Humans and other animals use spatial hearing to rapidly localize events in the environment.
However, neural encoding of sound location is a complex process involving the computation …

Our ability to make sense of the auditory world results from neural processing that begins in
the ear, goes through multiple subcortical areas, and continues in the cortex. The specific …

Evolution provides an important window into how cortical organization shapes function and
vice versa. The complex mosaic of changes in brain morphology and functional organization …

Recently, we showed that in a simple acoustic scene with one sound source, auditory cortex
tracks the time-varying location of a continuously moving sound. Specifically, we found that …

There are functional and anatomical distinctions between the neural systems involved in the
recognition of sounds in the environment and those involved in the sensorimotor guidance …

Background Nonhuman primate (NHP) models are commonly used to advance our
understanding of brain function and organization. However, to date, they have offered few …

Cortical connectivity conforms to a series of organizing principles that are common across
species. Spatial proximity, similar cortical type, and similar connectional profile all constitute …

The human occipito-temporal region hMT+/V5 is well known for processing visual motion
direction. Here, we demonstrate that hMT+/V5 also represents the direction of auditory …

In humans, the occipital middle-temporal region (hMT+/V5) specializes in the processing of
visual motion, while the planum temporale (hPT) specializes in auditory motion processing …

It is of increasing practical interest to be able to decode the spatial characteristics of an
auditory scene from electrophysiological signals. However, the cortical representation of …