scholarly journals Selectively driving cholinergic fibers optically in the thalamic reticular nucleus promotes sleep

eLife ◽  
2016 ◽  
Vol 5 ◽  
Author(s):  
Kun-Ming Ni ◽  
Xiao-Jun Hou ◽  
Ci-Hang Yang ◽  
Ping Dong ◽  
Yue Li ◽  
...  
Keyword(s):  
Eye Movement ◽  
Nicotinic Acetylcholine Receptors ◽  
Rem Sleep ◽  
Sleep Onset ◽  
Cholinergic Neurons ◽  
Nrem Sleep ◽  
Gabaergic Neurons ◽  
Thalamic Reticular Nucleus ◽  
Reticular Nucleus ◽  
Rapid Eye Movement

Cholinergic projections from the basal forebrain and brainstem are thought to play important roles in rapid eye movement (REM) sleep and arousal. Using transgenic mice in which channelrhdopsin-2 is selectively expressed in cholinergic neurons, we show that optical stimulation of cholinergic inputs to the thalamic reticular nucleus (TRN) activates local GABAergic neurons to promote sleep and protect non-rapid eye movement (NREM) sleep. It does not affect REM sleep. Instead, direct activation of cholinergic input to the TRN shortens the time to sleep onset and generates spindle oscillations that correlate with NREM sleep. It does so by evoking excitatory postsynaptic currents via α7-containing nicotinic acetylcholine receptors and inducing bursts of action potentials in local GABAergic neurons. These findings stand in sharp contrast to previous reports of cholinergic activity driving arousal. Our results provide new insight into the mechanisms controlling sleep.

scholarly journals A role for spindles in the onset of rapid eye movement sleep

2020 ◽  
Vol 11 (1) ◽  
Author(s):  
Mojtaba Bandarabadi ◽  
Carolina Gutierrez Herrera ◽  
Thomas C. Gent ◽  
Claudio Bassetti ◽  
Kaspar Schindler ◽  
...  
Keyword(s):  
Eye Movement ◽  
Rem Sleep ◽  
Nrem Sleep ◽  
State Regulation ◽  
Thalamic Reticular Nucleus ◽  
Reticular Nucleus ◽  
Rapid Eye Movement ◽  
Thalamic Nuclei ◽  
Sleep State ◽  
Field Coupling

Abstract Sleep spindle generation classically relies on an interplay between the thalamic reticular nucleus (TRN), thalamo-cortical (TC) relay cells and cortico-thalamic (CT) feedback during non-rapid eye movement (NREM) sleep. Spindles are hypothesized to stabilize sleep, gate sensory processing and consolidate memory. However, the contribution of non-sensory thalamic nuclei in spindle generation and the role of spindles in sleep-state regulation remain unclear. Using multisite thalamic and cortical LFP/unit recordings in freely behaving mice, we show that spike-field coupling within centromedial and anterodorsal (AD) thalamic nuclei is as strong as for TRN during detected spindles. We found that spindle rate significantly increases before the onset of rapid eye movement (REM) sleep, but not wakefulness. The latter observation is consistent with our finding that enhancing spontaneous activity of TRN cells or TRN-AD projections using optogenetics increase spindle rate and transitions to REM sleep. Together, our results extend the classical TRN-TC-CT spindle pathway to include non-sensory thalamic nuclei and implicate spindles in the onset of REM sleep.

scholarly journals Vesicular GABA-transporter neurons in the zona incerta are maximally active during non rapid-eye movement (NREM) and rapid-eye movement (REM) sleep

2020 ◽  
Author(s):  
Carlos Blanco-Centurion ◽  
SiWei Luo ◽  
Aurelio Vidal-Ortiz ◽  
Priyattam J. Shiromani
Keyword(s):  
Eye Movement ◽  
Lateral Hypothalamus ◽  
Rem Sleep ◽  
Sleep Onset ◽  
Nrem Sleep ◽  
Zona Incerta ◽  
Imaging Method ◽  
Rapid Eye Movement ◽  
Gaba Transporter

AbstractSleep and wake are opposing behavioral states controlled by the activity of specific neurons. The neurons responsible for sleep/wake control have not been fully identifed due to the lack of in-vivo high throughput technology. We use the deep-brain calcium (Ca2+) imaging method to identify activity of hypothalamic neurons expressing the vesicular GABA transporter (vGAT), a marker of GABAergic neurons. vGAT-cre mice (n=5) were microinjected with rAAV-FLEX-GCaMP6M into the lateral hypothalamus and 21d later the Ca2+ influx in vGAT neurons (n=372) was recorded in freely-behaving mice during waking (W), NREM and REM sleep. Post-mortem analysis revealed the lens tip located in the zona incerta/lateral hypothalamus (ZI-LH) and the change in fluorescence of neurons in the field of view was as follows: 54.9% of the vGAT neurons had peak fluorescence during REM sleep (REM-max), 17.2% were NREM-max, 22.8% were wake-max while 5.1% were both wake+REM max. Thus, three quarters of the recorded vGAT neurons in the ZI-LH were most active during sleep. In the NREM-max group Ca2+ fluorescence anticipated the initiation of NREM sleep onset and remained high throughout sleep (NREM and REM sleep). In the REM-max neurons Ca2+fluorescence increased before the onset of REM sleep and stayed elevated during the episode. Activation of the vGAT NREM-max neurons in the zona incerta and dorsal lateral hypothalamus would inhibit the arousal neurons to initiate and maintain sleep.

scholarly journals Microglia modulate stable wakefulness via the thalamic reticular nucleus in mice

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Hanxiao Liu ◽  
Xinxing Wang ◽  
Lu Chen ◽  
Liang Chen ◽  
Stella E. Tsirka ◽  
...  
Keyword(s):  
Diurnal Variation ◽  
Eye Movement ◽  
Nrem Sleep ◽  
Thalamic Reticular Nucleus ◽  
Reticular Nucleus ◽  
Rapid Eye Movement ◽  
Metabolomic Analysis ◽  
The Brain ◽  
Ceramide Production ◽  
Brain Homeostasis

AbstractMicroglia are important for brain homeostasis and immunity, but their role in regulating vigilance remains unclear. We employed genetic, physiological, and metabolomic methods to examine microglial involvement in the regulation of wakefulness and sleep. Microglial depletion decreased stable nighttime wakefulness in mice by increasing transitions between wakefulness and non-rapid eye movement (NREM) sleep. Metabolomic analysis revealed that the sleep-wake behavior closely correlated with diurnal variation of the brain ceramide, which disappeared in microglia-depleted mice. Ceramide preferentially influenced microglia in the thalamic reticular nucleus (TRN), and local depletion of TRN microglia produced similar impaired wakefulness. Chemogenetic manipulations of anterior TRN neurons showed that they regulated transitions between wakefulness and NREM sleep. Their firing capacity was suppressed by both microglial depletion and added ceramide. In microglia-depleted mice, activating anterior TRN neurons or inhibiting ceramide production both restored stable wakefulness. These findings demonstrate that microglia can modulate stable wakefulness through anterior TRN neurons via ceramide signaling.

scholarly journals Glutamatergic neurons in the preoptic hypothalamus promote wakefulness, destabilize NREM sleep, suppress REM sleep, and regulate cortical dynamics

2020 ◽  
Author(s):  
Alejandra Mondino ◽  
Viviane Hambrecht-Wiedbusch ◽  
Duan Li ◽  
A. Kane York ◽  
Dinesh Pal ◽  
...  
Keyword(s):  
Eye Movement ◽  
Rem Sleep ◽  
Preoptic Area ◽  
Sleep Onset ◽  
Nrem Sleep ◽  
State Transitions ◽  
Rapid Eye Movement ◽  
Cortical Dynamics ◽  
Glutamatergic Neurons ◽  
Conditional Expression

ABSTRACTClinical and experimental data from the last nine decades indicate that the preoptic area of the hypothalamus is a critical node in a brain network that controls sleep onset and homeostasis. By contrast, we recently reported that a group of glutamatergic neurons in the lateral and medial preoptic area increases wakefulness, challenging the long-standing notion in sleep neurobiology that the preoptic area is exclusively somnogenic. However, the precise role of these subcortical neurons in the control of behavioral state transitions and cortical dynamics remains unknown. Therefore, in this study we used conditional expression of excitatory hM3Dq receptors in these preoptic glutamatergic (Vglut2+) neurons and show that their activation initiates wakefulness, decreases non-rapid eye movement (NREM) sleep, and causes a persistent suppression of rapid eye movement (REM) sleep. Activation of preoptic glutamatergic neurons also causes a high degree of NREM sleep fragmentation, promotes state instability with frequent arousals from sleep, and shifts cortical dynamics (including oscillations, connectivity, and complexity) to a more wake-like state. We conclude that a subset of preoptic glutamatergic neurons may initiate -but not maintain- arousals from sleep, and their inactivation may be required for NREM stability and REM sleep generation. Further, these data provide novel empirical evidence supporting the conclusion that the preoptic area causally contributes to the regulation of both sleep and wakefulness.

scholarly journals Neurophysiological control of sleep with special emphasis on melatonin

2020 ◽  
Vol 18 (4) ◽  
pp. 355-376
Author(s):  
Iv. Penchev Georgiev
Keyword(s):  
Sleep Disorders ◽  
Eye Movement ◽  
Rem Sleep ◽  
Sleep Onset ◽  
Vascular Diseases ◽  
Nrem Sleep ◽  
Brain Structures ◽  
Rapid Eye Movement ◽  
Human Beings ◽  
Melatonin Receptor Agonists

Sleep and wakefulness are two main types of human and animal behavior. On the average human beings spend about one-third of their lives asleep. The sleep-wake cycle is the most important circadian rhythms which alternates in a periodic manner lasting for about 24 hours. Sleep is determined as the natural periodic suspension of consciousness characterized by relative immobility and reduced responsiveness to external stimuli. The researchers have found and identified many special brain structures and systems controlling waking, rapid eye movement (REM) sleep and non-rapid eye (NREM) sleep and the transitions among these states. Currently, there is an enhanced interest of researchers toward sleep and its neurophysiological mechanisms of regulation because the number of people suffering from various sleep disturbance such as insomnia, delayed sleep onset, duration and propensity of sleep, worldwide dramatically increases. In addition to the next day drowsiness, nervousness, tiredness and decreased workability, it has been suggested that sleep is important also for the maintaining of mood, memory and cognitive function of the brain and is essential for the normal functioning of the endocrine and immune systems. More recently, new studies show a sustained link between sleep disorders and different serious health problems, including obesity, insulin resistance, type 2 diabetes mellitus, cardio-vascular diseases and depression. Therefore, the purpose of this review is to summarize and analyze the available data about the neurological control of wakefulness, non-rapid-eye-movement (NREM) sleep and rapid- eye-movement (REM) sleep creating a substantial basis for better understanding different sleep disorders. Special attention is paid on the pharmacological aspects and use of some new classes of sleep promoting agents – melatonin, melatonin receptor agonists and orexin receptor antagonists.

scholarly journals Structural organization of dream experience during daytime sleep-onset rapid eye movement period sleep of patients with narcolepsy type 1

SLEEP ◽  
2020 ◽  
Vol 43 (8) ◽  
Author(s):  
Carlo Cipolli ◽  
Fabio Pizza ◽  
Claudia Bellucci ◽  
Michela Mazzetti ◽  
Giovanni Tuozzi ◽  
...  
Keyword(s):  
Eye Movement ◽  
Rem Sleep ◽  
Structural Organization ◽  
Sleep Onset ◽  
Nrem Sleep ◽  
Rapid Eye Movement ◽  
Story Grammar ◽  
Late Night ◽  
Grammar Analysis

Abstract Study Objective To assess the frequency of dream experience (DE) developed during naps at Multiple Sleep Latency Test (MSLT) by patients with narcolepsy type 1 (NT1) and establish, using story-grammar analysis, the structural organization of DEs developed during naps with sleep onset rapid eye movement (REM) period (SOREMP) sleep compared with their DEs during early- and late-night REM sleep. Methods Thirty drug-free cognitively intact adult NT1 patients were asked to report DE developed during each MSLT nap. Ten NT1 patients also spent voluntarily a supplementary night being awakened during the first-cycle and third-cycle REM sleep. Patients provided dream reports, white dreams, and no dreams, whose frequencies were matched in naps with SOREMP versus non-REM (NREM) sleep. All dream reports were then analyzed using story-grammar rules. Results DE was recalled in detail (dream report) by NT1 patients after 75% of naps with SOREMP sleep and after 25% of naps with NREM sleep. Dream reports were provided by 8 out of 10 NT1 patients after both awakenings from nighttime REM sleep. Story-grammar analysis of dream reports showed that SOREMP-DEs are organized as hierarchically ordered sequences of events (so-called dream-stories), which are longer and more complex in the first and fourth SOREMP naps and are comparable with nighttime REM-DEs. Conclusions The similar structural organization of SOREMP-DEs with nighttime REM-DEs indicates that their underlying cognitive processes are highly, albeit not uniformly, effective during daytime SOREMP sleep. Given the peculiar neurophysiology of SOREMP sleep, investigating SOREMP-DEs may cast further light on the relationships between the neurophysiological and psychological processes involved in REM-dreaming.

scholarly journals Control of Sleep and Wakefulness

2012 ◽  
Vol 92 (3) ◽  
pp. 1087-1187 ◽  
Author(s):  
Ritchie E. Brown ◽  
Radhika Basheer ◽  
James T. McKenna ◽  
Robert E. Strecker ◽  
Robert W. McCarley
Keyword(s):  
Brain Stem ◽  
Eye Movement ◽  
Rem Sleep ◽  
Emotional Reactivity ◽  
Low Voltage ◽  
Nrem Sleep ◽  
Gabaergic Neurons ◽  
Cortical Activation ◽  
Rapid Eye Movement ◽  
The Brain

This review summarizes the brain mechanisms controlling sleep and wakefulness. Wakefulness promoting systems cause low-voltage, fast activity in the electroencephalogram (EEG). Multiple interacting neurotransmitter systems in the brain stem, hypothalamus, and basal forebrain converge onto common effector systems in the thalamus and cortex. Sleep results from the inhibition of wake-promoting systems by homeostatic sleep factors such as adenosine and nitric oxide and GABAergic neurons in the preoptic area of the hypothalamus, resulting in large-amplitude, slow EEG oscillations. Local, activity-dependent factors modulate the amplitude and frequency of cortical slow oscillations. Non-rapid-eye-movement (NREM) sleep results in conservation of brain energy and facilitates memory consolidation through the modulation of synaptic weights. Rapid-eye-movement (REM) sleep results from the interaction of brain stem cholinergic, aminergic, and GABAergic neurons which control the activity of glutamatergic reticular formation neurons leading to REM sleep phenomena such as muscle atonia, REMs, dreaming, and cortical activation. Strong activation of limbic regions during REM sleep suggests a role in regulation of emotion. Genetic studies suggest that brain mechanisms controlling waking and NREM sleep are strongly conserved throughout evolution, underscoring their enormous importance for brain function. Sleep disruption interferes with the normal restorative functions of NREM and REM sleep, resulting in disruptions of breathing and cardiovascular function, changes in emotional reactivity, and cognitive impairments in attention, memory, and decision making.

Sleep Disorders

2015 ◽  
Author(s):  
Sudhansu Chokroverty
Keyword(s):  
Sleep Apnea ◽  
Sleep Disorders ◽  
Eye Movement ◽  
Rem Sleep ◽  
Sleep Apnea Syndrome ◽  
Nrem Sleep ◽  
Rapid Eye Movement ◽  
Circadian Rhythm Sleep Disorders ◽  
Apnea Syndrome ◽  
Sleep Mechanism

Recent research has generated an enormous fund of knowledge about the neurobiology of sleep and wakefulness. Sleeping and waking brain circuits can now be studied by sophisticated neuroimaging techniques that map different areas of the brain during different sleep states and stages. Although the exact biologic functions of sleep are not known, sleep is essential, and sleep deprivation leads to impaired attention and decreased performance. Sleep is also believed to have restorative, conservative, adaptive, thermoregulatory, and consolidative functions. This review discusses the physiology of sleep, including its two independent states, rapid eye movement (REM) and non–rapid eye movement (NREM) sleep, as well as functional neuroanatomy, physiologic changes during sleep, and circadian rhythms. The classification and diagnosis of sleep disorders are discussed generally. The diagnosis and treatment of the following disorders are described: obstructive sleep apnea syndrome, narcolepsy-cataplexy sydrome, idiopathic hypersomnia, restless legs syndrome (RLS) and periodic limb movements in sleep, circadian rhythm sleep disorders, insomnias, nocturnal frontal lobe epilepsy, and parasomnias. Sleep-related movement disorders and the relationship between sleep and psychiatric disorders are also discussed. Tables describe behavioral and physiologic characteristics of states of awareness, the international classification of sleep disorders, common sleep complaints, comorbid insomnia disorders, causes of excessive daytime somnolence, laboratory tests to assess sleep disorders, essential diagnostic criteria for RLS and Willis-Ekbom disease, and drug therapy for insomnia. Figures include polysomnographic recording showing wakefulness in an adult; stage 1, 2, and 3 NREM sleep in an adult; REM sleep in an adult; a patient with sleep apnea syndrome; a patient with Cheyne-Stokes breathing; a patient with RLS; and a patient with dream-enacting behavior; schematic sagittal section of the brainstem of the cat; schematic diagram of the McCarley-Hobson model of REM sleep mechanism; the Lu-Saper “flip-flop” model; the Luppi model to explain REM sleep mechanism; and a wrist actigraph from a man with bipolar disorder. This review contains 14 highly rendered figures, 8 tables, 115 references, and 5 MCQs.

Sleep Disorders

2015 ◽  
Author(s):  
Sudhansu Chokroverty
Keyword(s):  
Sleep Apnea ◽  
Sleep Disorders ◽  
Eye Movement ◽  
Rem Sleep ◽  
Sleep Apnea Syndrome ◽  
Nrem Sleep ◽  
Rapid Eye Movement ◽  
Circadian Rhythm Sleep Disorders ◽  
Apnea Syndrome ◽  
Sleep Mechanism

Recent research has generated an enormous fund of knowledge about the neurobiology of sleep and wakefulness. Sleeping and waking brain circuits can now be studied by sophisticated neuroimaging techniques that map different areas of the brain during different sleep states and stages. Although the exact biologic functions of sleep are not known, sleep is essential, and sleep deprivation leads to impaired attention and decreased performance. Sleep is also believed to have restorative, conservative, adaptive, thermoregulatory, and consolidative functions. This review discusses the physiology of sleep, including its two independent states, rapid eye movement (REM) and non–rapid eye movement (NREM) sleep, as well as functional neuroanatomy, physiologic changes during sleep, and circadian rhythms. The classification and diagnosis of sleep disorders are discussed generally. The diagnosis and treatment of the following disorders are described: obstructive sleep apnea syndrome, narcolepsy-cataplexy sydrome, idiopathic hypersomnia, restless legs syndrome (RLS) and periodic limb movements in sleep, circadian rhythm sleep disorders, insomnias, nocturnal frontal lobe epilepsy, and parasomnias. Sleep-related movement disorders and the relationship between sleep and psychiatric disorders are also discussed. Tables describe behavioral and physiologic characteristics of states of awareness, the international classification of sleep disorders, common sleep complaints, comorbid insomnia disorders, causes of excessive daytime somnolence, laboratory tests to assess sleep disorders, essential diagnostic criteria for RLS and Willis-Ekbom disease, and drug therapy for insomnia. Figures include polysomnographic recording showing wakefulness in an adult; stage 1, 2, and 3 NREM sleep in an adult; REM sleep in an adult; a patient with sleep apnea syndrome; a patient with Cheyne-Stokes breathing; a patient with RLS; and a patient with dream-enacting behavior; schematic sagittal section of the brainstem of the cat; schematic diagram of the McCarley-Hobson model of REM sleep mechanism; the Lu-Saper “flip-flop” model; the Luppi model to explain REM sleep mechanism; and a wrist actigraph from a man with bipolar disorder. This review contains 14 highly rendered figures, 8 tables, 115 references, and 5 MCQs.

Arousal Characteristics in Patients with Parkinson’s Disease and Isolated Rapid Eye Movement Sleep Behavior Disorder

SLEEP ◽  
2021 ◽  
Author(s):  
Andreas Brink-Kjær ◽  
Matteo Cesari ◽  
Friederike Sixel-Döring ◽  
Brit Mollenhauer ◽  
Claudia Trenkwalder ◽  
...  
Keyword(s):  
Parkinson’S Disease ◽  
Eye Movement ◽  
Rem Sleep ◽  
Regression Models ◽  
Muscle Tone ◽  
Behavior Disorder ◽  
Nrem Sleep ◽  
Rapid Eye Movement ◽  
Sleep Behavior

Abstract Study objectives Patients diagnosed with isolated rapid eye movement (REM) sleep behavior disorder (iRBD) and Parkinson’s disease (PD) have altered sleep stability reflecting neurodegeneration in brainstem structures. We hypothesize that neurodegeneration alters the expression of cortical arousals in sleep. Methods We analyzed polysomnography data recorded from 88 healthy controls (HC), 22 iRBD patients, 82 de novo PD patients without RBD and 32 with RBD (PD+RBD). These patients were also investigated at a 2-year follow-up. Arousals were analyzed using a previously validated automatic system, which used a central EEG lead, electrooculography, and chin electromyography. Multiple linear regression models were fitted to compare group differences at baseline and change to follow-up for arousal index (ArI), shifts in electroencephalographic signals associated with arousals, and arousal chin muscle tone. The regression models were adjusted for known covariates affecting the nature of arousal. Results In comparison to HC, patients with iRBD and PD+RBD showed increased ArI during REM sleep and their arousals showed a significantly lower shift in α-band power at arousals and a higher muscle tone during arousals. In comparison to HC, the PD patients were characterized by a decreased ArI in NREM sleep at baseline. ArI during NREM sleep decreased further at the 2-year follow-up, although not significantly Conclusions Patients with PD and iRBD present with abnormal arousal characteristics as scored by an automated method. These abnormalities are likely to be caused by neurodegeneration of the reticular activation system due to alpha-synuclein aggregation.

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