Abstract
The layers of the neocortex each have a unique anatomical connectivity and functional role. Their exploration in the human brain, however, has been severely restricted by the limited spatial resolution of non-invasive measurement techniques. Here, we exploit the sensitivity and specificity of ultra-high field fMRI at 7 Tesla to investigate responses to natural sounds at deep, middle, and superficial cortical depths of the human auditory cortex. Specifically, we compare the performance of computational models that represent different hypotheses on sound processing inside and outside the primary auditory cortex (PAC). We observe that while BOLD responses in deep and middle PAC layers are equally well represented by a simple frequency model and a more complex spectrotemporal modulation model, responses in superficial PAC are better represented by the more complex model. This indicates an increase in processing complexity in superficial PAC, which remains present throughout cortical depths in the non-primary auditory cortex. These results suggest that a relevant transformation in sound processing takes place between the thalamo-recipient middle PAC layers and superficial PAC. This transformation may be a first computational step towards sound abstraction and perception, serving to form an increasingly more complex representation of the physical input.
Highlights
The human neocortex consists of six layers, each with a distinct anatomical connectivity and functionality
We observed significant responses to the sounds throughout the supratemporal plane, including HG, Heschl’s sulcus, planum polare (PP), planum temporale (PT), and the parts of the superior temporal gyrus and sulcus that were covered by the fMRI field of view
The improved performance of the spectrotemporal modulation model in the non-primary auditory cortex (PAC) compared to the PAC was not confined to a subset of sounds, but was observed for all sound categories (Fig. S1b). It remains unclear if the laminar anatomical connectivity pattern of the human PAC is paralleled by layer-specific variations in sound processing
Summary
The human neocortex consists of six layers, each with a distinct anatomical connectivity and functionality. This suggests that the neuronal populations underlying the responses to natural sounds in superficial PAC display an increase in processing complexity compared to deep and middle PAC layers. This increased processing complexity is present throughout cortical depths in the non-primary auditory cortex as well.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
