemistry of living organisms–basically a virtual biopsy. It does not live up to this promise, as MRS is rarely used in routine diagnostics.

Methods

Results

Discussion

Conclusion