| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Karla Monzalvo, Ghislaine Dehaene-Lambert. How reading acquisition changes children's spoken language network. Brain and language. vol 127. issue 3. 2014-07-28. PMID:24216407. |
a year of reading instruction was nevertheless sufficient to increase activation in regions involved in phonological representations (posterior superior temporal region) and sentence integration (temporal pole and pars orbitalis). |
2014-07-28 |
2023-08-12 |
Not clear |
| HweeLing Lee, Uta Noppene. Physical and perceptual factors shape the neural mechanisms that integrate audiovisual signals in speech comprehension. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 31. issue 31. 2011-10-11. PMID:21813693. |
comparing audiovisual integration (interactions) of speech, sws-s, and sws-n revealed a posterior-anterior processing gradient within the left superior temporal sulcus/gyrus (sts/stg): bilateral posterior sts/stg integrated audiovisual inputs regardless of spectrotemporal structure or speech percept; in left mid-sts, the integration profile was primarily determined by the spectrotemporal structure of the signals; more anterior sts regions discarded spectrotemporal structure and integrated audiovisual signals constrained by stimulus intelligibility and the availability of linguistic representations. |
2011-10-11 |
2023-08-12 |
human |
| Christian F Altmann, Cícero Gomes de Oliveira Júnior, Linda Heinemann, Jochen Kaise. Processing of spectral and amplitude envelope of animal vocalizations in the human auditory cortex. Neuropsychologia. vol 48. issue 10. 2010-11-22. PMID:20493891. |
our findings suggest involvement of primary auditory areas in the representation of spectral cues and encoding of general spectro-temporal features of natural sounds in non-primary posterior and lateral superior temporal cortex. |
2010-11-22 |
2023-08-12 |
human |
| John F Smiley, Arnaud Falchie. Multisensory connections of monkey auditory cerebral cortex. Hearing research. vol 258. issue 1-2. 2010-02-05. PMID:19619628. |
potential sources of visual responses include peripheral field representations of areas v2 and prostriata, as well as the superior temporal polysensory area (stp) in the superior temporal sulcus, and the magnocellular medial geniculate thalamic nucleus (mgm). |
2010-02-05 |
2023-08-12 |
monkey |
| Bernhard Ross, Joel S Snyder, Meaghan Aalto, Kelly L McDonald, Benjamin J Dyson, Bruce Schneider, Claude Alai. Neural encoding of sound duration persists in older adults. NeuroImage. vol 47. issue 2. 2009-09-03. PMID:19393323. |
the time courses of cortical activity from bilateral sources in superior temporal planes showed specific differences related to the sound offsets indicating the neural representation of onset and offset markers as one dimension of the neural code for sound duration. |
2009-09-03 |
2023-08-12 |
human |
| Andreas M Rauschecker, Abbie Pringle, Kate E Watkin. Changes in neural activity associated with learning to articulate novel auditory pseudowords by covert repetition. Human brain mapping. vol 29. issue 11. 2008-12-30. PMID:17948887. |
the changes most likely reflect more efficient representation of the articulation patterns of these novel words in two connected systems, one involved in the perception of pseudoword stimuli (in the left superior temporal cortex) and one for processing the output of speech (in the left frontal cortex). |
2008-12-30 |
2023-08-12 |
human |
| Timothy J Andrews, Michael P Ewban. Distinct representations for facial identity and changeable aspects of faces in the human temporal lobe. NeuroImage. vol 23. issue 3. 2005-01-19. PMID:15528090. |
these results reveal a largely size-invariant neural representation in the inferior temporal lobe that could be involved in the recognition of facial identity, and a separate face-selective region in the superior temporal lobe that could be used to detect changeable aspects of faces. |
2005-01-19 |
2023-08-12 |
human |
| Takahiro Sekiguchi, Sachiko Koyama, Ryusuke Kakig. The effect of phonological repetition on cortical magnetic responses evoked by visually presented words. Journal of cognitive neuroscience. vol 16. issue 7. 2004-12-14. PMID:15453977. |
this result suggests that the activity in the left superior temporal cortical area is associated with access to the phonological representation of words. |
2004-12-14 |
2023-08-12 |
human |
| Tjeerd Jellema, David I Perret. Cells in monkey STS responsive to articulated body motions and consequent static posture: a case of implied motion? Neuropsychologia. vol 41. issue 13. 2003-12-16. PMID:14527537. |
these representations could play a role in producing the activity in the medial temporal/medial superior temporal (v5(mt)/mst) areas reported in fmri studies when subjects view still photographs of people in action. |
2003-12-16 |
2023-08-12 |
human |
| W J Kuo, T C Yeh, J R Duann, Y T Wu, L T Ho, D Hung, O J Tzeng, J C Hsie. A left-lateralized network for reading Chinese words: a 3 T fMRI study. Neuroreport. vol 12. issue 18. 2002-03-18. PMID:11742227. |
the orchestration of the middle frontal cortex, superior temporal cortex, superior parietal cortex, basal temporal area and extrastriate cortices of the left hemisphere may manifest the particularity of the central representation of simple word naming in chinese. |
2002-03-18 |
2023-08-12 |
human |
| K Itoh, M Yumoto, A Uno, T Kurauchi, K Kag. Temporal stream of cortical representation for auditory spatial localization in human hemispheres. Neuroscience letters. vol 292. issue 3. 2000-11-09. PMID:11018315. |
upon presenting a binaural sound, the first representations were found in the middle frontal region as well as the superior temporal region of the right hemisphere approximately 19 ms after the stimulation, but their patterns differed. |
2000-11-09 |
2023-08-12 |
human |
| K Lauwers, R Saunders, R Vogels, E Vandenbussche, G A Orba. Impairment in motion discrimination tasks is unrelated to amount of damage to superior temporal sulcus motion areas. The Journal of comparative neurology. vol 420. issue 4. 2000-05-31. PMID:10805926. |
the small lesion was restricted to the peripheral representation of mt/v5 but included v4t, whereas the large lesion included all of mt/v5 and the medial superior temporal (mst) area as well as substantial parts of the floor of the superior temporal (fst) area. |
2000-05-31 |
2023-08-12 |
monkey |
| G F Potts, J Dien, A L Hartry-Speiser, L M McDougal, D M Tucke. Dense sensor array topography of the event-related potential to task-relevant auditory stimuli. Electroencephalography and clinical neurophysiology. vol 106. issue 5. 1998-08-13. PMID:9680158. |
the n2b, which occurred only to targets in the active condition, and was the first index of target detection, had a scalp distribution consistent with generation in frontal and superior temporal cortex, suggesting activity in cortical areas of selective attention and auditory stimulus representation. |
1998-08-13 |
2023-08-12 |
Not clear |
| C D Frith, K J Friston, P F Liddle, R S Frackowia. A PET study of word finding. Neuropsychologia. vol 29. issue 12. 1992-04-01. PMID:1791928. |
we suggest that the superior temporal regions are the site of stored word representations and that inhibitory modulation of these areas by the left prefrontal cortex is the basis of intrinsic word generation. |
1992-04-01 |
2023-08-11 |
human |
| M M Merzenich, J F Brugg. Representation of the cochlear partition of the superior temporal plane of the macaque monkey. Brain research. vol 50. issue 2. 1973-07-19. PMID:4196192. |
representation of the cochlear partition of the superior temporal plane of the macaque monkey. |
1973-07-19 |
2023-08-11 |
monkey |