Abstract
Studying the human subcortical auditory system non-invasively is challenging due to its small, densely packed structures deep within the brain. Additionally, the elaborate three-dimensional (3-D) structure of the system can be difficult to understand based on currently available 2-D schematics and animal models. Wfe addressed these issues using a combination of histological data, post mortem magnetic resonance imaging (MRI), and in vivo MRI at 7 Tesla. We created anatomical atlases based on state-of-the-art human histology (BigBrain) and postmortem MRI (50 µm). We measured functional MRI (fMRI) responses to natural sounds and demonstrate that the functional localization of subcortical structures is reliable within individual participants who were scanned in two different experiments. Further, a group functional atlas derived from the functional data locates these structures with a median distance below 2 mm. Using diffusion MRI tractography, we revealed structural connectivity maps of the human subcortical auditory pathway both in vivo (1050 µm isotropic resolution) and post mortem (200 µm isotropic resolution). This work captures current MRI capabilities for investigating the human subcortical auditory system, describes challenges that remain, and contributes novel, openly available data, atlases, and tools for researching the human auditory system.
Highlights
Understanding the structure of the human subcortical auditory pathway is a necessary step to research its role in hearing, speech communication, and music
The results of our BigBrain subcortical auditory segmentation in corrected MNI space are reported in Fig 1 together with schematics redrawn from Moore (1987) and the Allen Human Brain Atlas (Hawrylycz et al, 2012; Ding et al, 2016)
We report the reproducibility of the individual functional delineations in six out of the ten participants who participated in a follow up experiment in which responses to 96 natural sounds (Experiment 2) were collected at 7 Tesla (7T) using a sparse acquisition scheme and a fast even related design
Summary
Understanding the structure of the human subcortical auditory pathway is a necessary step to research its role in hearing, speech communication, and music. Due to methodological issues in human research, most of our understanding of the subcortical (thalamic, midbrain, and brainstem) auditory pathway arises from research conducted in animal models. This might be problematic because, while the organization of the auditory pathway is largely conserved across mammalian species (Malmierca and Hackett, 2010; Schofield, 2010), the form and function of each structure may not be analogous (Moore, 1987). Moore (1987) stained both myelin and the cell bodies of subcortical auditory structures in four post mortem human brainstem samples and compared them to the analogous structures in cats (a common model for auditory investigations at the time). Kulesza (2007) stained six human brainstems for Nissl substance, focusing on the superior olivary complex, finding evidence of a substructure (the medial nucleus of the trapezoid body) whose existence in the human auditory system has been debated for decades
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