| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Banu Ahtam, Sven Braeutigam, Anthony Baile. Semantic Processing in Autism Spectrum Disorders Is Associated With the Timing of Language Acquisition: A Magnetoencephalographic Study. Frontiers in human neuroscience. vol 14. 2020-09-28. PMID:32754020. |
the reduced sensitivity to semantic context in individuals with asd and language delay was accompanied by strong right hemisphere lateralization at early and n400 latencies; such strong activity was not observed in td individuals and individuals with asd without a history of language delay at either latency. |
2020-09-28 |
2023-08-13 |
human |
| Tirso Rene Del Jesus Gonzalez Alam, Theodoros Karapanagiotidis, Jonathan Smallwood, Elizabeth Jefferie. Degrees of lateralisation in semantic cognition: Evidence from intrinsic connectivity. NeuroImage. vol 202. 2020-09-21. PMID:31419614. |
we compared the intrinsic connectivity of these sites in left hemisphere (lh) and right hemisphere (rh), and linked individual differences in the strength of within- and between-hemisphere connectivity from left-lateralised seeds to performance on semantic tasks, in a sample of 196 healthy volunteers. |
2020-09-21 |
2023-08-13 |
human |
| Julie S Snowden, Jennifer M Harris, Jennifer C Thompson, Christopher Kobylecki, Matthew Jones, Anna M Richardson, David Near. Semantic dementia and the left and right temporal lobes. Cortex; a journal devoted to the study of the nervous system and behavior. vol 107. 2019-12-12. PMID:28947063. |
semantic errors, the hallmark of semantic dementia, were linked to right hemisphere atrophy, especially the right posterior temporal lobe. |
2019-12-12 |
2023-08-13 |
Not clear |
| Dimitrios Kasselimis, Constantin Potagas, Panagiotis Simos, Ioannis Evdokimidis, Harry Whitake. Mixed language dominance: insights from a case of unexpected fluent aphasia with semantic jargon resulting from massive left perisylvian lesion. Neurocase. vol 24. issue 1. 2019-09-09. PMID:29277135. |
he exhibited strikingly unexpected aphasia with semantic jargon and prominent comprehension deficits, suggesting that this is a case of mixed dominance: the right hemisphere likely controls motor speech and basic syntactic skills, while the severely damaged left hemisphere controls semantic processing, predictably severely impaired. |
2019-09-09 |
2023-08-13 |
Not clear |
| Andrea Gajardo-Vidal, Diego L Lorca-Puls, Thomas M H Hope, Oiwi Parker Jones, Mohamed L Seghier, Susan Prejawa, Jennifer T Crinion, Alex P Leff, David W Green, Cathy J Pric. How right hemisphere damage after stroke can impair speech comprehension. Brain : a journal of neurology. vol 141. issue 12. 2019-07-15. PMID:30418586. |
for those with auditory sentence-to-picture matching impairments after right hemisphere strokes, the majority (n = 9) had normal performance on tests of perceptual (visual or auditory) and linguistic (semantic, phonological or syntactic) processing. |
2019-07-15 |
2023-08-13 |
human |
| Xiaopeng Si, Wenjing Zhou, Bo Hon. Cooperative cortical network for categorical processing of Chinese lexical tone. Proceedings of the National Academy of Sciences of the United States of America. vol 114. issue 46. 2018-06-19. PMID:29087324. |
moreover, the motor cortex received enhanced granger causal influence from the semantic hub, the anterior temporal lobe, in the right hemisphere. |
2018-06-19 |
2023-08-13 |
Not clear |
| Samuel J Westwood, Cristina Roman. Transcranial direct current stimulation (tDCS) modulation of picture naming and word reading: A meta-analysis of single session tDCS applied to healthy participants. Neuropsychologia. vol 104. 2018-05-30. PMID:28757003. |
we reviewed 14 papers measuring tdcs effects across a total of 96 conditions to a) quantify effects of conventional stimulation on language regions (i.e., left hemisphere anodal tdcs administered to temporal/frontal areas) under normal conditions or under conditions of cognitive (semantic) interference; b) identify parameters which may moderate the size of the tdcs effect within conventional stimulation protocols (e.g., online vs offline, high vs. low current densities, and short vs. long durations), as well as within types of stimulation not typically explored by previous reviews (i.e., right hemisphere anodal tdcs or left/right hemisphere cathodal tdcs). |
2018-05-30 |
2023-08-13 |
human |
| Guillaume Herbet, Sylvie Moritz-Gasser, Hugues Duffa. Direct evidence for the contributive role of the right inferior fronto-occipital fasciculus in non-verbal semantic cognition. Brain structure & function. vol 222. issue 4. 2018-03-05. PMID:27568379. |
to gain insights on this matter, we used an intraoperative direct electrostimulation to map the structures mediating the non-verbal semantic system in the right hemisphere. |
2018-03-05 |
2023-08-13 |
Not clear |
| Guillaume Herbet, Sylvie Moritz-Gasser, Hugues Duffa. Direct evidence for the contributive role of the right inferior fronto-occipital fasciculus in non-verbal semantic cognition. Brain structure & function. vol 222. issue 4. 2018-03-05. PMID:27568379. |
at the cortical level, in the right hemisphere, we found non-verbal semantic-related sites (n = 7 in 6 patients) in structures commonly associated with verbal semantic processes in the left hemisphere, including the superior temporal gyrus, the pars triangularis, and the dorsolateral prefrontal cortex. |
2018-03-05 |
2023-08-13 |
Not clear |
| Brian C Castelluccio, Emily B Myers, Jillian M Schuh, Inge-Marie Eigst. Neural Substrates of Processing Anger in Language: Contributions of Prosody and Semantics. Journal of psycholinguistic research. vol 45. issue 6. 2017-04-28. PMID:26645465. |
while many studies confirm the role of a left hemisphere network in processing semantic emotion, there has been debate over the role of the right hemisphere in processing prosodic emotion. |
2017-04-28 |
2023-08-13 |
Not clear |
| Hannah E Thompson, Lauren Henshall, Elizabeth Jefferie. The role of the right hemisphere in semantic control: A case-series comparison of right and left hemisphere stroke. Neuropsychologia. vol 85. 2017-04-28. PMID:26945505. |
the role of the right hemisphere in semantic control: a case-series comparison of right and left hemisphere stroke. |
2017-04-28 |
2023-08-13 |
Not clear |
| Hannah E Thompson, Lauren Henshall, Elizabeth Jefferie. The role of the right hemisphere in semantic control: A case-series comparison of right and left hemisphere stroke. Neuropsychologia. vol 85. 2017-04-28. PMID:26945505. |
to investigate the role of the right hemisphere (rh) in semantic control, we compared nine rh stroke patients with 21 left-hemisphere sa patients, 11 mild sa cases and 12 healthy, aged-matched controls on semantic and executive tasks, plus experimental tasks that manipulated semantic control in paradigms particularly sensitive to rh damage. |
2017-04-28 |
2023-08-13 |
Not clear |
| Guido Gainott. Implications of recent findings for current cognitive models of familiar people recognition. Neuropsychologia. vol 77. 2016-08-03. PMID:26359717. |
additionally, clinical and experimental data have shown that pins should not be considered as a simple gateway to a unitary semantic system, which stores information about people in an abstract and amodal format, but as structures involved in the storage and retrieval of person-specific information, preferentially represented in a sensory-motor format in the right hemisphere and in a language-mediated format in the left hemisphere. |
2016-08-03 |
2023-08-13 |
Not clear |
| Alessandra Passeri, Paolo Capotosto, Rosalia Di Matte. The right hemisphere contribution to semantic categorization: a TMS study. Cortex; a journal devoted to the study of the nervous system and behavior. vol 64. 2015-12-02. PMID:25584788. |
the right hemisphere contribution to semantic categorization: a tms study. |
2015-12-02 |
2023-08-13 |
Not clear |
| Alessandra Passeri, Paolo Capotosto, Rosalia Di Matte. The right hemisphere contribution to semantic categorization: a TMS study. Cortex; a journal devoted to the study of the nervous system and behavior. vol 64. 2015-12-02. PMID:25584788. |
overall, these results indicate that while both hemispheres are involved in the categorization of typical exemplars, the right hemisphere specifically contributes to semantic categorization of atypical ones. |
2015-12-02 |
2023-08-13 |
Not clear |
| Maria Montefinese, Marco Ciavarro, Ettore Ambrosin. What is the right place for atypical exemplars? Commentary: The right hemisphere contribution to semantic categorization: a TMS study. Frontiers in psychology. vol 6. 2015-10-07. PMID:26441726. |
commentary: the right hemisphere contribution to semantic categorization: a tms study. |
2015-10-07 |
2023-08-13 |
Not clear |
| Barbara Tomasino, Franco Fabbro, Paolo Brambill. How do conceptual representations interact with processing demands: An fMRI study on action- and abstract-related words. Brain research. vol 1591. 2015-09-02. PMID:25446003. |
rather, as we made sure that abstract verbs were not associated with motor states (as tested in a rating study of our stimulus list), imagery elicited by abstract verb processing (as compared to action verbs, and controlled for letter detection) differentially activated a right hemisphere neural network including the right supramarginal (smg) gyrus and the precuneus which might be related to mental imagery of emotion-related scenes and not to the semantics of the stimuli per se. |
2015-09-02 |
2023-08-13 |
Not clear |
| Ekaterini Klepousniotou, Vincent L Gracco, G Bruce Pik. Pathways to lexical ambiguity: fMRI evidence for bilateral fronto-parietal involvement in language processing. Brain and language. vol 131. 2015-02-05. PMID:24183467. |
the role of these areas in the right hemisphere in language processing is not understood and, although there is evidence from lesion studies that the right hemisphere is involved in the appreciation of semantic relations, no specific anatomical substrate has yet been identified. |
2015-02-05 |
2023-08-12 |
Not clear |
| Maor Zeev-Wolf, Abraham Goldstein, Yechiel Levkovitz, Miriam Faus. Fine-coarse semantic processing in schizophrenia: a reversed pattern of hemispheric dominance. Neuropsychologia. vol 56. 2014-11-12. PMID:24462952. |
beeman׳s fine-coarse semantic coding model asserts left hemisphere specialization in fine (i.e., conventionalized) semantic coding and right hemisphere specialization in coarse (i.e., non-conventionalized) semantic coding. |
2014-11-12 |
2023-08-12 |
human |
| John Kounios, Mark Beema. The cognitive neuroscience of insight. Annual review of psychology. vol 65. 2014-09-19. PMID:24405359. |
recent work has revealed insight-related coarse semantic coding in the right hemisphere and internally focused attention preceding and during problem solving. |
2014-09-19 |
2023-08-12 |
Not clear |