Recent technical developments and clinical research applications of sodium (Na) MRI.

in Progress in nuclear magnetic resonance spectroscopy by Lena V Gast, Tanja Platt, Armin M Nagel, Teresa Gerhalter

TLDR

  • This article provides a comprehensive review of technical and clinical developments in sodium MRI over the past decade.
  • The article highlights the potential of sodium MRI as a diagnostic and prognostic tool for various diseases and its potential to provide non-invasive assessment of physiological changes.
  • The article covers various technical and clinical applications of sodium MRI and suggests possible future research directions.

Abstract

Sodium is an essential ion that plays a central role in many physiological processes including the transmembrane electrochemical gradient and the maintenance of the body's homeostasis. Due to the crucial role of sodium in the human body, the sodium nucleus is a promising candidate for non-invasively assessing (patho-)physiological changes. Almost 10 years ago, Madelin et al. provided a comprehensive review of methods and applications of sodium (Na) MRI (Madelin et al., 2014) [1]. More recent review articles have focused mainly on specific applications ofNa MRI. For example, several articles coveredNa MRI applications for diseases such as osteoarthritis (Zbyn et al., 2016, Zaric et al., 2020) [2,3], multiple sclerosis (Petracca et al., 2016, Huhn et al., 2019) [4,5] and brain tumors (Schepkin, 2016) [6], or for imaging certain organs such as the kidneys (Zollner et al., 2016) [7], the brain (Shah et al., 2016, Thulborn et al., 2018) [8,9], and the heart (Bottomley, 2016) [10]. Other articles have reviewed technical developments such as radiofrequency (RF) coils forNa MRI (Wiggins et al., 2016, Bangerter et al., 2016) [11,12], pulse sequences (Konstandin et al., 2014) [13], image reconstruction methods (Chen et al., 2021) [14], and interleaved/simultaneous imaging techniques (Lopez Kolkovsky et al., 2022) [15]. In addition,Na MRI topics have been covered in review articles with broader topics such as multinuclear MRI or ultra-high-field MRI (Niesporek et al., 2019, Hu et al., 2019, Ladd et al., 2018) [16-18]. During the past decade, various research groups have continued working on technical improvements to sodium MRI and have investigated its potential to serve as a diagnostic and prognostic tool. Clinical research applications ofNa MRI have covered a broad spectrum of diseases, mainly focusing on the brain, cartilage, and skeletal muscle (see Fig. 1). In this article, we aim to provide a comprehensive summary of methodological and hardware developments, as well as a review of various clinical research applications of sodium (Na) MRI in the last decade (i.e., published from the beginning of 2013 to the end of 2022).

Overview

  • This article aims to provide a comprehensive summary of methodological and hardware developments, as well as a review of various clinical research applications of sodium MRI in the last decade.
  • The article will cover a range of topics, including technical developments and clinical applications of sodium MRI in various fields such as the brain, cartilage, and skeletal muscle.
  • The article will focus on the potential of sodium MRI as a diagnostic and prognostic tool for various diseases, highlighting the importance of non-invasive assessment of physiological changes.

Comparative Analysis & Findings

  • The article will explore various technical developments in sodium MRI, including radiofrequency coils, pulse sequences, image reconstruction methods, and interleaved/simultaneous imaging techniques.
  • The article will discuss the clinical applications of sodium MRI in various fields, including diseases such as osteoarthritis, multiple sclerosis, and brain tumors, as well as in imaging certain organs such as the kidneys, the brain, and the heart.
  • The article will highlight the potential of sodium MRI to provide non-invasive assessment of physiological changes and its potential as a diagnostic and prognostic tool for various diseases.

Implications and Future Directions

  • The article will highlight the importance of continued research and development in sodium MRI to improve its technical capabilities and expand its clinical applications.
  • The article will discuss the potential of sodium MRI to improve the diagnosis and treatment of various diseases, particularly in fields such as neurology and orthopedics.
  • The article will suggest possible future research directions, including exploring the potential of sodium MRI in other fields and investigating its use in combination with other imaging modalities.
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