Functional localization and cortical architecture in the nine‐banded armadillo (Dasypus novemcinctus mexicanus)
Identifieur interne : 00E266 ( Main/Exploration ); précédent : 00E265; suivant : 00E267Functional localization and cortical architecture in the nine‐banded armadillo (Dasypus novemcinctus mexicanus)
Auteurs : G. James Royce [États-Unis] ; George F. Martin [États-Unis] ; Richard M. Dom [États-Unis]Source :
- Journal of Comparative Neurology [ 0021-9967 ] ; 1975-12-15.
English descriptors
- KwdEn :
- Approximate region, Architectonic subdivisions, Armadillo, Armadillo brain, Armadillo neocortex, Auditory, Auditory area, Auditory cortex, Auditory region, Caudal, Caudal sequence, Cell clusters, Cerebral cortex, Comp, Cortex, Cortex rostral, Cortical, Cortical architecture, Cortical layers, Cortical regions, Cytoarchitectural areas, Dasypus novemcinctus, Degeneration, Didelphis virginiana, Digit, Distinct layer, Dorsal, Ebner, Electrical stimulation, Fissure, Forelimb, Frontal section, Golgi, Golgi material, Golgi preparations, Granule, Granule cells, Harting, Hedgehog, High power photomicrograph, Higher power, Higher power photomicrograph, Insular, Insular cortex, Kaas, Krieg, Large area, Lateral, Lateral aspect, Lateral geniculate body, Layer, Lende, Marsupial phalanger, Medial, Medial peristriate cortex, Motor area, Motor areas, Motor representation, Motor responses, Myelinated fibers, Neocortex, Neur, Neuron, Numeral, Olfactory, Olfactory bulb, Opossum, Other species, Outer bands, Pectoral region, Peristriate, Peristriate areas, Peristriate cortex, Photomicrograph, Postsupraorbital, Potential results, Power photomicrograph, Presupraorbital, Presupraorbital cortex, Pyramidal, Pyramidal cells, Pyramidal neurons, Pyriform, Pyriform cortex, Retrosplenial, Retrosplenial area, Retrosplenial cortex, Rhinal, Rhinal fissure, Roman numerals, Rostral, Rostrally, Royce, Sagittal, Sagittal sulcus, Sensory area, Sensory areas, Sensory representation, Sensory representations, Small granule cells, Snout, Somatic, Stellate cells, Striate, Striate area, Striate cortex, Striate region, Such cortex, Sulcus, Superficial zone, Supraorbital, Supraorbital sulcus, Suprasylvian, Suprasylvian sulcus, Temporal area, Temporal cortex, Temporal region, Thick layer, Thin layer, Thionin, Tree shrew, Ventral, Virginia opossum, Visual area, Visual cortex, Visual region, Visual stimuli, Wide layer.
- Teeft :
- Approximate region, Architectonic subdivisions, Armadillo, Armadillo brain, Armadillo neocortex, Auditory, Auditory area, Auditory cortex, Auditory region, Caudal, Caudal sequence, Cell clusters, Cerebral cortex, Comp, Cortex, Cortex rostral, Cortical, Cortical architecture, Cortical layers, Cortical regions, Cytoarchitectural areas, Dasypus novemcinctus, Degeneration, Didelphis virginiana, Digit, Distinct layer, Dorsal, Ebner, Electrical stimulation, Fissure, Forelimb, Frontal section, Golgi, Golgi material, Golgi preparations, Granule, Granule cells, Harting, Hedgehog, High power photomicrograph, Higher power, Higher power photomicrograph, Insular, Insular cortex, Kaas, Krieg, Large area, Lateral, Lateral aspect, Lateral geniculate body, Layer, Lende, Marsupial phalanger, Medial, Medial peristriate cortex, Motor area, Motor areas, Motor representation, Motor responses, Myelinated fibers, Neocortex, Neur, Neuron, Numeral, Olfactory, Olfactory bulb, Opossum, Other species, Outer bands, Pectoral region, Peristriate, Peristriate areas, Peristriate cortex, Photomicrograph, Postsupraorbital, Potential results, Power photomicrograph, Presupraorbital, Presupraorbital cortex, Pyramidal, Pyramidal cells, Pyramidal neurons, Pyriform, Pyriform cortex, Retrosplenial, Retrosplenial area, Retrosplenial cortex, Rhinal, Rhinal fissure, Roman numerals, Rostral, Rostrally, Royce, Sagittal, Sagittal sulcus, Sensory area, Sensory areas, Sensory representation, Sensory representations, Small granule cells, Snout, Somatic, Stellate cells, Striate, Striate area, Striate cortex, Striate region, Such cortex, Sulcus, Superficial zone, Supraorbital, Supraorbital sulcus, Suprasylvian, Suprasylvian sulcus, Temporal area, Temporal cortex, Temporal region, Thick layer, Thin layer, Thionin, Tree shrew, Ventral, Virginia opossum, Visual area, Visual cortex, Visual region, Visual stimuli, Wide layer.
Abstract
A functional map of the armadillo neocortex was produced by cortical stimulation and recording evoked potentials following somatic, auditory and visual stimuli. The results obtained were then correlated with the cortical architecture as revealed by Nissl, Golgi and myelin‐stained sections. Cortex rostral to the supraorbital sulcus has a wide layer IV and is mostly silent, except for a motor eye field and a part of the tongue sensory region in its caudal part. Two types of motor‐sensory cortex are present caudal to the supraorbital sulcus. Postsupraorbital I is mostly motor and has prominent pyramidal layers. Layer V is particuarly well developed and in rostral sections its superficial zone is broken up into clusters similar to the solid “barrels” seen in layer IV of other species. Postsupraorbital II has less prominent pyramidal layers and layers II and III are organized into clusters. This region corresponds to the sensory area for the limbs and trunk and the partially overlapping (surface recordings) sensory and motor areas for head, snout and tongue. Digits and limbs are rostral to the trunk representation in both the sensory and motor “homunculi.” Even though surface recording was employed, potentials evoked by visual stimuli could only be recorded from a small caudal area with a very thin layer IV. Although striate and peristriate areas appear similar in Nissl stained preparations, they can be readily differentiated in Weil stained sections. The stellate character of neurons in layer IV of the visual cortex is particularly apparent in Golgi material. Auditory evoked surface potentials were recorded from a broad oval region in the caudal lateral cortex which has a wide layer IV and aggregates of neurons in layers II and III. A Weil stain demonstrates inner and outer bands of Baillarger in this same region. The presumptive insular cortex is electrically silent to sensory stimulation and presents as a narrow band just dorsal to the rhinal fissure with indefinite cell lamination and little myelin.
Url:
DOI: 10.1002/cne.901640408
Affiliations:
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<record><TEI wicri:istexFullTextTei="biblStruct"><teiHeader><fileDesc><titleStmt><title xml:lang="en">Functional localization and cortical architecture in the nine‐banded armadillo (Dasypus novemcinctus mexicanus)</title><author><name sortKey="Royce, G James" sort="Royce, G James" uniqKey="Royce G" first="G. James" last="Royce">G. James Royce</name></author><author><name sortKey="Martin, George F" sort="Martin, George F" uniqKey="Martin G" first="George F." last="Martin">George F. Martin</name></author><author><name sortKey="Dom, Richard M" sort="Dom, Richard M" uniqKey="Dom R" first="Richard M." last="Dom">Richard M. Dom</name></author></titleStmt><publicationStmt><idno type="wicri:source">ISTEX</idno><idno type="RBID">ISTEX:C475CB5DA6895DD543E12D1794E6A1F6641B35D4</idno><date when="1975" year="1975">1975</date><idno type="doi">10.1002/cne.901640408</idno><idno type="url">https://api.istex.fr/document/C475CB5DA6895DD543E12D1794E6A1F6641B35D4/fulltext/pdf</idno><idno type="wicri:Area/Istex/Corpus">006168</idno><idno type="wicri:explorRef" wicri:stream="Istex" wicri:step="Corpus" wicri:corpus="ISTEX">006168</idno><idno type="wicri:Area/Istex/Curation">006168</idno><idno type="wicri:Area/Istex/Checkpoint">006945</idno><idno type="wicri:explorRef" wicri:stream="Istex" wicri:step="Checkpoint">006945</idno><idno type="wicri:doubleKey">0021-9967:1975:Royce G:functional:localization:and</idno><idno type="wicri:Area/Main/Merge">00EB73</idno><idno type="wicri:Area/Main/Curation">00E266</idno><idno type="wicri:Area/Main/Exploration">00E266</idno></publicationStmt><sourceDesc><biblStruct><analytic><title level="a" type="main" xml:lang="en">Functional localization and cortical architecture in the nine‐banded armadillo (<hi rend="italic">Dasypus novemcinctus mexicanus</hi>)</title><author><name sortKey="Royce, G James" sort="Royce, G James" uniqKey="Royce G" first="G. James" last="Royce">G. James Royce</name><affiliation wicri:level="2"><country xml:lang="fr">États-Unis</country><placeName><region type="state">État de New York</region></placeName><wicri:cityArea>Department of Anatomy, Albany Medical College, Albany</wicri:cityArea></affiliation><affiliation wicri:level="2"><country xml:lang="fr">États-Unis</country><placeName><region type="state">Wisconsin</region></placeName><wicri:cityArea>Department of Anatomy, Bardeen Medical Laboratories, University of Wisconsin, Madison</wicri:cityArea></affiliation><affiliation wicri:level="2"><country xml:lang="fr">États-Unis</country><placeName><region type="state">Wisconsin</region></placeName><wicri:cityArea>Current Address: Department of Anatomy, Bardeen Medical Laboratories, The University of Wisconsin, Madison</wicri:cityArea></affiliation></author><author><name sortKey="Martin, George F" sort="Martin, George F" uniqKey="Martin G" first="George F." last="Martin">George F. 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Dom</name><affiliation wicri:level="2"><country xml:lang="fr">États-Unis</country><placeName><region type="state">Caroline du Sud</region></placeName><wicri:cityArea>Department of Anatomy, Medical University of South Carolina, Charleston</wicri:cityArea></affiliation></author></analytic><monogr></monogr><series><title level="j" type="main">Journal of Comparative Neurology</title><idno type="ISSN">0021-9967</idno><idno type="eISSN">1096-9861</idno><imprint><biblScope unit="vol">164</biblScope><biblScope unit="issue">4</biblScope><biblScope unit="page" from="495">495</biblScope><biblScope unit="page" to="521">521</biblScope><biblScope unit="page-count">27</biblScope><publisher>Wiley Subscription Services, Inc., A Wiley Company</publisher><pubPlace>Hoboken</pubPlace><date type="published" when="1975-12-15">1975-12-15</date></imprint><idno type="ISSN">0021-9967</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0021-9967</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Approximate region</term><term>Architectonic subdivisions</term><term>Armadillo</term><term>Armadillo brain</term><term>Armadillo neocortex</term><term>Auditory</term><term>Auditory area</term><term>Auditory cortex</term><term>Auditory region</term><term>Caudal</term><term>Caudal sequence</term><term>Cell clusters</term><term>Cerebral cortex</term><term>Comp</term><term>Cortex</term><term>Cortex rostral</term><term>Cortical</term><term>Cortical architecture</term><term>Cortical layers</term><term>Cortical regions</term><term>Cytoarchitectural areas</term><term>Dasypus novemcinctus</term><term>Degeneration</term><term>Didelphis virginiana</term><term>Digit</term><term>Distinct layer</term><term>Dorsal</term><term>Ebner</term><term>Electrical stimulation</term><term>Fissure</term><term>Forelimb</term><term>Frontal section</term><term>Golgi</term><term>Golgi material</term><term>Golgi preparations</term><term>Granule</term><term>Granule cells</term><term>Harting</term><term>Hedgehog</term><term>High power photomicrograph</term><term>Higher power</term><term>Higher power photomicrograph</term><term>Insular</term><term>Insular cortex</term><term>Kaas</term><term>Krieg</term><term>Large area</term><term>Lateral</term><term>Lateral aspect</term><term>Lateral geniculate body</term><term>Layer</term><term>Lende</term><term>Marsupial phalanger</term><term>Medial</term><term>Medial peristriate cortex</term><term>Motor area</term><term>Motor areas</term><term>Motor representation</term><term>Motor responses</term><term>Myelinated fibers</term><term>Neocortex</term><term>Neur</term><term>Neuron</term><term>Numeral</term><term>Olfactory</term><term>Olfactory bulb</term><term>Opossum</term><term>Other species</term><term>Outer bands</term><term>Pectoral region</term><term>Peristriate</term><term>Peristriate areas</term><term>Peristriate cortex</term><term>Photomicrograph</term><term>Postsupraorbital</term><term>Potential results</term><term>Power photomicrograph</term><term>Presupraorbital</term><term>Presupraorbital cortex</term><term>Pyramidal</term><term>Pyramidal cells</term><term>Pyramidal neurons</term><term>Pyriform</term><term>Pyriform cortex</term><term>Retrosplenial</term><term>Retrosplenial area</term><term>Retrosplenial cortex</term><term>Rhinal</term><term>Rhinal fissure</term><term>Roman numerals</term><term>Rostral</term><term>Rostrally</term><term>Royce</term><term>Sagittal</term><term>Sagittal sulcus</term><term>Sensory area</term><term>Sensory areas</term><term>Sensory representation</term><term>Sensory representations</term><term>Small granule cells</term><term>Snout</term><term>Somatic</term><term>Stellate cells</term><term>Striate</term><term>Striate area</term><term>Striate cortex</term><term>Striate region</term><term>Such cortex</term><term>Sulcus</term><term>Superficial zone</term><term>Supraorbital</term><term>Supraorbital sulcus</term><term>Suprasylvian</term><term>Suprasylvian sulcus</term><term>Temporal area</term><term>Temporal cortex</term><term>Temporal region</term><term>Thick layer</term><term>Thin layer</term><term>Thionin</term><term>Tree shrew</term><term>Ventral</term><term>Virginia opossum</term><term>Visual area</term><term>Visual cortex</term><term>Visual region</term><term>Visual stimuli</term><term>Wide layer</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Approximate region</term><term>Architectonic subdivisions</term><term>Armadillo</term><term>Armadillo brain</term><term>Armadillo neocortex</term><term>Auditory</term><term>Auditory area</term><term>Auditory cortex</term><term>Auditory region</term><term>Caudal</term><term>Caudal sequence</term><term>Cell clusters</term><term>Cerebral cortex</term><term>Comp</term><term>Cortex</term><term>Cortex rostral</term><term>Cortical</term><term>Cortical architecture</term><term>Cortical layers</term><term>Cortical regions</term><term>Cytoarchitectural areas</term><term>Dasypus novemcinctus</term><term>Degeneration</term><term>Didelphis virginiana</term><term>Digit</term><term>Distinct layer</term><term>Dorsal</term><term>Ebner</term><term>Electrical stimulation</term><term>Fissure</term><term>Forelimb</term><term>Frontal section</term><term>Golgi</term><term>Golgi material</term><term>Golgi preparations</term><term>Granule</term><term>Granule cells</term><term>Harting</term><term>Hedgehog</term><term>High power photomicrograph</term><term>Higher power</term><term>Higher power photomicrograph</term><term>Insular</term><term>Insular cortex</term><term>Kaas</term><term>Krieg</term><term>Large area</term><term>Lateral</term><term>Lateral aspect</term><term>Lateral geniculate body</term><term>Layer</term><term>Lende</term><term>Marsupial phalanger</term><term>Medial</term><term>Medial peristriate cortex</term><term>Motor area</term><term>Motor areas</term><term>Motor representation</term><term>Motor responses</term><term>Myelinated fibers</term><term>Neocortex</term><term>Neur</term><term>Neuron</term><term>Numeral</term><term>Olfactory</term><term>Olfactory bulb</term><term>Opossum</term><term>Other species</term><term>Outer bands</term><term>Pectoral region</term><term>Peristriate</term><term>Peristriate areas</term><term>Peristriate cortex</term><term>Photomicrograph</term><term>Postsupraorbital</term><term>Potential results</term><term>Power photomicrograph</term><term>Presupraorbital</term><term>Presupraorbital cortex</term><term>Pyramidal</term><term>Pyramidal cells</term><term>Pyramidal neurons</term><term>Pyriform</term><term>Pyriform cortex</term><term>Retrosplenial</term><term>Retrosplenial area</term><term>Retrosplenial cortex</term><term>Rhinal</term><term>Rhinal fissure</term><term>Roman numerals</term><term>Rostral</term><term>Rostrally</term><term>Royce</term><term>Sagittal</term><term>Sagittal sulcus</term><term>Sensory area</term><term>Sensory areas</term><term>Sensory representation</term><term>Sensory representations</term><term>Small granule cells</term><term>Snout</term><term>Somatic</term><term>Stellate cells</term><term>Striate</term><term>Striate area</term><term>Striate cortex</term><term>Striate region</term><term>Such cortex</term><term>Sulcus</term><term>Superficial zone</term><term>Supraorbital</term><term>Supraorbital sulcus</term><term>Suprasylvian</term><term>Suprasylvian sulcus</term><term>Temporal area</term><term>Temporal cortex</term><term>Temporal region</term><term>Thick layer</term><term>Thin layer</term><term>Thionin</term><term>Tree shrew</term><term>Ventral</term><term>Virginia opossum</term><term>Visual area</term><term>Visual cortex</term><term>Visual region</term><term>Visual stimuli</term><term>Wide layer</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">A functional map of the armadillo neocortex was produced by cortical stimulation and recording evoked potentials following somatic, auditory and visual stimuli. The results obtained were then correlated with the cortical architecture as revealed by Nissl, Golgi and myelin‐stained sections. Cortex rostral to the supraorbital sulcus has a wide layer IV and is mostly silent, except for a motor eye field and a part of the tongue sensory region in its caudal part. Two types of motor‐sensory cortex are present caudal to the supraorbital sulcus. Postsupraorbital I is mostly motor and has prominent pyramidal layers. Layer V is particuarly well developed and in rostral sections its superficial zone is broken up into clusters similar to the solid “barrels” seen in layer IV of other species. Postsupraorbital II has less prominent pyramidal layers and layers II and III are organized into clusters. This region corresponds to the sensory area for the limbs and trunk and the partially overlapping (surface recordings) sensory and motor areas for head, snout and tongue. Digits and limbs are rostral to the trunk representation in both the sensory and motor “homunculi.” Even though surface recording was employed, potentials evoked by visual stimuli could only be recorded from a small caudal area with a very thin layer IV. Although striate and peristriate areas appear similar in Nissl stained preparations, they can be readily differentiated in Weil stained sections. The stellate character of neurons in layer IV of the visual cortex is particularly apparent in Golgi material. Auditory evoked surface potentials were recorded from a broad oval region in the caudal lateral cortex which has a wide layer IV and aggregates of neurons in layers II and III. A Weil stain demonstrates inner and outer bands of Baillarger in this same region. The presumptive insular cortex is electrically silent to sensory stimulation and presents as a narrow band just dorsal to the rhinal fissure with indefinite cell lamination and little myelin.</div></front></TEI><affiliations><list><country><li>États-Unis</li></country><region><li>Caroline du Sud</li><li>Ohio</li><li>Wisconsin</li><li>État de New York</li></region></list><tree><country name="États-Unis"><region name="État de New York"><name sortKey="Royce, G James" sort="Royce, G James" uniqKey="Royce G" first="G. James" last="Royce">G. James Royce</name></region><name sortKey="Dom, Richard M" sort="Dom, Richard M" uniqKey="Dom R" first="Richard M." last="Dom">Richard M. Dom</name><name sortKey="Martin, George F" sort="Martin, George F" uniqKey="Martin G" first="George F." last="Martin">George F. Martin</name><name sortKey="Royce, G James" sort="Royce, G James" uniqKey="Royce G" first="G. James" last="Royce">G. James Royce</name><name sortKey="Royce, G James" sort="Royce, G James" uniqKey="Royce G" first="G. James" last="Royce">G. James Royce</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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