Topographical organization of the projections from the reticular thalamic nucleus to the intralaminar and medial thalamic nuclei in the cat

Velayos, J. L.; Jiménez‐Castellanos, J.; Reinoso‐Suárez, Fernando

doi:10.1002/cne.902790310

Cited by 86 publications

(36 citation statements)

References 34 publications

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“…These findings are in good agreement with the results of studies in the rat and cat Velayos et al, 1989;Lozsadi, 1995;Gonzalo-Ruiz and Lieberman, 1995;Kolmac and Mitrofanis, 1997) that also described connections of the anterior pole with a variety of a,c,f), the symmetric nature of the synapse with some underlying dense substance is clearly seen. In b, e, and f note also Puncta aedherentia to the right from synaptic contacts.…”

Section: Discussionsupporting

confidence: 91%

“…However, it is not clear whether this concept can be extrapolated to all NRT sectors, specifically those related to the motor, limbic, association, and intralaminar nuclei connected with the frontal lobe. Based on retrograde tracing studies in cats and rats, it has been suggested that the rostral NRT sector or anterior pole as it is also known, is organized differently from the sensory sectors: it is connected with a large number of thalamic nuclei, including intralaminar, midline, and limbic without precise topography (Velayos et al, 1989;Gonzalo-Ruiz and Lieberman, 1995;Lozsadi, 1995;Kolmac and Mitrofanis, 1997;Lizier et al, 1997). Recent anterograde tracing studies (Yi et al, 1993;Kultas-Ilinsky et al, 1995;Tai et al, 1995) have further confirmed the connections of the anterior sector of the NRT with the same nuclei in the rhesus monkey as well.…”

mentioning

confidence: 99%

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Organization of projections from the anterior pole of the nucleus reticularis thalami (NRT) to subdivisions of the motor thalamus: Light and electron microscopic studies in the Rhesus monkey

1999

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Section: Discussionsupporting

confidence: 91%

mentioning

confidence: 99%

Organization of projections from the anterior pole of the nucleus reticularis thalami (NRT) to subdivisions of the motor thalamus: Light and electron microscopic studies in the Rhesus monkey

1999

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“…Anterograde labeling is faint in VM-VL. Terminallike labeling is visible in the anterodorsal zone of the pregeniculate sector (Velayos et al, 1989) of the reticular thalamic nucleus. Thereon, labeled axons can be followed medially and caudally as they traverse the ventral thalamic complex en route to PoM and LM, arranged in conspicuous small bundles.…”

Section: Labeling In the Thalamus After Cortical Injectionsmentioning

confidence: 98%

“…Interestingly, the bundle of axons directed to the thalamus and other subcortical structures follows a route ventral to the putamen into the sublenticular portion of the internal capsule, whereas after injections in the other areas of the orbitosylvian region these fibers always follow a dorsal route into the main, dorsal portion of the internal capsule. When passing through the most caudal part of the infrageniculate sector (Velayos et al, 1989) of the reticular thalamic nucleus, labeled axons leave terminal-like labeling. Thereon, axons travel within the acoustic radiation toward the caudal pole of the medial geniculate complex.…”

Section: Labeling In the Thalamus After Cortical Injectionsmentioning

confidence: 99%

Insular cortex and neighboring fields in the cat: A redefinition based on cortical microarchitecture and connections with the thalamus

1997

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The insular areas of the cerebral cortex in carnivores remain vaguely defined and fragmentarily characterized. We have examined the cortical microarchitecture and thalamic connections of the insular region in cats, as a part of a broader study aimed to clarify their subdivisions, functional affiliations, and eventual similarities with other mammals. We report that cortical areas, which resemble the insular fields of other mammals, are located in the cat's orbital gyrus and anterior rhinal sulcus. Our data suggest four such areas: (a) a "ventral agranular insular area" in the lower bank of the anterior rhinal sulcus, architectonically transitional between iso- and allocortex and sparsely connected to the thalamus, mainly with midline nuclei; (b) a "dorsal agranular insular area" in the upper bank of the anterior rhinal sulcus, linked to the mediodorsal, ventromedial, parafascicular and midline nuclei; (c) a "dysgranular insular area" in the anteroventral half of the orbital gyrus, characterized by its connections with gustatory and viscerosensory portions of the ventroposterior complex and with the ventrolateral nucleus; and (d) a "granular insular area", dorsocaudal in the orbital gyrus, which is chiefly bound to spinothalamic-recipient thalamic nuclei such as the posterior medial and the ventroposterior inferior. Three further fields are situated caudally to the insular areas. The anterior sylvian gyrus and dorsal lip of the pseudosylvian sulcus, which we designate "anterior sylvian area", is connected to the ventromedial, suprageniculate, and lateralis medialis nuclei. The fundus and ventral bank of the pseudosylvian sulcus, or "parainsular area", is associated with caudal portions of the medial geniculate complex. The rostral part of the ventral bank of the anterior ectosylvian sulcus, referred to as "ventral anterior ectosylvian area", is heavily interconnected with the lateral posterior-pulvinar complex and the ventromedial nucleus. Present results reveal that these areas interact with a wide array of sensory, motor, and limbic thalamic nuclei. In addition, these data provide a consistent basis for comparisons with cortical fields in other mammals.

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“…As a result of this disfacilitation, thalamic neurons would become sufficiently hyperpolarized to change their firing mode from tonic to phasic, as occurs in the transition to SWS (Steriade et al, 1994). Moreover, the thalamic reticularis neurons, which contain GABA (Houser et al, 1980) and project onto thalamic relay neurons, including midline, medial, and intralaminar nuclei of the diffuse thalamocortical projection system Jones, 1985;Velayos et al, 1989), would begin to burst, hyperpolarizing the thalamocortical neurons and entraining them first in a spindle and then ␦ rhythmicity (von Krosigk et al, 1993;Steriade et al, 1994). Thalamic neurons also oscillate in a slower rhythm with long-lasting hyperpolarizations in association with the "slow oscillation" on the cortex (Ͻ1 Hz) (Contreras et al, 1996), a recently described sleep rhythm (Steriade et al, 1994) that was not measured in the present study.…”

Section: Negative Covariation Of Rcbf With ␦ Ormentioning

confidence: 99%

Regional Cerebral Blood Flow Changes as a Function of Delta and Spindle Activity during Slow Wave Sleep in Humans

et al. 1997

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In the present study, we investigated changes in regional cerebral blood flow (rCBF) in humans during the progression from relaxed wakefulness through slow wave sleep (SWS). These changes were examined as a function of spindle (12-15 Hz) and ␦ (1.5-4.0 Hz) electroencephalographic (EEG) activity of SWS. rCBF was studied with positron emission tomography (PET) using the H 2 15 O bolus method. A maximum of six 60 sec scans were performed per subject during periods of wakefulness and stages 1-4 of SWS, as determined by on-line EEG monitoring. Spectral analysis was performed off-line on the EEG epochs corresponding to the scans for computation of activity in specific frequency bands. The relationship between EEG frequency band activity and normalized rCBF was determined by means of a voxel-by-voxel analysis of covariance. ␦ activity covaried negatively with rCBF most markedly in the thalamus and also in the brainstem reticular formation, cerebellum, anterior cingulate, and orbitofrontal cortex. After the effect of ␦ was removed, a significant negative covariation between spindle activity and the residual rCBF was evident in the medial thalamus. These negative covariations may reflect the disfacilitation and active inhibition of thalamocortical relay neurons in association with ␦ and spindles, as well as the neural substrates underlying the progressive attenuation of sensory awareness, motor responsiveness, and arousal that occur during SWS. ␦ activity covaried positively with rCBF in the visual and auditory cortex, possibly reflecting processes of dream-like mentation purported to occur during SWS.

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Topographical organization of the projections from the reticular thalamic nucleus to the intralaminar and medial thalamic nuclei in the cat

Cited by 86 publications

References 34 publications

Organization of projections from the anterior pole of the nucleus reticularis thalami (NRT) to subdivisions of the motor thalamus: Light and electron microscopic studies in the Rhesus monkey

Organization of projections from the anterior pole of the nucleus reticularis thalami (NRT) to subdivisions of the motor thalamus: Light and electron microscopic studies in the Rhesus monkey

Insular cortex and neighboring fields in the cat: A redefinition based on cortical microarchitecture and connections with the thalamus

Regional Cerebral Blood Flow Changes as a Function of Delta and Spindle Activity during Slow Wave Sleep in Humans

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