| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Heather L Kosakowski, Michael A Cohen, Lyneé Herrera, Isabel Nichoson, Nancy Kanwisher, Rebecca Sax. Cortical Face-Selective Responses Emerge Early in Human Infancy. eNeuro. 2024-06-13. PMID:38871455. |
in human adults, multiple cortical regions respond robustly to faces, including the occipital face area (ofa) and fusiform face area (ffa), implicated in face perception, and the superior temporal sulcus (sts) and medial prefrontal cortex (mpfc), implicated in higher level social functions. |
2024-06-13 |
2024-06-16 |
human |
| Silvia Gobbo, Carlotta Lega, Angelica De Sandi, Roberta Dain. The role of preSMA and STS in face recognition: A transcranial magnetic stimulation (TMS) study. Neuropsychologia. 2024-03-30. PMID:38555065. |
current models propose that facial recognition is mediated by two independent yet interacting anatomo-functional systems: one processing facial features mainly mediated by the fusiform face area and the other involved in the extraction of dynamic information from faces, subserved by superior temporal sulcus (sts). |
2024-03-30 |
2024-04-02 |
human |
| Ali Momen, Kurt Hugenberg, Eva Wies. Robots engage face-processing less strongly than humans. Frontiers in neuroergonomics. vol 3. 2024-01-18. PMID:38235446. |
robot faces often differ from human faces in terms of their facial features (e.g., lack of eyebrows) and spatial relationships between these features (e.g., disproportionately large eyes), which can influence the degree to which social brain [i.e., fusiform face area (ffa), superior temporal sulcus (sts); haxby et al., 2000] areas process them as social individuals that can be discriminated from other agents in terms of their perceptual features and person attributes. |
2024-01-18 |
2024-01-20 |
human |
| Jon Rodríguez-Antigüedad, Saül Martínez-Horta, Andrea Horta-Barba, Arnau Puig-Davi, Antonia Campolongo, Frederic Sampedro, Helena Bejr-Kasem, Juan Marín-Lahoz, Javier Pagonabarraga, Jaime Kulisevsk. Facial emotion recognition deficits are associated with hypomimia and related brain correlates in Parkinson's disease. Journal of neural transmission (Vienna, Austria : 1996). 2024-01-11. PMID:38206439. |
we found significant correlation between hypomimia, ef disgust (r = -0.242, p = 0.022) and ef happiness (r = -0.264, p = 0.012); an independent reduction in cortical thickness (cth) in the postcentral gyrus, insula, middle and superior temporal gyri, supramarginal gyrus, banks of the superior temporal sulcus, bilateral fusiform gyri, entorhinal cortex, parahippocampal gyrus, inferior and superior parietal cortex, and right cuneus and precuneus; and multiple correlations between negative emotions such as ef disgust or ef anger and a reduced cth in fronto-temporo-parietal regions. |
2024-01-11 |
2024-01-13 |
human |
| Nestor Zaragoza-Jimenez, Hauke Niehaus, Ina Thome, Christoph Vogelbacher, Gabriele Ende, Inge Kamp-Becker, Dominik Endres, Andreas Janse. Modeling face recognition in the predictive coding framework: A combined computational modeling and functional imaging study. Cortex; a journal devoted to the study of the nervous system and behavior. vol 168. 2023-10-13. PMID:37832490. |
more specifically, brain activity in the superior temporal sulcus (sts) varied with contextual familiarity, whereas activity in the fusiform face area (ffa) covaried with the prediction error parameter that updated facial familiarity. |
2023-10-13 |
2023-10-15 |
Not clear |
| Jason J S Barto. Face processing in the temporal lobe. Handbook of clinical neurology. vol 187. 2022-08-14. PMID:35964972. |
while early human neuroimaging work suggested a core face network consisting of the occipital face area, fusiform face area, and posterior superior temporal sulcus, studies in both humans and monkeys show a system of face patches stretching from posterior to anterior in both the superior temporal sulcus and inferotemporal cortex. |
2022-08-14 |
2023-08-14 |
human |
| Di Wu, Pan Zhang, Na Liu, Kewei Sun, Wei Xia. Effects of High-Definition Transcranial Direct Current Stimulation Over the Left Fusiform Face Area on Face View Discrimination Depend on the Individual Baseline Performance. Frontiers in neuroscience. vol 15. 2021-12-07. PMID:34867146. |
early neuroimaging studies have identified the involvement of the left fusiform face area (ffa) and the left superior temporal sulcus (sts) in face view discrimination. |
2021-12-07 |
2023-08-13 |
human |
| Thomas Murray, Justin O'Brien, Noam Sagiv, Lúcia Garrid. The role of stimulus-based cues and conceptual information in processing facial expressions of emotion. Cortex; a journal devoted to the study of the nervous system and behavior. vol 144. 2021-11-11. PMID:34666297. |
in study 2, 30 participants viewed facial expressions while undergoing fmri, allowing for the measurement of brain representational geometries of facial expressions of emotion in three core face-responsive regions (the fusiform face area, occipital face area, and superior temporal sulcus), and a region involved in theory of mind (medial prefrontal cortex). |
2021-11-11 |
2023-08-13 |
human |
| Nian Liu, Yuan Xiao, Wenjing Zhang, Biqiu Tang, Jiaxin Zeng, Na Hu, Shah Chandan, Qiyong Gong, Su Lu. Characteristics of gray matter alterations in never-treated and treated chronic schizophrenia patients. Translational psychiatry. vol 10. issue 1. 2021-06-18. PMID:32398765. |
relative to controls, both treated and never-treated chronic schizophrenia patients showed reduced gm mainly involving the bilateral medial and rostral middle frontal, left banks superior temporal sulcus, left fusiform, and left pericalcarine cortex and increased in the left cuneus. |
2021-06-18 |
2023-08-13 |
Not clear |
| Gary C-W Shyi, Peter K-H Cheng, S-T Tina Huang, C-C Lee, Felix F-S Tsai, Wan-Ting Hsieh, Becky Y-C Che. Predicting Performances on Processing and Memorizing East Asian Faces from Brain Activities in Face-Selective Regions: A Neurocomputational Approach. Frontiers in human neuroscience. vol 14. 2020-09-28. PMID:32848662. |
for more than two decades, a network of face-selective brain regions has been identified as the core system for face processing, including occipital face area (ofa), fusiform face area (ffa), and posterior region of superior temporal sulcus (psts). |
2020-09-28 |
2023-08-13 |
human |
| S Maher, T Ekstrom, D Ongur, D L Levy, D J Norton, L D Nickerson, Y Che. Functional disconnection between the visual cortex and right fusiform face area in schizophrenia. Schizophrenia research. vol 209. 2020-08-24. PMID:31126803. |
we used functional magnetic resonance imaging (fmri) to characterize resting state functional connectivity between an independent component analysis (ica)-defined early visual cortical network (corresponding to regions in v1, v2, v3) and a priori defined face-processing regions (fusiform face area [ffa], occipital face area [ofa], superior temporal sulcus [sts] and amygdala) using dual regression in 20 schizophrenia patients and 26 healthy controls. |
2020-08-24 |
2023-08-13 |
Not clear |
| Tessa R Flack, Richard J Harris, Andrew W Young, Timothy J Andrew. Symmetrical Viewpoint Representations in Face-Selective Regions Convey an Advantage in the Perception and Recognition of Faces. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 39. issue 19. 2020-06-11. PMID:30842248. |
within the face regions, patterns of neural response to symmetrical views (-45 and 45° or -90 and 90°) were more similar than responses to nonsymmetrical views in the fusiform face area and superior temporal sulcus, but not in the occipital face area. |
2020-06-11 |
2023-08-13 |
human |
| Xiaojing Wang, Jin Gu, Junhai Xu, Xianglin Li, Junzu Geng, Bin Wang, Baolin Li. Decoding natural scenes based on sounds of objects within scenes using multivariate pattern analysis. Neuroscience research. vol 148. 2020-03-20. PMID:30513353. |
we found that patterns evoked by scenes could be predicted with patterns evoked by sounds of objects within the scenes in the posterior fusiform area (pf), lateral occipital area (lo) and superior temporal sulcus (sts). |
2020-03-20 |
2023-08-13 |
Not clear |
| Maria A Bobes, Agustin Lage-Castellanos, Ela I Olivares, Jhoanna Perez Hidalgo-Gato, Jaime Iglesias, Ana Maria Castro-Laguardia, Pedro Valdes-Sos. ERP Source Analysis Guided by fMRI During Familiar Face Processing. Brain topography. vol 32. issue 4. 2019-12-06. PMID:29464518. |
different areas contributed to the generation of the early and middle erps elicited by unfamiliar faces: fusiform (fus), inferior occipital, superior temporal sulcus and the posterior cingulate (pc) cortices. |
2019-12-06 |
2023-08-13 |
Not clear |
| Katja Weibert, Tessa R Flack, Andrew W Young, Timothy J Andrew. Patterns of neural response in face regions are predicted by low-level image properties. Cortex; a journal devoted to the study of the nervous system and behavior. vol 103. 2019-10-11. PMID:29655043. |
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. |
2019-10-11 |
2023-08-13 |
human |
| Wei He, Blake W Johnso. Development of face recognition: Dynamic causal modelling of MEG data. Developmental cognitive neuroscience. vol 30. 2019-06-10. PMID:29197727. |
dynamic causal modelling (dcm) of the m250 in both age groups tested the effects of face repetition within the core face network including the occipital face area (ofa), the fusiform face area (ffa), and the superior temporal sulcus (sts). |
2019-06-10 |
2023-08-13 |
Not clear |
| Molly R LaPoint, Jasmeer P Chhatwal, Jorge Sepulcre, Keith A Johnson, Reisa A Sperling, Aaron P Schult. The association between tau PET and retrospective cortical thinning in clinically normal elderly. NeuroImage. vol 157. 2018-05-28. PMID:28545932. |
significant local relationships were seen in right superior temporal, middle temporal, temporal pole, and fusiform, as well as the left cuneus and banks of the left superior temporal sulcus. |
2018-05-28 |
2023-08-13 |
Not clear |
| Stefano Anzellotti, Dorit Kliemann, Nir Jacoby, Rebecca Sax. Directed network discovery with dynamic network modelling. Neuropsychologia. vol 99. 2018-02-20. PMID:28215697. |
in this article, we outline the functioning of dnm, we validate dnm in simulated data for which the ground truth is known, and we report an example of its application to the investigation of influences between regions during emotion recognition, revealing top-down influences from brain regions encoding abstract representations of emotions (medial prefrontal cortex and superior temporal sulcus) onto regions engaged in the perceptual analysis of facial expressions (occipital face area and fusiform face area) when participants are asked to switch between reporting the emotional valence and the age of a face. |
2018-02-20 |
2023-08-13 |
human |
| Aiden E G F Arnold, Giuseppe Iaria, Vina M Goghar. Efficacy of identifying neural components in the face and emotion processing system in schizophrenia using a dynamic functional localizer. Psychiatry research. Neuroimaging. vol 248. 2016-10-07. PMID:26792586. |
fusiform face area, occipital face area, superior temporal sulcus), and regions within an extended system (e.g. |
2016-10-07 |
2023-08-13 |
human |
| Hagar Goldberg, Andrea Christensen, Tamar Flash, Martin A Giese, Rafael Malac. Brain activity correlates with emotional perception induced by dynamic avatars. NeuroImage. vol 122. 2016-07-21. PMID:26220746. |
our results revealed robust brain selectivity to emotional compared to neutral gait stimuli in brain regions which are involved in emotion and biological motion processing, such as the extrastriate body area (eba), fusiform body area (fba), superior temporal sulcus (sts), and the amygdala (amg). |
2016-07-21 |
2023-08-13 |
human |