| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Deborah Zaitchik, Caren Walker, Saul Miller, Pete LaViolette, Eric Feczko, Bradford C Dickerso. Mental state attribution and the temporoparietal junction: an fMRI study comparing belief, emotion, and perception. Neuropsychologia. vol 48. issue 9. 2010-10-20. PMID:20435051. |
this is especially surprising with respect to sts, since it is widely reported in the literature to mediate the detection of referential states--among them emotions and perceptions--rather than the inference of beliefs. |
2010-10-20 |
2023-08-12 |
Not clear |
| Marius V Peelen, Anthony P Atkinson, Patrik Vuilleumie. Supramodal representations of perceived emotions in the human brain. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 30. issue 30. 2010-08-20. PMID:20668196. |
a whole-brain searchlight analysis revealed modality-independent but emotion category-specific activity patterns in medial prefrontal cortex (mpfc) and left superior temporal sulcus (sts). |
2010-08-20 |
2023-08-12 |
human |
| Marius V Peelen, Anthony P Atkinson, Patrik Vuilleumie. Supramodal representations of perceived emotions in the human brain. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 30. issue 30. 2010-08-20. PMID:20668196. |
we suggest that mpfc and sts represent perceived emotions at an abstract, modality-independent level, and thus play a key role in the understanding and categorization of others' emotional mental states. |
2010-08-20 |
2023-08-12 |
human |
| Katrin R Scharpf, Julia Wendt, Martin Lotze, Alfons O Ham. The brain's relevance detection network operates independently of stimulus modality. Behavioural brain research. vol 210. issue 1. 2010-06-30. PMID:20122966. |
the amygdala, the anterior insula, the sts, and the ofc showed increased activation during processing of emotional as well as social stimuli independent of the sensory modality in which the stimuli were presented. |
2010-06-30 |
2023-08-12 |
human |
| Brent C Vander Wyk, Caitlin M Hudac, Elizabeth J Carter, David M Sobel, Kevin A Pelphre. Action understanding in the superior temporal sulcus region. Psychological science. vol 20. issue 6. 2010-04-14. PMID:19422619. |
this functional magnetic resonance imaging experiment examined activity in the sts region as participants viewed actions that were congruent or incongruent with intentions established by a previous emotional context. |
2010-04-14 |
2023-08-12 |
human |
| Benjamin Kreifelts, Thomas Ethofer, Thomas Shiozawa, Wolfgang Grodd, Dirk Wildgrube. Cerebral representation of non-verbal emotional perception: fMRI reveals audiovisual integration area between voice- and face-sensitive regions in the superior temporal sulcus. Neuropsychologia. vol 47. issue 14. 2010-01-25. PMID:19596021. |
using functional magnetic resonance imaging (fmri), we demonstrated that the neural representations of the audiovisual integration of non-verbal emotional signals, voice sensitivity and face sensitivity are located in different parts of the sts with maximum voice sensitivity in the trunk section and maximum face sensitivity in the posterior terminal ascending branch. |
2010-01-25 |
2023-08-12 |
human |
| Benjamin Kreifelts, Thomas Ethofer, Thomas Shiozawa, Wolfgang Grodd, Dirk Wildgrube. Cerebral representation of non-verbal emotional perception: fMRI reveals audiovisual integration area between voice- and face-sensitive regions in the superior temporal sulcus. Neuropsychologia. vol 47. issue 14. 2010-01-25. PMID:19596021. |
the audiovisual integration area for emotional signals is located at the bifurcation of the sts at an overlap of voice- and face-sensitive regions. |
2010-01-25 |
2023-08-12 |
human |
| Benjamin Kreifelts, Thomas Ethofer, Thomas Shiozawa, Wolfgang Grodd, Dirk Wildgrube. Cerebral representation of non-verbal emotional perception: fMRI reveals audiovisual integration area between voice- and face-sensitive regions in the superior temporal sulcus. Neuropsychologia. vol 47. issue 14. 2010-01-25. PMID:19596021. |
in summary, our findings evidence a functional subdivision of the sts into modules subserving the processing of different aspects of social communication, here exemplified in human voices and faces and audiovisual integration of emotional signals from these sources and suggest a possible interaction of the underlying voice- and face-sensitive neuronal populations during the formation of the audiovisual emotional percept. |
2010-01-25 |
2023-08-12 |
human |
| Jorge Moll, Ricardo de Oliveira-Souza, Griselda J Garrido, Ivanei E Bramati, Egas M A Caparelli-Daquer, Mirella L M F Paiva, Roland Zahn, Jordan Grafma. The self as a moral agent: linking the neural bases of social agency and moral sensitivity. Social neuroscience. vol 2. issue 3-4. 2008-12-12. PMID:18633822. |
compared to emotionally neutral agency, different categories of moral emotions led to distinct activation patterns: (1) prosocial emotions (guilt, embarrassment, compassion) activated the anterior medial pfc and sts, with (2) empathic emotions (guilt and compassion) additionally recruiting the mesolimbic pathway; (3) other-critical emotions (disgust and indignation) were associated with activation of the amygdala-parahippocampal and fusiform areas. |
2008-12-12 |
2023-08-12 |
human |
| Arieta Chouchourelou, Toshihiko Matsuka, Kent Harber, Maggie Shiffra. The visual analysis of emotional actions. Social neuroscience. vol 1. issue 1. 2008-12-10. PMID:18633776. |
to the extent that amygdala activity influences sts activity, one would expect to find systematic differences in the visual detection of emotional actions. |
2008-12-10 |
2023-08-12 |
human |
| Karen Badger, David Royse, Carlton Crai. Hospital social workers and indirect trauma exposure: an exploratory study of contributing factors. Health & social work. vol 33. issue 1. 2008-04-23. PMID:18326451. |
this article explores the predictive ability of empathy (measured by the interpersonal reactivity index), emotional separation (measured by the maintenance of emotional separation scale), occupational stress (measured by the work-related strain inventory), and social support (measured by the multidimensional scale of perceived social support) on secondary traumatic stress (sts) (measured by the secondary traumatic stress scale) in hospital social workers. |
2008-04-23 |
2023-08-12 |
Not clear |
| Karen Badger, David Royse, Carlton Crai. Hospital social workers and indirect trauma exposure: an exploratory study of contributing factors. Health & social work. vol 33. issue 1. 2008-04-23. PMID:18326451. |
emotional separation and occupational stress were the strongest predictors of sts, explaining 49 percent of the variance, which suggests that hospital social workers need to be able to emotionally differentiate during work with patients and families and manage organizational stressors to minimize indirect trauma reactions. |
2008-04-23 |
2023-08-12 |
Not clear |
| Tien-Wen Lee, Raymond J Dolan, Hugo D Critchle. Controlling emotional expression: behavioral and neural correlates of nonimitative emotional responses. Cerebral cortex (New York, N.Y. : 1991). vol 18. issue 1. 2008-02-25. PMID:17483530. |
neuroimaging revealed activation of distributed brain regions including anterior right inferior frontal gyrus (brain area [ba] 47), supplementary motor area (facial area), posterior superior temporal sulcus (sts), and right anterior insula during emotion expression-associated interference. |
2008-02-25 |
2023-08-12 |
Not clear |
| Tien-Wen Lee, Raymond J Dolan, Hugo D Critchle. Controlling emotional expression: behavioral and neural correlates of nonimitative emotional responses. Cerebral cortex (New York, N.Y. : 1991). vol 18. issue 1. 2008-02-25. PMID:17483530. |
individual differences in empathy and emotion regulatory tendency predicted the magnitude of eei-evoked regional activity with ba 47 and sts. |
2008-02-25 |
2023-08-12 |
Not clear |
| Virginie Beaucousin, Anne Lacheret, Marie-Renée Turbelin, Michel Morel, Bernard Mazoyer, Nathalie Tzourio-Mazoye. FMRI study of emotional speech comprehension. Cerebral cortex (New York, N.Y. : 1991). vol 17. issue 2. 2007-02-28. PMID:16525130. |
when affective prosody was present, additional rightward activations of the human-selective voice area and the posterior part of sts were observed, corresponding to the processing of speaker's voice emotional content. |
2007-02-28 |
2023-08-12 |
human |
| Robert W Motta, Caren L Newman, Kerri L Lombardo, Matthew A Silverma. Objective assessment of secondary trauma. International journal of emergency mental health. vol 6. issue 2. 2004-09-21. PMID:15298077. |
the sts demonstrated strong psychometric characteristics and was significantly correlated with known measures of emotional distress and dissociation. |
2004-09-21 |
2023-08-12 |
human |
| T L Znajda, J S Wunder, R S Bell, A M Davi. Gender issues in patients with extremity soft-tissue sarcoma: a pilot study. Cancer nursing. vol 22. issue 2. 1999-05-20. PMID:10217026. |
recent study has identified physical, emotional, and psychological factors associated with a diagnosis of malignancy, but the tissues affecting the sts patient population may differ from those of more common cancers due to physical disability secondary to treatment. |
1999-05-20 |
2023-08-12 |
Not clear |
| D I Perrett, E T Rolls, W Caa. Visual neurones responsive to faces in the monkey temporal cortex. Experimental brain research. vol 47. issue 3. 1982-12-18. PMID:7128705. |
these findings indicate that explanations in terms of arousal, emotional or motor reactions, simple visual feature sensitivity or receptive fields are insufficient to account for the selective responses to faces and face features observed in this population of sts neurones. |
1982-12-18 |
2023-08-12 |
human |