| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| J D Cohen, T S Braver, R C O'Reill. A computational approach to prefrontal cortex, cognitive control and schizophrenia: recent developments and current challenges. Philosophical transactions of the Royal Society of London. Series B, Biological sciences. vol 351. issue 1346. 1997-04-11. PMID:8941963. |
in particular, we focus on refinements concerning the mechanisms underlying active maintenance of representations within pfc, and the characteristics of these representations that allow them to support the flexibility of cognitive control exhibited by normal human behaviour. |
1997-04-11 |
2023-08-12 |
human |
| J Decet. The neurophysiological basis of motor imagery. Behavioural brain research. vol 77. issue 1-2. 1996-11-18. PMID:8762158. |
this review emphasizes the importance of the prefrontal cortex and its connections to the basal ganglia in maintaining dynamic motor representations in working memory. |
1996-11-18 |
2023-08-12 |
human |
| J Decet. The neurophysiological basis of motor imagery. Behavioural brain research. vol 77. issue 1-2. 1996-11-18. PMID:8762158. |
this view fits with the general idea that the prefrontal cortex is responsible for the creation and maintenance of explicit representations that guide thought and action. |
1996-11-18 |
2023-08-12 |
human |
| L Godbout, J Doyo. Mental representation of knowledge following frontal-lobe or postrolandic lesions. Neuropsychologia. vol 33. issue 12. 1996-10-28. PMID:8745123. |
the aims of this study were to examine the role of the prefrontal cortex in the representation of familiar activities using scripts, and to compare both shallice's [phil. |
1996-10-28 |
2023-08-12 |
human |
| J E Desmedt, C Tomber. Consciousness. Electroencephalography and clinical neurophysiology. Supplement. vol 44. 1995-09-27. PMID:7649027. |
about 80 msec later, the dorsolateral prefrontal cortex discloses enhanced electrogeneses which we believe to reflect activation of somatic representations in 'working memory'. |
1995-09-27 |
2023-08-12 |
human |
| J M Clarke, E Halgren, J M Scarabin, P Chauve. Auditory and visual sensory representations in human prefrontal cortex as revealed by stimulus-evoked spike-wave complexes. Brain : a journal of neurology. vol 118 ( Pt 2). 1995-06-07. PMID:7735888. |
auditory and visual sensory representations in human prefrontal cortex as revealed by stimulus-evoked spike-wave complexes. |
1995-06-07 |
2023-08-12 |
human |
| J M Clarke, E Halgren, J M Scarabin, P Chauve. Auditory and visual sensory representations in human prefrontal cortex as revealed by stimulus-evoked spike-wave complexes. Brain : a journal of neurology. vol 118 ( Pt 2). 1995-06-07. PMID:7735888. |
we report electrophysiological evidence for auditory and visual representations in the dorsolateral prefrontal cortex, as inferred from intracerebral 'depth' recordings of focal, sensory-evoked spike-wave complexes (swc) in an epileptic patient. |
1995-06-07 |
2023-08-12 |
human |
| J M Clarke, E Halgren, J M Scarabin, P Chauve. Auditory and visual sensory representations in human prefrontal cortex as revealed by stimulus-evoked spike-wave complexes. Brain : a journal of neurology. vol 118 ( Pt 2). 1995-06-07. PMID:7735888. |
these results are consistent with electrophysiological findings in animals indicating overlapping auditory and visual representations in the dorsolateral prefrontal cortex. |
1995-06-07 |
2023-08-12 |
human |
| M T Lu, J B Preston, P L Stric. Interconnections between the prefrontal cortex and the premotor areas in the frontal lobe. The Journal of comparative neurology. vol 341. issue 3. 1994-06-24. PMID:7515081. |
third, the prefrontal cortex is interconnected with only a portion of the arm representation in three premotor areas (supplementary motor area, the caudal cingulate motor area on the ventral bank of the cingulate sulcus, and the dorsal premotor area), whereas it is interconnected with the entire arm representation in the ventral premotor area and the rostral cingulate motor area. |
1994-06-24 |
2023-08-12 |
Not clear |
| J C Vickers, A Delacourte, J H Morriso. Progressive transformation of the cytoskeleton associated with normal aging and Alzheimer's disease. Brain research. vol 594. issue 2. 1993-01-07. PMID:1450952. |
normal aging was marked by transitional pathology in layer ii of the entorhinal cortex but no neurofibrillary tangles in prefrontal cortex, whereas, in alzheimer's disease cases, layer ii entorhinal neurons had progressed to end-stage neurofibrillary tangles and the prefrontal cortex contained a high representation of transitional forms of the neurofibrillary tangle. |
1993-01-07 |
2023-08-11 |
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 |
| G Luppino, M Matelli, G Rizzolatt. Cortico-cortical connections of two electrophysiologically identified arm representations in the mesial agranular frontal cortex. Experimental brain research. vol 82. issue 1. 1991-01-31. PMID:2257908. |
in contrast, the arm representation of area 6a beta receives afferents chiefly from area f5, the prefrontal cortex and that part of cingulate sulcus which has few, if any, connections with the spinal cord. |
1991-01-31 |
2023-08-11 |
Not clear |
| J E Desmedt, C Tomber. Mapping early somatosensory evoked potentials in selective attention: critical evaluation of control conditions used for titrating by difference the cognitive P30, P40, P100 and N140. Electroencephalography and clinical neurophysiology. vol 74. issue 5. 1989-10-19. PMID:2476292. |
the evolving topographical patterns of the p100 and n140 electrogeneses, revealed by bit-mapped data, suggest complex interactions between posterior parietal and prefrontal cortex whereby the sensory information is placed into spatial coordinate systems and matched with representations of relevant objects or relationships in space for target processing in the sequential tasks. |
1989-10-19 |
2023-08-11 |
human |
| M Watanab. Prefrontal unit activity during delayed conditional Go/No-Go discrimination in the monkey. I. Relation to the stimulus. Brain research. vol 382. issue 1. 1986-12-10. PMID:3768666. |
in summary, these results indicate that primate prefrontal cortex participates in visual information processing and may code several aspects of visual stimuli including behavioral significance and mnemonic representations. |
1986-12-10 |
2023-08-11 |
monkey |
| J M Fuste. The prefrontal cortex, mediator of cross-temporal contingencies. Human neurobiology. vol 4. issue 3. 1986-01-06. PMID:3934116. |
the three have a somewhat different topographic representation within the prefrontal cortex and thus the principle of its functional heterogeneity is upheld. |
1986-01-06 |
2023-08-11 |
Not clear |
| W Frie. Cortical projections to the superior colliculus in the macaque monkey: a retrograde study using horseradish peroxidase. The Journal of comparative neurology. vol 230. issue 1. 1985-01-31. PMID:6096414. |
when intermediate and deeper layers of the colliculus were injected, labelled cells were found also in posterior parietal cortex (area 7) where they were concentrated mainly on the posterior bank of the intraparietal fissure, in inferotemporal cortex (areas 20 and 21), in auditory cortex (area 22), in the somatosensory representation sii (anterior bank of sylvian fissure, area 2), in upper insular cortex (area 14), in motor cortex (area 4), in premotor cortex (area 6), and in prefrontal cortex (area 9). |
1985-01-31 |
2023-08-12 |
monkey |