Neuropil distribution in the cerebral cortex differs between humans and chimpanzees

Spocter, Muhammad A.; Hopkins, William D.; Barks, Sarah K.; Bianchi, Serena; Hehmeyer, Abigail; Anderson, Sarah M.; Stimpson, Cheryl D.; Fobbs, Archibald J.; Hof, Patrick R.; Sherwood, Chet C.

doi:10.1002/cne.23074

Cited by 92 publications

(68 citation statements)

References 92 publications

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“…It is clear from the work of Ribeiro et al [2013] that in the human brain the density of cells decreases as one moves anteriorly in the brain, being at its lowest in the anterior sections. It is also clear that in the human brain the cell density in the frontal polar cortex is particularly sparse [Semendeferi et al, 2010;Spocter et al, 2012]. Thus, it could be that if, for example, cell numbers were available for the prefrontal and temporal cortex, it might turn out that the human remapping factor does not stand out in terms of cells, though it does in terms of tissue.…”

Section: Limitations Of the Studymentioning

confidence: 99%

Is the Prefrontal Cortex Especially Enlarged in the Human Brain? Allometric Relations and Remapping Factors

Passingham¹,

Smaers²

2014

Brain Behav Evol

104

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There has been no agreement as to whether the prefrontal cortex is especially enlarged in the human brain. To answer this question, we analyzed the only two datasets that provide information on total prefrontal cortex volume based on cytoarchitectonic criteria. One delineated the prefrontal cortex proper on the basis of cytoarchitectonic criteria; the other used a proxy of the prefrontal cortex based on a cytoarchitectonic delineation of the frontal lobe. To investigate whether all cortical association areas, including the prefrontal cortex, are enlarged in the human brain, we scaled the different areas to a common reference, the primary visual cortex. To investigate whether the prefrontal cortex is more enlarged than other association areas, we scaled it relative to its inputs from and outputs to other nonprimary areas. We carried out separate regression analyses using different data samples as a predictive baseline group: data for monkeys alone informs us on whether great apes are different from monkeys; data for all non-human anthropoids, including great apes, informs us on whether humans are different from all other primates. The analyses show that the value for the human prefrontal cortex is greater than expected, and that this is true even when data for the great apes are included in the analysis. They also show that the chimpanzee prefrontal cortex is greater than expected for a monkey with a similar sized cortex. We discuss possible functional consequences.

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Section: Limitations Of the Studymentioning

confidence: 99%

Is the Prefrontal Cortex Especially Enlarged in the Human Brain? Allometric Relations and Remapping Factors

Passingham¹,

Smaers²

2014

Brain Behav Evol

104

View full text Add to dashboard Cite

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“…But based on previous knowledge, the presence of adult neuron recruitment in other regions except potentially the olfactory bulb is unlikely (Amrein 2015). Volumetric changes are more likely to occur in the neuropil, which makes up the space between cells (Spocter et al 2012). Finally, mammalian brains show high variation in white matter over the lifetime (Marner et al 2003).…”

Section: Discussionmentioning

confidence: 99%

Profound seasonal changes in brain size and architecture in the common shrew

et al. 2018

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The seasonal changes in brain size of some shrews represent the most drastic reversible transformation in the mammalian central nervous system known to date. Brain mass decreases 10–26% from summer to winter and regrows 9–16% in spring, but the underlying structural changes at the cellular level are not yet understood. Here, we describe the volumetric differences in brain structures between seasons and sexes of the common shrew (Sorex araneus) in detail, confirming that changes in different brain regions vary in the magnitude of change. Notably, shrews show a decrease in hypothalamus, thalamus, and hippocampal volume and later regrowth in spring, whereas neocortex and striatum volumes decrease in winter and do not recover in size. For some regions, males and females showed different patterns of seasonal change from each other. We also analyzed the underlying changes in neuron morphology. We observed a general decrease in soma size and total dendrite volume in the caudoputamen and anterior cingulate cortex. This neuronal retraction may partially explain the overall tissue shrinkage in winter. While not sufficient to explain the entire seasonal process, it represents a first step toward understanding the mechanisms beneath this remarkable phenomenon.Electronic supplementary materialThe online version of this article (10.1007/s00429-018-1666-5) contains supplementary material, which is available to authorized users.

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“…Investigating prefrontal and parietal layer III—a locus for pyramidal cell bodies as well as inter- and intrahemispheric connections—has identified fewer pyramidal neurons, spaced further apart in humans relative to chimpanzees and macaques (Semendeferi et al, 2011; Spocter et al, 2012). A greater horizontal spacing difference suggests that the expanded surface area contains more dendrites and axons, suggesting more of an integrative function of these neurons in humans.…”

Section: Cortical Expansion Differences Are Found In Regions Supportimentioning

confidence: 99%

Evolutionary and Developmental Changes in the Lateral Frontoparietal Network: A Little Goes a Long Way for Higher-Level Cognition

Vendetti

Bunge

2014

Neuron

115

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Relational thinking, or the ability to represent the relations between items, is widespread in the animal kingdom. However, humans are unparalleled in their ability to engage in the higher-order relational thinking required for reasoning and other forms of abstract thought. Here we propose that the versatile reasoning skills observed in humans can be traced back to developmental and evolutionary changes in the lateral frontoparietal network (LFPN). We first identify the regions within the LFPN that are most strongly linked to relational thinking, and show that stronger communication between these regions over the course of development supports improvements in relational reasoning. We then explore differences in the LFPN between humans and other primate species that could explain species differences in the capacity for relational reasoning. We conclude that fairly small neuroanatomical changes in specific regions of the LFPN and their connections have led to big ontogenetic and phylogenetic changes in cognition.

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Neuropil distribution in the cerebral cortex differs between humans and chimpanzees

Cited by 92 publications

References 92 publications

Is the Prefrontal Cortex Especially Enlarged in the Human Brain? Allometric Relations and Remapping Factors

Is the Prefrontal Cortex Especially Enlarged in the Human Brain? Allometric Relations and Remapping Factors

Profound seasonal changes in brain size and architecture in the common shrew

Evolutionary and Developmental Changes in the Lateral Frontoparietal Network: A Little Goes a Long Way for Higher-Level Cognition

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