| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Remus Oşan, Liping Zhu, Shy Shoham, Joe Z Tsie. Subspace projection approaches to classification and visualization of neural network-level encoding patterns. PloS one. vol 2. issue 5. 2010-04-29. PMID:17476326. |
our analyses of hippocampal data recorded during episodic memory events and cortical data simulated during face perception or arm movements illustrate how low-dimensional encoding subspaces can reveal the existence of network-level ensemble representations. |
2010-04-29 |
2023-08-12 |
Not clear |
| Naotsugu Tsuchiya, Hiroto Kawasaki, Hiroyuki Oya, Matthew A Howard, Ralph Adolph. Decoding face information in time, frequency and space from direct intracranial recordings of the human brain. PloS one. vol 3. issue 12. 2009-01-23. PMID:19065268. |
a dominant theory of face perception postulates independent representations of invariant aspects of faces (e.g., identity) in ventral temporal cortex including the fusiform gyrus, and changeable aspects of faces (e.g., emotion) in lateral temporal cortex including the superior temporal sulcus. |
2009-01-23 |
2023-08-12 |
human |
| M Ida Gobbini, James V Haxb. Neural systems for recognition of familiar faces. Neuropsychologia. vol 45. issue 1. 2007-02-26. PMID:16797608. |
the amygdala and the insula, structures that are involved in the representation of emotion, also are part of the distributed network of areas that are modulated by familiarity, reflecting the role of emotion in face recognition. |
2007-02-26 |
2023-08-12 |
Not clear |
| Alumit Ishai, Elena Yag. Recognition memory of newly learned faces. Brain research bulletin. vol 71. issue 1-3. 2007-02-01. PMID:17113943. |
our findings suggest that face recognition memory is mediated by stimulus-specific representations stored in extrastriate regions; parietal and prefrontal regions where old and new items are classified; and the hippocampus where veridical memory traces are recovered. |
2007-02-01 |
2023-08-12 |
human |
| Barak Blumenfeld, Son Preminger, Dov Sagi, Misha Tsodyk. Dynamics of memory representations in networks with novelty-facilitated synaptic plasticity. Neuron. vol 52. issue 2. 2007-01-05. PMID:17046699. |
the model predicts that memory representations should be sensitive to learning order, consistent with recent psychophysical studies of face recognition and electrophysiological experiments on hippocampal place cells. |
2007-01-05 |
2023-08-12 |
Not clear |
| Galia Avidan, Uri Hasson, Rafael Malach, Marlene Behrman. Detailed exploration of face-related processing in congenital prosopagnosia: 2. Functional neuroimaging findings. Journal of cognitive neuroscience. vol 17. issue 7. 2005-10-27. PMID:16102242. |
the absence of a bold-behavioral correlation (profound behavioral deficit, normal face-related activation in the ventral occipito-temporal cortex) challenges existing accounts of face representation, and suggests that activation in these cortical regions per se is not sufficient to ensure intact face processing. |
2005-10-27 |
2023-08-12 |
human |
| Galit Yovel, Jerre Levy, Marcia Grabowecky, Ken A Palle. Neural correlates of the left-visual-field superiority in face perception appear at multiple stages of face processing. Journal of cognitive neuroscience. vol 15. issue 3. 2003-06-27. PMID:12729496. |
we conclude that the two hemispheres exchange information symmetrically at early stages of face processing and together generate a shared facial representation, which is better when facial information is directly presented to the right hemisphere (rh; l faces) than to the left hemisphere (lh; r faces) and best when both hemispheres receive facial information (b faces). |
2003-06-27 |
2023-08-12 |
human |
| Patrik Vuilleumier, Christine Mohr, Nathalie Valenza, Corinne Wetzel, Theodor Landi. Hyperfamiliarity for unknown faces after left lateral temporo-occipital venous infarction: a double dissociation with prosopagnosia. Brain : a journal of neurology. vol 126. issue Pt 4. 2003-05-22. PMID:12615646. |
hyperfamiliarity for unknown faces might arise from an imbalance between reciprocal hemispheric functions in face recognition, with relative hypoactivation of left hemisphere processes but hyperactivation of right-hemisphere processes for retrieving stored associations about people, linking seen faces to representations of affective and personal relevance. |
2003-05-22 |
2023-08-12 |
human |
| B C Duchain. Developmental prosopagnosia with normal configural processing. Neuroreport. vol 11. issue 1. 2000-03-16. PMID:10683834. |
the pattern of spared and impaired face recognition indicates that this case of developmental prosopagnosia is caused by a domain-specific inability to match novel views of faces with previously derived representations. |
2000-03-16 |
2023-08-12 |
Not clear |
| P Verstichel, L Chi. [Difficulties in face identification after lesion in the left hemisphere]. Revue neurologique. vol 155. issue 11. 2000-02-08. PMID:10603638. |
left-hemisphere specific function in facial recognition enabled access to semantic-biographic store in a conscious, verbal and explicit way, after the right hemisphere had achieved basic visual analysis and activation of facial representation in memory. |
2000-02-08 |
2023-08-12 |
Not clear |
| M R Polster, S Z Rapcsa. Representations in learning new faces: evidence from prosopagnosia. Journal of the International Neuropsychological Society : JINS. vol 2. issue 3. 1997-12-30. PMID:9375190. |
we postulate further that r.j.'s poor performance on face learning tasks may be attributable to excessive reliance on a feature-based left hemisphere face processing system that operates primarily on view-specific representations. |
1997-12-30 |
2023-08-12 |
Not clear |
| J Sergent, M Ponce. From covert to overt recognition of faces in a prosopagnosic patient. Brain : a journal of neurology. vol 113 ( Pt 4). 1990-10-17. PMID:2397396. |
they suggest that (1) prosopagnosia may result from a breakdown at different levels of face-recognition processes, (2) prosopagnosia may occur in spite of normal configurational encoding of facial representations, (3) covert recognition of overtly unrecognized faces requires the integrity of perceptual processes, and (4) failure of overt face recognition reflects a disturbance in the normal interactions between pertinent memories and facial representations which thus remain meaningless. |
1990-10-17 |
2023-08-11 |
human |