Your search keyword '"Stimpson, Cheryl D."' showing total 11 results

1. Invariant Synapse Density and Neuronal Connectivity Scaling in Primate Neocortical Evolution.

Author

Sherwood CC, Miller SB, Karl M, Stimpson CD, Phillips KA, Jacobs B, Hof PR, Raghanti MA, and Smaers JB

Subjects

Adult, Animals, Female, Humans, Male, Primary Visual Cortex cytology, Temporal Lobe cytology, Young Adult, Biological Evolution, Neocortex cytology, Neurons cytology, Primates anatomy & histology, Synapses

Abstract

Synapses are involved in the communication of information from one neuron to another. However, a systematic analysis of synapse density in the neocortex from a diversity of species is lacking, limiting what can be understood about the evolution of this fundamental aspect of brain structure. To address this, we quantified synapse density in supragranular layers II-III and infragranular layers V-VI from primary visual cortex and inferior temporal cortex in a sample of 25 species of primates, including humans. We found that synapse densities were relatively constant across these levels of the cortical visual processing hierarchy and did not significantly differ with brain mass, varying by only 1.9-fold across species. We also found that neuron densities decreased in relation to brain enlargement. Consequently, these data show that the number of synapses per neuron significantly rises as a function of brain expansion in these neocortical areas of primates. Humans displayed the highest number of synapses per neuron, but these values were generally within expectations based on brain size. The metabolic and biophysical constraints that regulate uniformity of synapse density, therefore, likely underlie a key principle of neuronal connectivity scaling in primate neocortical evolution., (© The Author(s) 2020. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permission@oup.com.)

Published

2020

2. Comparative neocortical neuromorphology in felids: African lion, African leopard, and cheetah.

Author

Nguyen VT, Uchida R, Warling A, Sloan LJ, Saviano MS, Wicinski B, Hård T, Bertelsen MF, Stimpson CD, Bitterman K, Schall M, Hof PR, Sherwood CC, Manger PR, Spocter MA, and Jacobs B

Subjects

Animals, Felidae anatomy & histology, Female, Male, Neocortex chemistry, Species Specificity, Acinonyx anatomy & histology, Lions anatomy & histology, Neocortex anatomy & histology, Neocortex cytology, Panthera anatomy & histology

Abstract

The present study examines cortical neuronal morphology in the African lion (Panthera leo leo), African leopard (Panthera pardus pardus), and cheetah (Acinonyx jubatus jubatus). Tissue samples were removed from prefrontal, primary motor, and primary visual cortices and investigated with a Golgi stain and computer-assisted morphometry to provide somatodendritic measures of 652 neurons. Although neurons in the African lion were insufficiently impregnated for accurate quantitative dendritic measurements, descriptions of neuronal morphologies were still possible. Qualitatively, the range of spiny and aspiny neurons across the three species was similar to those observed in other felids, with typical pyramidal neurons being the most prominent neuronal type. Quantitatively, somatodendritic measures of typical pyramidal neurons in the cheetah were generally larger than in the African leopard, despite similar brain sizes. A MARsplines analysis of dendritic measures correctly differentiated 87.4% of complete typical pyramidal neurons between the African leopard and cheetah. In addition, unbiased stereology was used to compare the soma size of typical pyramidal neurons (n = 2,238) across all three cortical regions and gigantopyramidal neurons (n = 1,189) in primary motor and primary visual cortices. Both morphological and stereological analyses indicated that primary motor gigantopyramidal neurons were exceptionally large across all three felids compared to other carnivores, possibly due to specializations related to the felid musculoskeletal systems. The large size of these neurons in the cheetah which, unlike lions and leopards, does not belong to the Panthera genus, suggests that exceptionally enlarged primary motor gigantopyramidal neurons evolved independently in these felid species., (© 2019 Wiley Periodicals, Inc.)

Published

2020

3. Gradients in cytoarchitectural landscapes of the isocortex: Diprotodont marsupials in comparison to eutherian mammals.

Author

Charvet CJ, Stimpson CD, Kim YD, Raghanti MA, Lewandowski AH, Hof PR, Gómez-Robles A, Krienen FM, and Sherwood CC

Subjects

Animals, Imaging, Three-Dimensional, Species Specificity, Mammals anatomy & histology, Marsupialia anatomy & histology, Neocortex anatomy & histology

Abstract

Although it has been claimed that marsupials possess a lower density of isocortical neurons compared with other mammals, little is known about cross-cortical variation in neuron distributions in this diverse taxonomic group. We quantified upper-layer (layers II-IV) and lower-layer (layers V-VI) neuron numbers per unit of cortical surface area in three diprotodont marsupial species (two macropodiformes, the red kangaroo and the parma wallaby, and a vombatiform, the koala) and compared these results to eutherian mammals (e.g., xenarthrans, rodents, primates). In contrast to the notion that the marsupial isocortex contains a low density of neurons, we found that neuron numbers per unit of cortical surface area in several marsupial species overlap with those found in eutherian mammals. Furthermore, neuron numbers vary systematically across the isocortex of the marsupial mammals examined. Neuron numbers under a unit of cortical surface area are low toward the frontal cortex and high toward the caudo-medial (occipital) pole. Upper-layer neurons (i.e., layers II-IV) account for most of the variation in neuron numbers across the isocortex. The variation in neuron numbers across the rostral to the caudal pole resembles primates. These findings suggest that diprotodont marsupials and eutherian mammals share a similar cortical architecture despite their distant evolutionary divergence., (© 2017 Wiley Periodicals, Inc.)

Published

2017

4. Developmental changes in the spatial organization of neurons in the neocortex of humans and common chimpanzees.

Author

Teffer K, Buxhoeveden DP, Stimpson CD, Fobbs AJ, Schapiro SJ, Baze WB, McArthur MJ, Hopkins WD, Hof PR, Sherwood CC, and Semendeferi K

Subjects

Animals, Child, Child, Preschool, Female, Humans, Infant, Infant, Newborn, Male, Pan troglodytes, Neocortex cytology, Neocortex growth & development, Neurons cytology

Abstract

In adult humans the prefrontal cortex possesses wider minicolumns and more neuropil space than other cortical regions. These aspects of prefrontal cortex architecture, furthermore, are increased in comparison to chimpanzees and other great apes. In order to determine the developmental appearance of this human cortical specialization, we examined the spatial organization of neurons in four cortical regions (frontal pole [Brodmann's area 10], primary motor [area 4], primary somatosensory [area 3b], and prestriate visual cortex [area 18]) in chimpanzees and humans from birth to approximately the time of adolescence (11 years of age). Horizontal spacing distance (HSD) and gray level ratio (GLR) of layer III neurons were measured in Nissl-stained sections. In both human and chimpanzee area 10, HSD was significantly higher in the postweaning specimens compared to the preweaning ones. No significant age-related differences were seen in the other regions in either species. In concert with other recent studies, the current findings suggest that there is a relatively slower maturation of area 10 in both humans and chimpanzees as compared to other cortical regions, and that further refinement of the spatial organization of neurons within this prefrontal area in humans takes place after the postweaning periods included here., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

5. Dendritic morphology of pyramidal neurons in the chimpanzee neocortex: regional specializations and comparison to humans.

Author

Bianchi S, Stimpson CD, Bauernfeind AL, Schapiro SJ, Baze WB, McArthur MJ, Bronson E, Hopkins WD, Semendeferi K, Jacobs B, Hof PR, and Sherwood CC

Subjects

Animals, Female, Humans, Male, Pan troglodytes, Dendrites ultrastructure, Neocortex cytology, Pyramidal Cells ultrastructure

Abstract

The primate cerebral cortex is characterized by regional variation in the structure of pyramidal neurons, with more complex dendritic arbors and greater spine density observed in prefrontal compared with sensory and motor cortices. Although there are several investigations in humans and other primates, virtually nothing is known about regional variation in the morphology of pyramidal neurons in the cerebral cortex of great apes, humans' closest living relatives. The current study uses the rapid Golgi stain to quantify the dendritic structure of layer III pyramidal neurons in 4 areas of the chimpanzee cerebral cortex: Primary somatosensory (area 3b), primary motor (area 4), prestriate visual (area 18), and prefrontal (area 10) cortex. Consistent with previous studies in humans and macaque monkeys, pyramidal neurons in the prefrontal cortex of chimpanzees exhibit greater dendritic complexity than those in other cortical regions, suggesting that prefrontal cortical evolution in primates is characterized by increased potential for integrative connectivity. Compared with chimpanzees, the pyramidal neurons of humans had significantly longer and more branched dendritic arbors in all cortical regions.

Published

2013

6. Synaptogenesis and development of pyramidal neuron dendritic morphology in the chimpanzee neocortex resembles humans.

Author

Bianchi S, Stimpson CD, Duka T, Larsen MD, Janssen WG, Collins Z, Bauernfeind AL, Schapiro SJ, Baze WB, McArthur MJ, Hopkins WD, Wildman DE, Lipovich L, Kuzawa CW, Jacobs B, Hof PR, and Sherwood CC

Subjects

Animals, Feedback, Sensory physiology, Female, Humans, Male, Dendrites physiology, Neocortex cytology, Neocortex physiology, Pan troglodytes anatomy & histology, Pan troglodytes physiology, Phylogeny, Pyramidal Cells cytology, Pyramidal Cells physiology, Synapses physiology

Abstract

Neocortical development in humans is characterized by an extended period of synaptic proliferation that peaks in mid-childhood, with subsequent pruning through early adulthood, as well as relatively delayed maturation of neuronal arborization in the prefrontal cortex compared with sensorimotor areas. In macaque monkeys, cortical synaptogenesis peaks during early infancy and developmental changes in synapse density and dendritic spines occur synchronously across cortical regions. Thus, relatively prolonged synapse and neuronal maturation in humans might contribute to enhancement of social learning during development and transmission of cultural practices, including language. However, because macaques, which share a last common ancestor with humans ≈ 25 million years ago, have served as the predominant comparative primate model in neurodevelopmental research, the paucity of data from more closely related great apes leaves unresolved when these evolutionary changes in the timing of cortical development became established in the human lineage. To address this question, we used immunohistochemistry, electron microscopy, and Golgi staining to characterize synaptic density and dendritic morphology of pyramidal neurons in primary somatosensory (area 3b), primary motor (area 4), prestriate visual (area 18), and prefrontal (area 10) cortices of developing chimpanzees (Pan troglodytes). We found that synaptogenesis occurs synchronously across cortical areas, with a peak of synapse density during the juvenile period (3-5 y). Moreover, similar to findings in humans, dendrites of prefrontal pyramidal neurons developed later than sensorimotor areas. These results suggest that evolutionary changes to neocortical development promoting greater neuronal plasticity early in postnatal life preceded the divergence of the human and chimpanzee lineages.

Published

2013

7. Prolonged myelination in human neocortical evolution.

Author

Miller DJ, Duka T, Stimpson CD, Schapiro SJ, Baze WB, McArthur MJ, Fobbs AJ, Sousa AM, Sestan N, Wildman DE, Lipovich L, Kuzawa CW, Hof PR, and Sherwood CC

Subjects

Adolescent, Adult, Animals, Blotting, Western, Child, Humans, Infant, Infant, Newborn, Motor Cortex growth & development, Motor Cortex metabolism, Myelin-Associated Glycoprotein metabolism, Neocortex growth & development, Pan troglodytes, Prefrontal Cortex growth & development, Prefrontal Cortex metabolism, Somatosensory Cortex growth & development, Somatosensory Cortex metabolism, Time Factors, Visual Cortex growth & development, Visual Cortex metabolism, Young Adult, Biological Evolution, Myelin Proteins metabolism, Myelin Sheath metabolism, Neocortex metabolism

Abstract

Nerve myelination facilitates saltatory action potential conduction and exhibits spatiotemporal variation during development associated with the acquisition of behavioral and cognitive maturity. Although human cognitive development is unique, it is not known whether the ontogenetic progression of myelination in the human neocortex is evolutionarily exceptional. In this study, we quantified myelinated axon fiber length density and the expression of myelin-related proteins throughout postnatal life in the somatosensory (areas 3b/3a/1/2), motor (area 4), frontopolar (prefrontal area 10), and visual (areas 17/18) neocortex of chimpanzees (N = 20) and humans (N = 33). Our examination revealed that neocortical myelination is developmentally protracted in humans compared with chimpanzees. In chimpanzees, the density of myelinated axons increased steadily until adult-like levels were achieved at approximately the time of sexual maturity. In contrast, humans displayed slower myelination during childhood, characterized by a delayed period of maturation that extended beyond late adolescence. This comparative research contributes evidence crucial to understanding the evolution of human cognition and behavior, which arises from the unfolding of nervous system development within the context of an enriched cultural environment. Perturbations of normal developmental processes and the decreased expression of myelin-related molecules have been related to psychiatric disorders such as schizophrenia. Thus, these species differences suggest that the human-specific shift in the timing of cortical maturation during adolescence may have implications for vulnerability to certain psychiatric disorders.

Published

2012

8. Neocortical neuron morphology in Afrotheria: comparing the rock hyrax with the African elephant.

Author

Bianchi S, Bauernfeind AL, Gupta K, Stimpson CD, Spocter MA, Bonar CJ, Manger PR, Hof PR, Jacobs B, and Sherwood CC

Subjects

Anatomy, Comparative, Animals, Cell Count, Cell Shape, Cell Size, Dendrites physiology, Female, Male, Neocortex ultrastructure, Pyramidal Cells cytology, Elephants anatomy & histology, Hyraxes anatomy & histology, Neocortex anatomy & histology, Neocortex cytology, Neurons cytology

Abstract

The mammalian neocortex contains a great variety of neuronal types. In particular, recent studies have shown substantial morphological diversity among spiny projecting neurons in species that diverged close to the base of the mammalian radiation (e.g., monotremes, afrotherians, and xenarthrans). Here, we used a Golgi technique to examine different neuronal morphologies in an afrotherian species, the rock hyrax (Procavia capensis), and provide a comparison with the related African elephant (Loxodonta africana). Results showed that spiny neurons in the rock hyrax neocortex exhibit less morphological variation than in elephants, displaying a higher frequency of relatively "typical" pyramidal neurons. A quantitative comparison of rock hyrax pyramidal neuron morphology between frontal and visual areas, moreover, revealed greater spine density of neurons in frontal cortex, but no differences in other morphological aspects. Regional variations in pyramidal structure have also been observed in the African elephant, as well as a number of primate species., (© 2011 New York Academy of Sciences.)

Published

2011

9. Neocortical neuron types in Xenarthra and Afrotheria: implications for brain evolution in mammals.

Author

Sherwood CC, Stimpson CD, Butti C, Bonar CJ, Newton AL, Allman JM, and Hof PR

Subjects

Animals, Body Weight, Calbindin 2, Calbindins, Female, Glial Fibrillary Acidic Protein analysis, Hyraxes, Male, Mammals classification, Mammals genetics, Neurofilament Proteins analysis, Neurons chemistry, Neurons cytology, Neuropeptide Y analysis, Organ Size, Parvalbumins analysis, Photomicrography, Phylogeny, Regression Analysis, S100 Calcium Binding Protein G analysis, Shrews, Xenarthra classification, Xenarthra genetics, Biological Evolution, Mammals anatomy & histology, Neocortex cytology, Neurons classification, Xenarthra anatomy & histology

Abstract

Interpreting the evolution of neuronal types in the cerebral cortex of mammals requires information from a diversity of species. However, there is currently a paucity of data from the Xenarthra and Afrotheria, two major phylogenetic groups that diverged close to the base of the eutherian mammal adaptive radiation. In this study, we used immunohistochemistry to examine the distribution and morphology of neocortical neurons stained for nonphosphorylated neurofilament protein, calbindin, calretinin, parvalbumin, and neuropeptide Y in three xenarthran species-the giant anteater (Myrmecophaga tridactyla), the lesser anteater (Tamandua tetradactyla), and the two-toed sloth (Choloepus didactylus)-and two afrotherian species-the rock hyrax (Procavia capensis) and the black and rufous giant elephant shrew (Rhynchocyon petersi). We also studied the distribution and morphology of astrocytes using glial fibrillary acidic protein as a marker. In all of these species, nonphosphorylated neurofilament protein-immunoreactive neurons predominated in layer V. These neurons exhibited diverse morphologies with regional variation. Specifically, high proportions of atypical neurofilament-enriched neuron classes were observed, including extraverted neurons, inverted pyramidal neurons, fusiform neurons, and other multipolar types. In addition, many projection neurons in layers II-III were found to contain calbindin. Among interneurons, parvalbumin- and calbindin-expressing cells were generally denser compared to calretinin-immunoreactive cells. We traced the evolution of certain cortical architectural traits using phylogenetic analysis. Based on our reconstruction of character evolution, we found that the living xenarthrans and afrotherians show many similarities to the stem eutherian mammal, whereas other eutherian lineages display a greater number of derived traits.

Published

2009

10. Evolution of Increased Glia-neuron Ratios in the Human Frontal Cortex

Author

Sherwood, Chet C., Stimpson, Cheryl D., Raghanti, Mary Ann, Wildman, Derek E., Uddin, Monica, Grossman, Lawrence I., Goodman, Morris, Redmond, John C., Bonar, Christopher J., Erwin, Joseph M., and Hof, Patrick R.

Published

2006

11. Developmental changes in the spatial organization of neurons in the neocortex of humans and common chimpanzees

Author

Teffer, Kate, Buxhoeveden, Daniel P., Stimpson, Cheryl D., Fobbs, Archibald J., Schapiro, Steven J., Baze, Wallace B., McArthur, Mark J., Hopkins, William D., Hof, Patrick R., Sherwood, Chet C., and Semendeferi, Katerina

Subjects

Male, Neurons, Pan troglodytes, Child, Preschool, Infant, Newborn, Animals, Humans, Infant, Female, Neocortex, Child, Article

Abstract

In adult humans, the prefrontal cortex possesses wider minicolumns and more neuropil space than other cortical regions. These aspects of prefrontal cortex architecture, furthermore, are increased in comparison to chimpanzees and other great apes. In order to determine the developmental appearance of this human cortical specialization, we examined the spatial organization of neurons in four cortical regions (frontal pole [Brodmann’s area 10], primary motor [area 4], primary somatosensory [area 3b], and prestriate visual cortex [area 18]) in chimpanzees and humans from birth to approximately the time of adolescence (11 years of age). Horizontal spacing distance (HSD) and gray level ratio (GLR) of layer III neurons were measured in Nissl-stained sections. In both human and chimpanzee area 10, HSD was significantly higher in the post-weaning specimens compared to the pre-weaning ones. No significant age-related differences were seen in the other regions in either species. In concert with other recent studies, the current findings suggest that there is a relatively slower maturation of area 10 in both humans and chimpanzees as compared to other cortical regions, and that further refinement of the spatial organization of neurons within this prefrontal area in humans takes place after the post-weaning periods included here.

Published

2013