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Neurocomputational Consequences of Evolutionary Connectivity Changes in Perisylvian Language Cortex
- Source :
- The Journal of Neuroscience
- Publication Year :
- 2017
- Publisher :
- Society for Neuroscience, 2017.
-
Abstract
- The human brain sets itself apart from that of its primate relatives by specific neuroanatomical features, especially the strong linkage of left perisylvian language areas (frontal and temporal cortex) by way of the arcuate fasciculus (AF). AF connectivity has been shown to correlate with verbal working memory—a specifically human trait providing the foundation for language abilities—but a mechanistic explanation of any related causal link between anatomical structure and cognitive function is still missing. Here, we provide a possible explanation and link, by using neurocomputational simulations in neuroanatomically structured models of the perisylvian language cortex. We compare networks mimicking key features of cortical connectivity in monkeys and humans, specifically the presence of relatively stronger higher-order “jumping links” between nonadjacent perisylvian cortical areas in the latter, and demonstrate that the emergence of working memory for syllables and word forms is a functional consequence of this structural evolutionary change. We also show that a mere increase of learning time is not sufficient, but that this specific structural feature, which entails higher connectivity degree of relevant areas and shorter sensorimotor path length, is crucial. These results offer a better understanding of specifically human anatomical features underlying the language faculty and their evolutionary selection advantage.SIGNIFICANCE STATEMENTWhy do humans have superior language abilities compared to primates? Recently, a uniquely human neuroanatomical feature has been demonstrated in the strength of the arcuate fasciculus (AF), a fiber pathway interlinking the left-hemispheric language areas. Although AF anatomy has been related to linguistic skills, an explanation of how this fiber bundle may support language abilities is still missing. We use neuroanatomically structured computational models to investigate the consequences of evolutionary changes in language area connectivity and demonstrate that the human-specific higher connectivity degree and comparatively shorter sensorimotor path length implicated by the AF entail emergence of verbal working memory, a prerequisite for language learning. These results offer a better understanding of specifically human anatomical features for language and their evolutionary selection advantage.
- Subjects :
- Pan troglodytes
Behavioral/Cognitive
Models, Neurological
neurocomputational modeling
050105 experimental psychology
03 medical and health sciences
0302 clinical medicine
Species Specificity
Connectome
medicine
Animals
Humans
Arcuate fasciculus
Computer Simulation
perisylvian cortex
0501 psychology and cognitive sciences
cortical connectivity
Research Articles
Language
Cerebral Cortex
Statement (computer science)
Temporal cortex
Neuronal Plasticity
Models, Genetic
Working memory
General Neuroscience
05 social sciences
Cerebral Aqueduct
Cognition
Haplorhini
Human brain
verbal working memory
Language acquisition
Biological Evolution
Feature (linguistics)
medicine.anatomical_structure
arcuate fasciculus
Macaca
action–perception cycle
Psychology
030217 neurology & neurosurgery
Cognitive psychology
Subjects
Details
- ISSN :
- 15292401 and 02706474
- Volume :
- 37
- Database :
- OpenAIRE
- Journal :
- The Journal of Neuroscience
- Accession number :
- edsair.doi.dedup.....cca5d2ecd5b65c7da9a03cf797821628