The anterior part of the macaque inferior temporal cortex, area TE, occupies a large portion of the temporal lobe and is critical for object recognition. Thus far, no relation between anatomical subdivisions of TE and neuronal selectivity has been described. Here, we present evidence that neurons selective for three-dimensional (3D) shape are concentrated in the lower bank of the superior temporal sulcus, whereas neurons in lateral TE are generally unselective for 3D shape, though equally selective for 2D shape. These findings reveal that TE consists of at least two distinct areas, one of which processes a specific object property.status: publishe
Horizontal binocular disparity is a powerful depth cue, both for relative and absolute depth informa...
SummaryInferotemporal cortex (IT) has long been studied as a single pathway dedicated to object visi...
The primate visual system extracts object shape information for object recognition in the ventral vi...
Neurons in the rostral lower bank of the superior temporal sulcus (TEs), part of the inferior tempor...
Motion is a potent cue for the perception of three-dimensional (3D) shape in primates, but little is...
The inferior temporal (IT) cortex in monkeys plays a central role in visual object recognition and l...
AbstractBackground: The inferior temporal cortex (IT) of the monkey has long been known to play an e...
We perceive real-world objects as three-dimensional (3D), yet it is unknown which brain area underli...
SummaryWe perceive real-world objects as three-dimensional (3D), yet it is unknown which brain area ...
The neural mechanisms of stereoscopic 3D shape perception have only recently been investigated. Here...
SummaryOne of the fundamental goals of neuroscience is to understand how perception arises from the ...
Anatomical studies indicate that area F5 in the macaque ventral premotor cortex consists of three di...
Humans are able to recognize shapes even when they are partially occluded by another pattern. We det...
The macaque anterior intraparietal area (AIP) is crucial for visually guided grasping. AIP neurons r...
AbstractNeurons in the rostral lower bank of the superior temporal sulcus (TEs), part of the inferio...
Horizontal binocular disparity is a powerful depth cue, both for relative and absolute depth informa...
SummaryInferotemporal cortex (IT) has long been studied as a single pathway dedicated to object visi...
The primate visual system extracts object shape information for object recognition in the ventral vi...
Neurons in the rostral lower bank of the superior temporal sulcus (TEs), part of the inferior tempor...
Motion is a potent cue for the perception of three-dimensional (3D) shape in primates, but little is...
The inferior temporal (IT) cortex in monkeys plays a central role in visual object recognition and l...
AbstractBackground: The inferior temporal cortex (IT) of the monkey has long been known to play an e...
We perceive real-world objects as three-dimensional (3D), yet it is unknown which brain area underli...
SummaryWe perceive real-world objects as three-dimensional (3D), yet it is unknown which brain area ...
The neural mechanisms of stereoscopic 3D shape perception have only recently been investigated. Here...
SummaryOne of the fundamental goals of neuroscience is to understand how perception arises from the ...
Anatomical studies indicate that area F5 in the macaque ventral premotor cortex consists of three di...
Humans are able to recognize shapes even when they are partially occluded by another pattern. We det...
The macaque anterior intraparietal area (AIP) is crucial for visually guided grasping. AIP neurons r...
AbstractNeurons in the rostral lower bank of the superior temporal sulcus (TEs), part of the inferio...
Horizontal binocular disparity is a powerful depth cue, both for relative and absolute depth informa...
SummaryInferotemporal cortex (IT) has long been studied as a single pathway dedicated to object visi...
The primate visual system extracts object shape information for object recognition in the ventral vi...