Leveraging ultra-high field (7T) MRI in psychiatric research

• Published in: Neuropsychopharmacology (New York, N.Y.)
• Main Authors: Calabro, Finnegan J, Parr, Ashley C, Sydnor, Valerie J, Hetherington, Hoby, Prasad, Konasale M, Ibrahim, Tamer S, Sarpal, Deepak K, Famalette, Alyssa, Verma, Piya, Luna, Beatriz
• Format: Journal Article
• Language: English
• Published: England 09.09.2024
• ISSN: 0893-133X; 1740-634X; 1740-634X
• DOI: 10.1038/s41386-024-01980-6

Non-invasive brain imaging has played a critical role in establishing our understanding of the neural properties that contribute to the emergence of psychiatric disorders. However, characterizing core neurobiological mechanisms of psychiatric symptomatology requires greater structural, functional, and neurochemical specificity than is typically obtainable with standard field strength MRI acquisitions (e.g., 3T). Ultra-high field (UHF) imaging at 7 Tesla (7T) provides the opportunity to identify neurobiological systems that confer risk, determine etiology, and characterize disease progression and treatment outcomes of major mental illnesses. Increases in scanner availability, regulatory approval, and sequence availability have made the application of UHF to clinical cohorts more feasible than ever before, yet the application of UHF approaches to the study of mental health remains nascent. In this technical review, we describe core neuroimaging methodologies which benefit from UHF acquisition, including high resolution structural and functional imaging, single ( H) and multi-nuclear (e.g., P) MR spectroscopy, and quantitative MR techniques for assessing brain tissue iron and myelin. We discuss advantages provided by 7T MRI, including higher signal- and contrast-to-noise ratio, enhanced spatial resolution, increased test-retest reliability, and molecular and neurochemical specificity, and how these have begun to uncover mechanisms of psychiatric disorders. Finally, we consider current limitations of UHF in its application to clinical cohorts, and point to ongoing work that aims to overcome technical hurdles through the continued development of UHF hardware, software, and protocols.