AUTHOR=Li Ningzhi , Li Shizhe , Shen Jun 

TITLE=High Field In vivo13C Magnetic Resonance Spectroscopy of Brain by Random Radiofrequency Heteronuclear Decoupling and Data Undersampling

JOURNAL=Frontiers in Physics

VOLUME=5

YEAR=2017

URL=https://www.frontiersin.org/journals/physics/articles/10.3389/fphy.2017.00026

DOI=10.3389/fphy.2017.00026

ISSN=2296-424X

ABSTRACT=<p><italic>In vivo</italic><sup>13</sup>C magnetic resonance spectroscopy (MRS) is a unique and effective tool for studying dynamic human brain metabolism and the cycling of neurotransmitters. One of the major technical challenges for <italic>in vivo</italic><sup>13</sup>C-MRS is the high radio frequency (RF) power necessary for heteronuclear decoupling. In the common practice of <italic>in vivo</italic><sup>13</sup>C-MRS, alkanyl carbons are detected in the spectra range of 10–65 ppm. The amplitude of decoupling pulses has to be significantly greater than the large one-bond <sup>1</sup>H-<sup>13</sup>C scalar coupling (<sup>1</sup>J<sub>CH</sub> = 125–145 Hz). Two main proton decoupling methods have been developed: broadband stochastic decoupling and coherent composite or adiabatic pulse decoupling (e.g., WALTZ); the latter is widely used because of its efficiency and superb performance under inhomogeneous B<sub>1</sub> field. Because the RF power required for proton decoupling increases quadratically with field strength, <italic>in vivo</italic><sup>13</sup>C-MRS using coherent decoupling is often limited to low magnetic fields [&lt;=4 Tesla (T)] to keep the local and averaged specific absorption rate (SAR) under the safety guidelines established by the International Electrotechnical Commission (IEC) and the US Food and Drug Administration (FDA). Alternately, carboxylic/amide carbons are coupled to protons via weak long-range <sup>1</sup>H-<sup>13</sup>C scalar couplings, which can be decoupled using low RF power broadband stochastic decoupling. Recently, the carboxylic/amide <sup>13</sup>C-MRS technique using low power random RF heteronuclear decoupling was safely applied to human brain studies at 7T. Here, we review the two major decoupling methods and the carboxylic/amide <sup>13</sup>C-MRS with low power decoupling strategy. Further decreases in RF power deposition by frequency-domain windowing and time-domain random under-sampling are also discussed. Low RF power decoupling opens the possibility of performing <italic>in vivo</italic><sup>13</sup>C experiments of human brain at very high magnetic fields (such as 11.7T), where signal-to-noise ratio as well as spatial and temporal spectral resolution are more favorable than lower fields.</p>