A Golgi study of the principal projection neurons of the medial cortex of the lizardPodarcis hispanica

Iglesia, José Antonio Luis de la; López‐García, Carlos

doi:10.1002/(sici)1096-9861(19970908)385:4<528::aid-cne4>3.0.co;2-5

Cited by 27 publications

(15 citation statements)

References 107 publications

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“…The classification criteria, such as the differential dendritic tree pattern, dendritic spine covering, axonal arborization and soma shape and size, suggest that three main types of neurons occur in the corticoid complex of E. amandava: projection neurons, local circuit neurons and stellate neurons. In the case of reptiles, the types of neurons seem to be variable (Wouterlood 1981;Berbel et al 1987;Guirado et al 1987;Luis de la Iglasia et al 1994;Luis de la Iglesia and Lopez-Garcia 1997;Maurya and Srivastava 2006), whereas in the present study on the strawberry finch and in previous reports of the types of neurons in the hippocampal region of birds (Montagnese et al 1996;Tömböl et al 2000aTömböl et al , 2000bSrivastava et al 2007a), neuronal types are consistent and independent of the number of individuals studied.…”

Section: Discussionsupporting

confidence: 70%

Neuronal classes in the corticoid complex of the telencephalon of the strawberry finch, Estrilda amandava

2009

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The present study, based on neurohistological techniques (Nissl-staining, Golgi-impregnation), focuses on the cytoarchitecture of the corticoid complex in the strawberry finch, Estrilda amandava. This complex in birds occupies the dorsolateral surface of the telencephalic pallium and remains subdivided into an intermediate corticoid area (CI) and a dorsolateral corticoid area (CDL). The CDL in the strawberry finch is a thin superficial part of the caudal pallium adjoining the medially situated hippocampal formation, whereas the CI is demarcated between the CDL and the parahippocampal area of telencephalon. Neurons of the corticoid complex are classified into three main cell groups: predominant projection neurons, local circuit neurons and stellate neurons. The spinous projection neurons send out distant projecting axons that typically extend several varicose collaterals. Most of these collaterals lie parallel to the ventricle. These neurons are subclassified into pyramidal neurons (localized only in the CI) and multipolar neurons (present in both the CI and CDL). The CDL also possesses small and medium-sized horizontal cells, which are bitufted or multipolar with smooth, moderately branching dendrites. The aspinous local circuit neurons extend short axons that ramify locally. Stellate neurons have sparse spinous dendrites and locally arborizing axons. The corticoid complex of birds corresponds to the lateral cerebral cortex of lizards and to the entorhinal cortex of mammals on the basis of neuronal morphology and bidirectional connections between adjacent areas.

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Section: Discussionsupporting

confidence: 70%

Neuronal classes in the corticoid complex of the telencephalon of the strawberry finch, Estrilda amandava

2009

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“…The pyramidal neurons accounting for at least 70% of the total neocortical population in mammals form the principal element in neocortical circuit. The evolutionary trend of pyramidal neurons' development can be traced right from "extraverted" neurons observed in amphibian pallium; pyramid-like neurons in reptilian cortex (Luis de la Iglasia and Lopez Garcia, 1997;Srivastava et al, 2007Srivastava et al, , 2009b; in hippocampus of homing pigeon, chick (T€ omb€ ol et al, 2000); corticoid complex in strawberry finch (Srivastava et al, 2009a) to the well developed neocortical elements referred by Cajal as "psychic cells" (Nieuwenhuys, 1994). The different aspects of pyramidal cell microanatomy may influence different aspects of cellular, and systems function (Elston and DeFelipe, 2002;Ha€usser and Mel, 2003;Segev et al, 2001).…”

Section: Discussionmentioning

confidence: 99%

Heterogeneity of spine density in pyramidal neurons of isocortex of mongoose, Herpestes edwardsii (É. Geoffroy Saint‐Hilaire 1818)

Srivastava

Singh

Chauhan

2013

Microscopy Res & Technique

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The characteristics of pyramidal neurons within six layers of Indian gray mongoose (Herpestes edwardsii) isocortex have been investigated using Golgi and Cresyl-Violet methods. Pyramidal neurons and the cytoarchitecture of isocortex of mongoose were photographed with the help of computer aided Nikon eclipse 80i microscope whereas the lucida drawings were made by simple light microscope equipped with camera lucida. The cortical neurons exhibit marked regional differences in phenotype. The differences occur in morphology and distribution of spines within the cortical neurons not only among different species but also within an animal's brain. The present investigation aims at studying the features of pyramidal neurons and to find out the differences if any in distribution of spines in different layers (II-VI) as well as regions (Frontal, Temporal, Parietal, and Occipital) of isocortex of mongoose, which will provide information regarding importance of different layer and region. This piece of work embarks the findings that spine density shows inter-regional as well as interlaminar variations within isocortex of mongoose indicating that pyramidal cells present in varied layer and region are not equally functional and there do exists differences in activity among layers and regions. Among regions, the Temporal region possessing highest spine density contributes more toward functioning of mongoose isocortex and might play significant role in predatory nature of mongoose because this region in mammals is associated with auditory, visual perception, and object recognition.

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“…The medial cortex of the lizard is a trilaminar region that exhibits many characteristics similar to the mammalian dentate gyrus, as demonstrated by the Golgi impregnation method and immunocytochemistry studies [68,69]. The neuronal types of the dorsomedial cortex of reptiles, the parahippocampal area in birds, and the CA3 region in mammals may present with homology [70] (Figure 1).…”

Section: Adult Neurogenesis In Reptilesmentioning

confidence: 99%

Adult Hippocampal Neurogenesis in Different Taxonomic Groups: Possible Functional Similarities and Striking Controversies

Augusto-Oliveira

Arrifano

Malva

et al. 2019

Cells

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Adult neurogenesis occurs in many species, from fish to mammals, with an apparent reduction in the number of both neurogenic zones and new neurons inserted into established circuits with increasing brain complexity. Although the absolute number of new neurons is high in some species, the ratio of these cells to those already existing in the circuit is low. Continuous replacement/addition plays a role in spatial navigation (migration) and other cognitive processes in birds and rodents, but none of the literature relates adult neurogenesis to spatial navigation and memory in primates and humans. Some models developed by computational neuroscience attribute a high weight to hippocampal adult neurogenesis in learning and memory processes, with greater relevance to pattern separation. In contrast to theories involving neurogenesis in cognitive processes, absence/rarity of neurogenesis in the hippocampus of primates and adult humans was recently suggested and is under intense debate. Although the learning process is supported by plasticity, the retention of memories requires a certain degree of consolidated circuitry structures, otherwise the consolidation process would be hampered. Here, we compare and discuss hippocampal adult neurogenesis in different species and the inherent paradoxical aspects.

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A Golgi study of the principal projection neurons of the medial cortex of the lizardPodarcis hispanica

Cited by 27 publications

References 107 publications

Neuronal classes in the corticoid complex of the telencephalon of the strawberry finch, Estrilda amandava

Neuronal classes in the corticoid complex of the telencephalon of the strawberry finch, Estrilda amandava

Heterogeneity of spine density in pyramidal neurons of isocortex of mongoose, Herpestes edwardsii (É. Geoffroy Saint‐Hilaire 1818)

Adult Hippocampal Neurogenesis in Different Taxonomic Groups: Possible Functional Similarities and Striking Controversies

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