Models of face processing suggest that the neural response in different face regions is selective for higher-level attributes of the face, such as identity and expression. However, it remains unclear to what extent the response in these regions can also be explained by more basic organizing principles. Here, we used functional magnetic resonance imaging multivariate pattern analysis (fMRI-MVPA) to ask whether spatial patterns of response in the core face regions (occipital face area – OFA, fusiform face area – FFA, superior temporal sulcus – STS) can be predicted across different participants by lower level properties of the stimulus. First, we compared the neural response to face identity and viewpoint, by showing images of different ident...
An intriguing region of human visual cortex (the fusiform face area; FFA) responds selectively to fa...
fMRI studies have reported three regions in human ventral visual cortex that respond selectively to ...
Face processing relies on a distributed, patchy network of cortical regions in the temporal and fron...
Models of face processing suggest that the neural response in different face regions is selective fo...
fMRI (functional magnetic resonance imaging) studies on humans have shown a cortical area, the fusif...
A whole network of brain areas showing larger response to faces than other visual stimuli has been i...
Faces contain a variety of information such as one’s identity and expression. One prevailing model s...
Several regions of the human brain respond more strongly to faces than to other visual stimuli, such...
Two regions in the occipito-temporal cortex respond more strongly to faces than to objects and are t...
Numerous functional magnetic resonance imaging (fMRI) studies have identified multiple cortical regi...
Numerous functional magnetic resonance imaging (fMRI) studies have identified multiple cortical regi...
AbstractAlthough different brain regions are widely considered to be involved in the recognition of ...
Behavioral research indicates that successful face individuation is associated with sensitivity to s...
SummaryUnderstanding the neural mechanisms underlying object recognition is one of the fundamental c...
The neural basis of face recognition has been investigated extensively. Using fMRI, several regions ...
An intriguing region of human visual cortex (the fusiform face area; FFA) responds selectively to fa...
fMRI studies have reported three regions in human ventral visual cortex that respond selectively to ...
Face processing relies on a distributed, patchy network of cortical regions in the temporal and fron...
Models of face processing suggest that the neural response in different face regions is selective fo...
fMRI (functional magnetic resonance imaging) studies on humans have shown a cortical area, the fusif...
A whole network of brain areas showing larger response to faces than other visual stimuli has been i...
Faces contain a variety of information such as one’s identity and expression. One prevailing model s...
Several regions of the human brain respond more strongly to faces than to other visual stimuli, such...
Two regions in the occipito-temporal cortex respond more strongly to faces than to objects and are t...
Numerous functional magnetic resonance imaging (fMRI) studies have identified multiple cortical regi...
Numerous functional magnetic resonance imaging (fMRI) studies have identified multiple cortical regi...
AbstractAlthough different brain regions are widely considered to be involved in the recognition of ...
Behavioral research indicates that successful face individuation is associated with sensitivity to s...
SummaryUnderstanding the neural mechanisms underlying object recognition is one of the fundamental c...
The neural basis of face recognition has been investigated extensively. Using fMRI, several regions ...
An intriguing region of human visual cortex (the fusiform face area; FFA) responds selectively to fa...
fMRI studies have reported three regions in human ventral visual cortex that respond selectively to ...
Face processing relies on a distributed, patchy network of cortical regions in the temporal and fron...