Your search keyword '"UAM. Departamento de Anatomía, Histología y Neurociencia"' showing total 2 results

1. Synaptic interactions between perifornical lateral hypothalamic area, locus coeruleus nucleus and the oral pontine reticular nucleus are implicated in the stage succession during sleep-wakefulness cycle

Author

M.L. Rodrigo-Angulo, Silvia Tortorella, Angel Nuñez, Miguel Garzón, and UAM. Departamento de Anatomía, Histología y Neurociencia

Subjects

Lateral hypothalamus, Medicina, Catecholaminergic receptors, lcsh:RC321-571, medicine, Premovement neuronal activity, Original Research Article, Wakefulness, Orexin-1 receptor, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Pharmacology, Chemistry, General Neuroscience, Bicuculline, Orexin, medicine.anatomical_structure, GABAergic receptors, nervous system, Locus coeruleus, REM sleep, Nucleus, Neuroscience, Oral pontine reticular nucleus, medicine.drug

Abstract

This Document is Protected by copyright and was first published by Frontiers. All rights reserved. it is reproduced with permission, The perifornical area in the posterior lateral hypothalamus (PeFLH) has been implicated in several physiological functions including the sleep-wakefulness regulation. The PeFLH area contains several cell types including those expressing orexins (Orx; also known as hypocretins), mainly located in the PeF nucleus. The aim of the present study was to elucidate the synaptic interactions between Orx neurons located in the PeFLH area and different brainstem neurons involved in the generation of wakefulness and sleep stages such as the locus coeruleus (LC) nucleus (contributing to wakefulness) and the oral pontine reticular nucleus (PnO) nucleus (contributing to REM sleep). Anatomical data demonstrated the existence of a neuronal network involving the PeFLH area, LC, and the PnO nuclei that would control the sleep-wake cycle. Electrophysiological experiments indicated that PeFLH area had an excitatory effect on LC neurons. PeFLH stimulation increased the firing rate of LC neurons and induced an activation of the EEG. The excitatory effect evoked by PeFLH stimulation in LC neurons was blocked by the injection of the Orx-1 receptor antagonist SB-334867 into the LC. Similar electrical stimulation of the PeFLH area evoked an inhibition of PnO neurons by activation of GABAergic receptors because the effect was blocked by bicuculline application into the PnO. Our data also revealed that the LC and PnO nuclei exerted a feedback control on neuronal activity of PeFLH area. Electrical stimulation of LC facilitated firing activity of PeFLH neurons by activation of catecholaminergic receptors whereas PnO stimulation inhibited PeFLH neurons by activation of GABAergic receptors. In conclusion, Orx neurons of the PeFLH area seem to be an important organizer of the wakefulness and sleep stages in order to maintain a normal succession of stages during the sleep-wakefulness cycle

Published

2013

2. Functional anatomy of non-REM sleep

Author

Fernando Reinoso-Suárez, Isabel de Andrés, Miguel Garzón, and UAM. Departamento de Anatomía, Histología y Neurociencia

Subjects

NREM sleep homeostasis, Sleep need, Medicina, Cellular homeostasis, Sleep spindle, Review Article, Rostral hypnogenic system, Sleep Spindles, Non-rapid eye movement sleep, lcsh:RC346-429, sleep need, Thalamus-cerebral cortex unit, Slow wave sleep, thalamus–cerebral cortex unit, mental disorders, slow wave activity, slow wave sleep, lcsh:Neurology. Diseases of the nervous system, Slow-wave sleep, rostral hypnogenic system, musculoskeletal, neural, and ocular physiology, Caudal hypnogenic system, Sleep in non-human animals, Neurology, caudal hypnogenic system, Wakefulness, Neurology (clinical), Sleep onset, Psychology, K-complex, Neuroscience, psychological phenomena and processes

Abstract

The state of non-REM sleep (NREM), or slow wave sleep, is associated with a synchronized EEG pattern in which sleep spindles and/or K complexes and high-voltage slow wave activity (SWA) can be recorded over the entire cortical surface. In humans, NREM is subdivided into stages 2 and 3–4 (presently named N3) depending on the proportions of each of these polygraphic events. NREM is necessary for normal physical and intellectual performance and behavior. An overview of the brain structures involved in NREM generation shows that the thalamus and the cerebral cortex are absolutely necessary for the most significant bioelectric and behavioral events of NREM to be expressed; other structures like the basal forebrain, anterior hypothalamus, cerebellum, caudal brain stem, spinal cord and peripheral nerves contribute to NREM regulation and modulation. In NREM stage 2, sustained hyperpolarized membrane potential levels resulting from interaction between thalamic reticular and projection neurons gives rise to spindle oscillations in the membrane potential; the initiation and termination of individual spindle sequences depends on corticothalamic activities. Cortical and thalamic mechanisms are also involved in the generation of EEG delta SWA that appears in deep stage 3–4 (N3) NREM; the cortex has classically been considered to be the structure that generates this activity, but delta oscillations can also be generated in thalamocortical neurons. NREM is probably necessary to normalize synapses to a sustainable basal condition that can ensure cellular homeostasis. Sleep homeostasis depends not only on the duration of prior wakefulness but also on its intensity, and sleep need increases when wakefulness is associated with learning. NREM seems to ensure cell homeostasis by reducing the number of synaptic connections to a basic level; based on simple energy demands, cerebral energy economizing during NREM sleep is one of the prevalent hypotheses to explain NREM homeostasis., Grant BFU2009-06991/BFI from the Spanish Ministry of Science and Innovation supported this work

Published

2011