Using high spatial resolution fMRI to understand representation in the auditory network.

• We review the study of the human auditory system with ultra-high field (UHF) (f)MRI. • UHF fMRI can detail processing in the small subcortical auditory regions. • Primary auditory cortex may be localized through use of the versatile MRI contrasts. • Laminar UHF fMRI may reveal how a categorical sound representation emerges. • UHF (f)MRI is well suited to study the sound representation in the auditory pathway. Following rapid methodological advances, ultra-high field (UHF) functional and anatomical magnetic resonance imaging (MRI) has been repeatedly and successfully used for the investigation of the human auditory system in recent years. Here, we review this work and argue that UHF MRI is uniquely suited to shed light on how sounds are represented throughout the network of auditory brain regions. That is, the provided gain in spatial resolution at UHF can be used to study the functional role of the small subcortical auditory processing stages and details of cortical processing. Further, by combining high spatial resolution with the versatility of MRI contrasts, UHF MRI has the potential to localize the primary auditory cortex in individual hemispheres. This is a prerequisite to study how sound representation in higher-level auditory cortex evolves from that in early (primary) auditory cortex. Finally, the access to independent signals across auditory cortical depths, as afforded by UHF, may reveal the computations that underlie the emergence of an abstract, categorical sound representation based on low-level acoustic feature processing. Efforts on these research topics are underway. Here we discuss promises as well as challenges that come with studying these research questions using UHF MRI, and provide a future outlook. [ABSTRACT FROM AUTHOR]