Your search keyword '"slow oscillations"' showing total 485 results

51. Impact of GABAA and GABAB Inhibition on Cortical Dynamics and Perturbational Complexity during Synchronous and Desynchronized States.

Author

Barbero-Castillo, Almudena, Mateos-Aparicio, Pedro, Dalla Porta, Leonardo, Camassa, Alessandra, Perez-Mendez, Lorena, and Sanchez-Vives, Maria V.

Subjects

*CEREBRAL cortex, *FERRET, *CONSCIOUSNESS, *SYNCHRONIZATION

Abstract

Quantitative estimations of spatiotemporal complexity of cortical activity patterns are used in the clinic as a measure of consciousness levels, but the cortical mechanisms involved are not fully understood. We used a version of the perturbational complexity index (PCI) adapted to multisite recordings from the ferret (either sex) cerebral cortex in vitro (sPCI) to investigate the role of GABAergic inhibition in cortical complexity. We studied two dynamical states: slow-wave activity (synchronous state) and desynchronized activity, that express low and high causal complexity respectively. Progressive blockade of GABAergic inhibition during both regimes revealed its impact on the emergent cortical activity and on sPCI. Gradual GABAA receptor blockade resulted in higher synchronization, being able to drive the network from a desynchronized to a synchronous state, with a progressive decrease of complexity (sPCI). Blocking GABAB receptors also resulted in a reduced sPCI, in particular when in a synchronous, slow wave state. Our findings demonstrate that physiological levels of inhibition contribute to the generation of dynamical richness and spatiotemporal complexity. However, if inhibition is diminished or enhanced, cortical complexity decreases. Using a computational model, we explored a larger parameter space in this relationship and demonstrate a link between excitatory/inhibitory balance and the complexity expressed by the cortical network. [ABSTRACT FROM AUTHOR]

Published

2021

52. Frequency Characteristics of Sleep

Author

Lázár, Alpár S., Lázár, Zsolt I., Bódizs, Róbert, Gable, Philip A., book editor, Miller, Matthew W., book editor, and Bernat, Edward M., book editor

Published

2022

53. Sleep, oscillations, interictal discharges, and seizures in human focal epilepsy

Author

Birgit Frauscher and Jean Gotman

Subjects

Stereo-electroencephalography, High-frequency oscillations, Interictal epileptiform discharges, Slow oscillations, REM sleep, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Bidirectional interactions between sleep and epilepsy are known since antiquity, however only the introduction of the method of electroencephalography (EEG) in 1929 contributed to objectively investigate and further unravel these obvious clinical relationships. Despite the increasing evidence over the last century, certain aspects of epilepsy and sleep interactions are still incompletely or not well understood. This article discusses the influence of sleep on adult focal epilepsy as assessed objectively via EEG, and highlights new developments of the last decade regarding sleep microstructure and new markers of the epileptogenic zone such as high-frequency oscillations >80 Hz. It further describes evidence obtained from invasive intracranial EEG, as this is a unique method to assess directly cortical activity of superficial and deep structures of the human brain. Important achievements of the last decade were to unravel how epileptic activity is modulated by sleep, underlining the role of sleep slow waves to enhance epileptic activity, to demonstrate that seizure types are differently affected by sleep, and to show that sleep may be useful to better identify the epileptogenic zone for epilepsy surgery in drug-resistant epilepsy.

Published

2019

54. Control of cortical oscillatory frequency by a closed-loop system

Author

Mattia D’Andola, Massimiliano Giulioni, Vittorio Dante, Paolo Del Giudice, and Maria V. Sanchez-Vives

Subjects

Stimulation, Cortex, In vitro, Real-time, Slow oscillations, Emergent properties, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Background We present a closed-loop system able to control the frequency of slow oscillations (SO) spontaneously generated by the cortical network in vitro. The frequency of SO can be controlled by direct current (DC) electric fields within a certain range. Here we set out to design a system that would be able to autonomously bring the emergent oscillatory activity to a target frequency determined by the experimenter. Methods The cortical activity was recorded through an electrode and was analyzed online. Once a target frequency was set, the frequency of the slow oscillation was steered through the injection of DC of variable intensity that generated electric fields of proportional amplitudes in the brain slice. To achieve such closed-loop control, we designed a custom programmable stimulator ensuring low noise and accurate tuning over low current levels. For data recording and analysis, we relied on commercial acquisition and software tools. Results The result is a flexible and reliable system that ensures control over SO frequency in vitro. The system guarantees artifact removal, minimal gaps in data acquisition and robustness in spite of slice heterogeneity. Conclusions Our tool opens new possibilities for the investigation of dynamics of cortical slow oscillations—an activity pattern that is associated with cognitive processes such as memory consolidation, and that is altered in several neurological conditions—and also for potential applications of this technology.

Published

2019

55. Somatostatin interneurons activated by 5-HT2A receptor suppress slow oscillations in medial entorhinal cortex

Author

Roberto de Filippo, Benjamin R Rost, Alexander Stumpf, Claire Cooper, John J Tukker, Christoph Harms, Prateep Beed, and Dietmar Schmitz

Subjects

serotonin, somatostatin interneurons, slow oscillations, MDMA, fenfluramine, Medicine, Science, Biology (General), QH301-705.5

Abstract

Serotonin (5-HT) is one of the major neuromodulators present in the mammalian brain and has been shown to play a role in multiple physiological processes. The mechanisms by which 5-HT modulates cortical network activity, however, are not yet fully understood. We investigated the effects of 5-HT on slow oscillations (SOs), a synchronized cortical network activity universally present across species. SOs are observed during anesthesia and are considered to be the default cortical activity pattern. We discovered that (±)3,4-methylenedioxymethamphetamine (MDMA) and fenfluramine, two potent 5-HT releasers, inhibit SOs within the entorhinal cortex (EC) in anesthetized mice. Combining opto- and pharmacogenetic manipulations with in vitro electrophysiological recordings, we uncovered that somatostatin-expressing (Sst) interneurons activated by the 5-HT2A receptor (5-HT2AR) play an important role in the suppression of SOs. Since 5-HT2AR signaling is involved in the etiology of different psychiatric disorders and mediates the psychological effects of many psychoactive serotonergic drugs, we propose that the newly discovered link between Sst interneurons and 5-HT will contribute to our understanding of these complex topics.

Published

2021

56. Electric Stimulation to Improve Memory Consolidation During Sleep

Author

Campos-Beltrán, Diana, Marshall, Lisa, Reuter, Martin, Series editor, Montag, Christian, Series editor, Axmacher, Nikolai, editor, and Rasch, Björn, editor

Published

2017

57. The Role of Sleep Spindles in Sleep-Dependent Memory Consolidation

Author

McDevitt, Elizabeth A., Krishnan, Giri P., Bazhenov, Maxim, Mednick, Sara C., Reuter, Martin, Series editor, Montag, Christian, Series editor, Axmacher, Nikolai, editor, and Rasch, Björn, editor

Published

2017

58. Sleep Spindles Preferentially Consolidate Weakly Encoded Memories.

Author

Denis, Dan, Mylonas, Dimitrios, Poskanzer, Craig, Bursal, Verda, Payne, Jessica D., and Stickgold, Robert

Subjects

*SLEEP spindles, *NON-REM sleep

Abstract

Sleep has been shown to be critical for memory consolidation, with some research suggesting that certain memories are prioritized for consolidation. Initial strength of a memory appears to be an important boundary condition in determining which memories are consolidated during sleep. However, the role of consolidation-mediating oscillations, such as sleep spindles and slow oscillations, in this preferential consolidation has not been explored. Here, 54 human participants (76% female) studied pairs of words to three distinct encoding strengths, with recall being tested immediately following learning and again 6 h later. Thirty-six had a 2 h nap opportunity following learning, while the remaining 18 remained awake throughout. Results showed that, across 6 h awake, weakly encoded memories deteriorated the fastest. In the nap group, however, this effect was attenuated, with forgetting rates equivalent across encoding strengths. Within the nap group, consolidation of weakly encoded items was associated with fast sleep spindle density during non-rapid eye movement sleep. Moreover, sleep spindles that were coupled to slow oscillations predicted the consolidation of weak memories independently of uncoupled sleep spindles. These relationships were unique to weakly encoded items, with spindles not correlating with memory for intermediate or strong items. This suggests that sleep spindles facilitate memory consolidation, guided in part by memory strength. [ABSTRACT FROM AUTHOR]

Published

2021

59. Transcranial Electrical Stimulation targeting limbic cortex increases the duration of human deep sleep.

Author

Hathaway, Evan, Morgan, Kyle, Carson, Megan, Shusterman, Roma, Fernandez-Corazza, Mariano, Luu, Phan, and Tucker, Don M.

Subjects

*CINGULATE cortex, *ELECTRIC stimulation, *CONVOLUTIONAL neural networks, *BRAIN stimulation, *SLEEP stages

Abstract

Background: Researchers have proposed that impaired sleep may be a causal link in the progression from Mild Cognitive Impairment (MCI) to Alzheimer's Disease (AD). Several recent findings suggest that enhancing deep sleep (N3) may improve neurological health in persons with MCI, and buffer the risk for AD. Specifically, Transcranial Electrical Stimulation (TES) of frontal brain areas, the inferred source of the Slow Oscillations (SOs) of N3 sleep, can extend N3 sleep duration and improve declarative memory for recently learned information. Recent work in our laboratory using dense array Electroencephalography (dEEG) localized the sources of SOs to anterior limbic sites - suggesting that targeting these sites with TES may be more effective for enhancing N3.Methods: For the present study, we recruited 13 healthy adults (M = 42 years) to participate in three all-night sleep EEG recordings where they received low level (0.5 mA) TES designed to target anterior limbic areas and a sham stimulation (placebo). We used a convolutional neural network, trained and tested on professionally scored EEG sleep staging, to predict sleep stages for each recording.Results: When compared to the sham session, limbic-targeted TES significantly increased the duration of N3 sleep. TES also significantly increased spectral power in the 0.5-1 Hz frequency band (relative to pre-TES epochs) in left temporoparietal and left occipital scalp regions compared to sham.Conclusion: These results suggest that even low-level TES, when specifically targeting anterior limbic sites, can increase deep (N3) sleep and thereby contribute to healthy sleep quality. [ABSTRACT FROM AUTHOR]

Published

2021

60. Glutamatergic Neurons in the Preoptic Hypothalamus Promote Wakefulness, Destabilize NREM Sleep, Suppress REM Sleep, and Regulate Cortical Dynamics.

Author

Mondino, Alejandra, Hambrecht-Wiedbusch, Viviane S., Duan Li, York, A. Kane, Pal, Dinesh, González, Joaquin, Torterolo, Pablo, Mashour, George A., and Vanini, Giancarlo

Subjects

*RAPID eye movement sleep, *PREOPTIC area, *WAKEFULNESS, *HYPOTHALAMUS, *SLEEP, *BODY temperature

Abstract

Clinical 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 (Vglut21) neurons and show that their activation initiates wakefulness, decreases nonrapid eye movement (NREM) sleep, and causes a persistent suppression of rapid eye movement (REM) sleep. We also demonstrate, for the first time, that activation of these preoptic glutamatergic neurons causes a high degree of NREM sleep fragmentation, promotes state instability with frequent arousals from sleep, decreases body temperature, and shifts cortical dynamics (including oscillations, connectivity, and complexity) to a more wake-like state. We conclude that a subset of preoptic glutamatergic neurons can 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 hypothesis that the preoptic area causally contributes to the regulation of both sleep and wakefulness. [ABSTRACT FROM AUTHOR]

Published

2021

61. Up and Down States During Slow Oscillations in Slow-Wave Sleep and Different Levels of Anesthesia

Author

Melody Torao-Angosto, Arnau Manasanch, Maurizio Mattia, and Maria V. Sanchez-Vives

Subjects

Up states, Down states, slow oscillations, sleep, anesthesia, cerebral cortex, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Slow oscillations are a pattern of synchronized network activity generated by the cerebral cortex. They consist of Up and Down states, which are periods of activity interspersed with periods of silence, respectively. However, even when this is a unique dynamic regime of transitions between Up and Down states, this pattern is not constant: there is a range of oscillatory frequencies (0.1–4 Hz), and the duration of Up vs. Down states during the cycles is variable. This opens many questions. Is there a constant relationship between the duration of Up and Down states? How much do they vary across conditions and oscillatory frequencies? Are there different sub regimes within the slow oscillations? To answer these questions, we aimed to explore a concrete aspect of slow oscillations, Up and Down state durations, across three conditions: deep anesthesia, light anesthesia, and slow-wave sleep (SWS), in the same chronically implanted rats. We found that light anesthesia and SWS have rather similar properties, occupying a small area of the Up and Down state duration space. Deeper levels of anesthesia occupy a larger region of this space, revealing that a large variety of Up and Down state durations can emerge within the slow oscillatory regime. In a network model, we investigated the network parameters that can explain the different points within our bifurcation diagram in which slow oscillations are expressed.

Published

2021

62. Isoflurane-Induced Burst Suppression Is a Thalamus-Modulated, Focal-Onset Rhythm With Persistent Local Asynchrony and Variable Propagation Patterns in Rats

Author

Qianwen Ming, Jyun-You Liou, Fan Yang, Jing Li, Chaojia Chu, Qingchen Zhou, Dan Wu, Shujia Xu, Peijuan Luo, Jianmin Liang, Dan Li, Kane O. Pryor, Weihong Lin, Theodore H. Schwartz, and Hongtao Ma

Subjects

general anesthesia, burst suppression, widefield calcium imaging, thalamocortical interactions, traveling wave, slow oscillations, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Background: Inhalational anesthetic-induced burst suppression (BS) is classically considered a bilaterally synchronous rhythm. However, local asynchrony has been predicted in theoretical studies and reported in patients with pre-existing focal pathology.Method: We used high-speed widefield calcium imaging to study the spatiotemporal dynamics of isoflurane-induced BS in rats.Results: We found that isoflurane-induced BS is not a globally synchronous rhythm. In the neocortex, neural activity first emerged in a spatially shifting, variably localized focus. Subsequent propagation across the whole cortex was rapid, typically within

Published

2021

63. GABAB receptors: modulation of thalamocortical dynamics and synaptic plasticity.

Author

Sanchez-Vives, Maria V., Barbero-Castillo, Almudena, Perez-Zabalza, Maria, and Reig, Ramon

Subjects

*NEUROPLASTICITY, *G protein coupled receptors, *NEUROTRANSMITTER receptors, *GABA receptors, *CENTRAL nervous system

Abstract

• GABA B -Rs can be pre or postsynaptic, inhibiting both excitatory and inhibitory neurons, and also decreasing excitation. • Activation of GABA B -Rs in the thalamus and cortex modulates emergent rhythms and synaptic plasticity. • In the thalamus, activation of GABA B -Rs switches the network from generating spindle waves to spike-and-wave cycles. • During cortical Up and Down states, GABA B -R blockade consistently elongates Up states and modifies the rhythmic cycle. • Blockade of GABA B -Rs increases regularity of the cycle and decreases the network complexity of causal interactions. GABA B -receptors (GABA B -Rs) are metabotropic, G protein-coupled receptors for the neurotransmitter GABA. Their activation induces slow inhibitory control of the neuronal excitability mediated by pre- and postsynaptic inhibition. Presynaptically GABA B -Rs reduce GABA and glutamate release inhibiting presynaptic Ca2+ channels in both inhibitory and excitatory synapses while postsynaptic GABA B -Rs induce robust slow hyperpolarization by the activation of K+ channels. GABA B -Rs are activated by non-synaptic or volume transmission, which requires high levels of GABA release, either by the simultaneous discharge of GABAergic interneurons or very intense discharges in the thalamus or by means of the activation of a neurogliaform interneurons in the cortex. The main receptor subunits GABA B 1a , GABA B 1b and GABA B 2 are strongly expressed in neurons and glial cells throughout the central nervous system and GABA B -R activation is related to many neuronal processes such as the modulation of rhythmic activity in several brain regions. In the thalamus, GABA B -Rs modulate the generation of the main thalamic rhythm, spindle waves. In the cerebral cortex, GABA B -Rs also modulate the most prominent emergent oscillatory activity—slow oscillations—as well as faster oscillations like gamma frequency. Further, recent studies evaluating the complexity expressed by the cortical network, a parameter associated with consciousness levels, have found that GABA B -Rs enhance this complexity, while their blockade decreases it. This review summarizes the current results on how the activation of GABA B -Rs affects the interchange of information between brain areas by controlling rhythmicity as well as synaptic plasticity. [ABSTRACT FROM AUTHOR]

Published

2021

64. Up and Down States During Slow Oscillations in Slow-Wave Sleep and Different Levels of Anesthesia.

Author

Torao-Angosto, Melody, Manasanch, Arnau, Mattia, Maurizio, and Sanchez-Vives, Maria V.

Subjects

SLOW wave sleep, OSCILLATIONS, ANESTHESIA, CEREBRAL cortex, BIFURCATION diagrams

Abstract

Slow oscillations are a pattern of synchronized network activity generated by the cerebral cortex. They consist of Up and Down states, which are periods of activity interspersed with periods of silence, respectively. However, even when this is a unique dynamic regime of transitions between Up and Down states, this pattern is not constant: there is a range of oscillatory frequencies (0.1–4 Hz), and the duration of Up vs. Down states during the cycles is variable. This opens many questions. Is there a constant relationship between the duration of Up and Down states? How much do they vary across conditions and oscillatory frequencies? Are there different sub regimes within the slow oscillations? To answer these questions, we aimed to explore a concrete aspect of slow oscillations, Up and Down state durations, across three conditions: deep anesthesia, light anesthesia, and slow-wave sleep (SWS), in the same chronically implanted rats. We found that light anesthesia and SWS have rather similar properties, occupying a small area of the Up and Down state duration space. Deeper levels of anesthesia occupy a larger region of this space, revealing that a large variety of Up and Down state durations can emerge within the slow oscillatory regime. In a network model, we investigated the network parameters that can explain the different points within our bifurcation diagram in which slow oscillations are expressed. [ABSTRACT FROM AUTHOR]

Published

2021

65. Modulation of Prefrontal Cortex Slow Oscillations by Phasic Activation of the Locus Coeruleus.

Author

Durán, Ernesto, Yang, Mingyu, Neves, Ricardo, Logothetis, Nikos K., and Eschenko, Oxana

Subjects

*PREFRONTAL cortex, *LOCUS coeruleus, *OSCILLATIONS, *THALAMOCORTICAL system, *ELECTRIC stimulation, *ACTION potentials, *POPULATION dynamics

Abstract

• Locus Coeruleus phasic response facilitated prefrontal network activation. • Transient NA release sustained depolarization and enhanced spiking probability in the mPFC. • Effect of LC stimulation depended on excitability level of prefrontal network. • Functional role for the coerulear–prefrontal interactions for promoting plasticity is proposed. Cortical slow rhythmic activity, a hallmark of deep sleep, is observed under urethane anesthesia. Synchronized fluctuations of the membrane excitability of a large neuronal population are reflected in the extracellular Local Field Potential (LFP), as high-amplitude slow (∼1 Hz) oscillations (SO). The SO-phase indicates the presence (Up) or absence (Down) of neuronal spiking. The cortical state is controlled by the input from thalamic and neuromodulatory centers, including the brainstem noradrenergic nucleus Locus Coeruleus (LC). The bidirectional modulation of neuronal excitability by noradrenaline (NA) is well known. We have previously shown that LC phasic activation caused transient excitability increase in the medial prefrontal cortex (mPFC). In the present study, we characterized the effect of LC phasic activation on the prefrontal population dynamics at a temporal scale of a single SO cycle. We applied short (0.2 s) trains of electric pulses (0.02–0.05 mA at 20–50 Hz) to the LC cell bodies and monitored a broadband (0.1 Hz–8 kHz) mPFC LFP in urethane-anesthetized rats. The direct electrical stimulation of LC (LC-DES), applied during the Up-phase, enhanced the firing probability in the mPFC by ∼20% and substantially prolonged Up-states in 56% of trials. The LC-DES applied during Down-phase caused a rapid Down-to-Up transition in 81.5% of trials. The LC-DES was more effective at a higher frequency, but not at a higher current. Our results suggest that transient NA release, coupled to SO, may promote synaptic plasticity and memory consolidation by sustaining a depolarized state in the mPFC neurons. [ABSTRACT FROM AUTHOR]

Published

2021

66. Isoflurane-Induced Burst Suppression Is a Thalamus-Modulated, Focal-Onset Rhythm With Persistent Local Asynchrony and Variable Propagation Patterns in Rats.

Author

Ming, Qianwen, Liou, Jyun-You, Yang, Fan, Li, Jing, Chu, Chaojia, Zhou, Qingchen, Wu, Dan, Xu, Shujia, Luo, Peijuan, Liang, Jianmin, Li, Dan, Pryor, Kane O., Lin, Weihong, Schwartz, Theodore H., and Ma, Hongtao

Subjects

RHYTHM, RATS, TETRODOTOXIN, THALAMUS, SYNCHRONIC order

Abstract

Background: Inhalational anesthetic-induced burst suppression (BS) is classically considered a bilaterally synchronous rhythm. However, local asynchrony has been predicted in theoretical studies and reported in patients with pre-existing focal pathology. Method: We used high-speed widefield calcium imaging to study the spatiotemporal dynamics of isoflurane-induced BS in rats. Results: We found that isoflurane-induced BS is not a globally synchronous rhythm. In the neocortex, neural activity first emerged in a spatially shifting, variably localized focus. Subsequent propagation across the whole cortex was rapid, typically within <100 milliseconds, giving the superficial resemblance to global synchrony. Neural activity remained locally asynchronous during the bursts, forming complex recurrent propagating waves. Despite propagation variability, spatial sequences of burst propagation were largely preserved between the hemispheres, and neural activity was highly correlated between the homotopic areas. The critical role of the thalamus in cortical burst initiation was demonstrated by using unilateral thalamic tetrodotoxin injection. Conclusion: The classical impression that anesthetics-induced BS is a state of global brain synchrony is inaccurate. Bursts are a series of shifting local cortical events facilitated by thalamic projection that unfold as rapid, bilaterally asynchronous propagating waves. [ABSTRACT FROM AUTHOR]

Published

2021

67. Early Disruption of Cortical Sleep-Related Oscillations in a Mouse Model of Dementia With Lewy Bodies (DLB) Expressing Human Mutant (A30P) Alpha-Synuclein

Author

Myrto Stylianou, Boubker Zaaimi, Alan Thomas, John-Paul Taylor, and Fiona E. N. LeBeau

Subjects

slow oscillations, prefrontal cortex, hippocampus, fast network oscillations, alpha-synuclein, spindles, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Changes in sleep behavior and sleep-related cortical activity have been reported in conditions associated with abnormal alpha-synuclein (α-syn) expression, in particular Parkinson’s disease (PD) and dementia with Lewy bodies (DLB). Notably, changes can occur in patients years before the onset of cognitive decline. Sleep-related network oscillations play a key role in memory function, but how abnormal α-syn impacts the generation of such activity is currently unclear. To determine whether early changes in sleep-related network activity could also be observed, prior to any previously reported cognitive dysfunction, we used mice that over-express human mutant α-syn (A30P). Recordings in vivo were performed under urethane anesthesia in the medial prefrontal cortex (mPFC) and CA1 region of the hippocampus in young male (2.5 – 4 months old) A30P and age-matched wild type (WT) mice. We found that the slow oscillation (SO) < 1 Hz frequency was significantly faster in both the mPFC and hippocampus in A30P mice, and Up-state-associated fast oscillations at beta (20 – 30 Hz) and gamma (30 – 80 Hz) frequencies were delayed relative to the onset of the Up-state. Spindle (8 – 15 Hz) activity in the mPFC was also altered in A30P mice, as spindles were shorter in duration and had reduced density compared to WT. These changes demonstrate that dysregulation of sleep-related oscillations occurs in young A30P mice long before the onset of cognitive dysfunction. Our data suggest that, as seen in patients, changes in sleep-related oscillations are an early consequence of abnormal α-syn aggregation in A30P mice.

Published

2020

68. Slow Wave Sleep Is a Promising Intervention Target for Alzheimer’s Disease

Author

Yee Fun Lee, Dmitry Gerashchenko, Igor Timofeev, Brian J. Bacskai, and Ksenia V. Kastanenka

Subjects

Alzheimer’s disease, sleep, NREM sleep, slow wave activity, slow oscillations, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Alzheimer’s disease (AD) is the major cause of dementia, characterized by the presence of amyloid-beta plaques and neurofibrillary tau tangles. Plaques and tangles are associated with sleep-wake cycle disruptions, including the disruptions in non-rapid eye movement (NREM) slow wave sleep (SWS). Alzheimer’s patients spend less time in NREM sleep and exhibit decreased slow wave activity (SWA). Consistent with the critical role of SWS in memory consolidation, reduced SWA is associated with impaired memory consolidation in AD patients. The aberrant SWA can be modeled in transgenic mouse models of amyloidosis and tauopathy. Animal models exhibited slow wave impairments early in the disease progression, prior to the deposition of amyloid-beta plaques, however, in the presence of abundant oligomeric amyloid-beta. Optogenetic rescue of SWA successfully halted the amyloid accumulation and restored intraneuronal calcium levels in mice. On the other hand, optogenetic acceleration of slow wave frequency exacerbated amyloid deposition and disrupted neuronal calcium homeostasis. In this review, we summarize the evidence and the mechanisms underlying the existence of a positive feedback loop between amyloid/tau pathology and SWA disruptions that lead to further accumulations of amyloid and tau in AD. Moreover, since SWA disruptions occur prior to the plaque deposition, SWA disruptions may provide an early biomarker for AD. Finally, we propose that therapeutic targeting of SWA in AD might lead to an effective treatment for Alzheimer’s patients.

Published

2020

69. Brain states govern the spatio-temporal dynamics of resting-state functional connectivity

Author

Felipe Aedo-Jury, Miriam Schwalm, Lara Hamzehpour, and Albrecht Stroh

Subjects

functional connectivity, fMRI, brain states, optic-fiber-based calcium recordings, slow waves, slow oscillations, Medicine, Science, Biology (General), QH301-705.5

Abstract

Previously, using simultaneous resting-state functional magnetic resonance imaging (fMRI) and photometry-based neuronal calcium recordings in the anesthetized rat, we identified blood oxygenation level-dependent (BOLD) responses directly related to slow calcium waves, revealing a cortex-wide and spatially organized correlate of locally recorded neuronal activity (Schwalm et al., 2017). Here, using the same techniques, we investigate two distinct cortical activity states: persistent activity, in which compartmentalized network dynamics were observed; and slow wave activity, dominated by a cortex-wide BOLD component, suggesting a strong functional coupling of inter-cortical activity. During slow wave activity, we find a correlation between the occurring slow wave events and the strength of functional connectivity between different cortical areas. These findings suggest that down-up transitions of neuronal excitability can drive cortex-wide functional connectivity. This study provides further evidence that changes in functional connectivity are dependent on the brain’s current state, directly linked to the generation of slow waves.

Published

2020

70. Slow oscillation-spindle coupling predicts enhanced memory formation from childhood to adolescence

Author

Michael A Hahn, Dominik Heib, Manuel Schabus, Kerstin Hoedlmoser, and Randolph F Helfrich

Subjects

sleep-dependent memory consolidation, cross-frequency coupling, maturation, development, slow oscillations, sleep spindles, Medicine, Science, Biology (General), QH301-705.5

Abstract

Precise temporal coordination of slow oscillations (SO) and sleep spindles is a fundamental mechanism of sleep-dependent memory consolidation. SO and spindle morphology changes considerably throughout development. Critically, it remains unknown how the precise temporal coordination of these two sleep oscillations develops during brain maturation and whether their synchronization indexes the development of memory networks. Here, we use a longitudinal study design spanning from childhood to adolescence, where participants underwent polysomnography and performed a declarative word-pair learning task. Performance on the memory task was better during adolescence. After disentangling oscillatory components from 1/f activity, we found frequency shifts within SO and spindle frequency bands. Consequently, we devised an individualized cross-frequency coupling approach, which demonstrates that SO-spindle coupling strength increases during maturation. Critically, this increase indicated enhanced memory formation from childhood to adolescence. Our results provide evidence that improved coordination between SOs and spindles indexes the development of sleep-dependent memory networks.

Published

2020

71. Accelerated Aging Characterizes the Early Stage of Alzheimer’s Disease

Author

Alessandro Leparulo, Marta Bisio, Nelly Redolfi, Tullio Pozzan, Stefano Vassanelli, and Cristina Fasolato

Subjects

Alzheimer’s disease, PS2APP, presenilin-2, amyloid-β, slow oscillations, delta waves, Cytology, QH573-671

Abstract

For Alzheimer’s disease (AD), aging is the main risk factor, but whether cognitive impairments due to aging resemble early AD deficits is not yet defined. When working with mouse models of AD, the situation is just as complicated, because only a few studies track the progression of the disease at different ages, and most ignore how the aging process affects control mice. In this work, we addressed this problem by comparing the aging process of PS2APP (AD) and wild-type (WT) mice at the level of spontaneous brain electrical activity under anesthesia. Using local field potential recordings, obtained with a linear probe that traverses the posterior parietal cortex and the entire hippocampus, we analyzed how multiple electrical parameters are modified by aging in AD and WT mice. With this approach, we highlighted AD specific features that appear in young AD mice prior to plaque deposition or that are delayed at 12 and 16 months of age. Furthermore, we identified aging characteristics present in WT mice but also occurring prematurely in young AD mice. In short, we found that reduction in the relative power of slow oscillations (SO) and Low/High power imbalance are linked to an AD phenotype at its onset. The loss of SO connectivity and cortico-hippocampal coupling between SO and higher frequencies as well as the increase in UP-state and burst durations are found in young AD and old WT mice. We show evidence that the aging process is accelerated by the mutant PS2 itself and discuss such changes in relation to amyloidosis and gliosis.

Published

2022

72. Role of normal sleep and sleep apnea in human memory processing

Author

Ahuja S, Chen RK, Kam K, Pettibone WD, Osorio RS, and Varga AW

Subjects

consolidation, learning, REM sleep, sleep spindles, slow oscillations, Psychiatry, RC435-571, Neurophysiology and neuropsychology, QP351-495

Abstract

Shilpi Ahuja,1 Rebecca K Chen,1 Korey Kam,1 Ward D Pettibone,1 Ricardo S Osorio,2 Andrew W Varga1 1Mount Sinai Integrative Sleep Center, Division of Pulmonary, Critical Care, and Sleep Medicine, Icahn School of Medicine at Mount Sinai, New York, NY, USA; 2Center for Brain Health, Department of Psychiatry, NYU School of Medicine, New York, NY, USA Abstract: A fundamental problem in the field of obstructive sleep apnea (OSA) and memory is that it has historically minimized the basic neurobiology of sleep’s role in memory. Memory formation has been classically divided into phases of encoding, processing/consolidation, and retrieval. An abundance of evidence suggests that sleep plays a critical role specifically in the processing/consolidation phase, but may do so differentially for memories that were encoded using particular brain circuits. In this review, we discuss some of the more established evidence for sleep’s function in the processing of declarative, spatial navigational, emotional, and motor/procedural memories and more emerging evidence highlighting sleep’s importance in higher order functions such as probabilistic learning, transitive inference, and category/gist learning. Furthermore, we discuss sleep’s capacity for memory augmentation through targeted/cued memory reactivation. OSA – by virtue of its associated sleep fragmentation, intermittent hypoxia, and potential brain structural effects – is well positioned to specifically impact the processing/consolidation phase, but testing this possibility requires experimental paradigms in which memory encoding and retrieval are separated by a period of sleep with and without the presence of OSA. We argue that such paradigms should focus on the specific types of memory tasks for which sleep has been shown to have a significant effect. We discuss the small number of studies in which this has been done, in which OSA nearly uniformly negatively impacts offline memory processing. When periods of offline processing are minimal or absent and do not contain sleep, as is the case in the broad literature on OSA and memory, the effects of OSA on memory are far less consistent. Keywords: consolidation, learning, REM sleep, sleep spindles, slow oscillations

Published

2018

73. Comparative study of short-term cardiovascular autonomic control in cardiac surgery patients who underwent coronary artery bypass grafting or correction of valvular heart disease

Author

Vladimir A Shvartz, Anton R Kiselev, Anatoly S Karavaev, Kristina A Vulf, Ekaterina I Borovkova, Mikhail D Prokhorov, Andrey D Petrosyan, and Olga L Bockeria

Subjects

cardiovascular autonomic control, coronary artery bypass grafting, valvular heart disease, heart rate variability, slow oscillations, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Introduction: Our aim was to perform a comparative study of short-term cardiovascular autonomic control in cardiac surgery patients who underwent coronary artery bypass grafting (CABG) or surgical correction of valvular heart disease (SCVHD). Methods: The synchronous 15 minutes records of heart rate variability (HRV) and finger’s photoplethysmographic waveform variability (PPGV) were performed in 42 cardiac surgery patients (12 women) aged 61.8 ± 8.6 years (mean ± standard deviation), who underwent CABG, and 36 patients (16 women) aged 54.2 ± 14.9 years, who underwent SCVHD, before surgery and in 5-7 days after surgery. Conventional time and frequency domain measures of HRV and index S of synchronization between the slow oscillations in PPGV and HRV were analyzed. We also calculated personal dynamics of these indices after surgery. Results: We found no differences (Р > 0.05) in all studied autonomic indices (preoperative and post-surgery) between studied patients’ groups, except for the preoperative heart rate, which was higher in patients who underwent SCVHD (P = 0.013). We have shown a pronounced preoperative and post-surgery variability (magnitude of inter-quartile ranges) of all autonomic indices in studied patients. In the cluster analysis based on cardiovascular autonomic indices (preoperative and post-surgery), we divided all patients into two clusters (38 and 40 subjects) which did not differ in all clinical characteristics (except for the preoperative hematocrit, P = 0.038), index S, and all post-surgery HRV indices. First cluster (38 patients) had higher preoperative values of the HR, TP, HF, and HF%, and lower preoperative values of the LF% and LF/HF. Conclusion: The variability of cardiovascular autonomic indices in on-pump cardiac surgery patients (two characteristic clusters were identified based on preoperative indices) was not associated with their clinical characteristics and features of surgical procedure (including cardioplegia).

Published

2018

74. Cell Assemblies in the Cortico-Hippocampal-Reuniens Network during Slow Oscillations.

Author

Angulo-Garcia, David, Ferraris, Maëva, Ghestem, Antoine, Nallet-Khosrofian, Lauriane, Bernard, Christophe, and Quilichini, Pascale P.

Subjects

*OSCILLATIONS, *PREFRONTAL cortex, *INFORMATION sharing, *HIPPOCAMPUS (Brain), *NEURONS

Abstract

The nucleus reuniens (NR) is an important anatomic and functional relay between the medial prefrontal cortex (mPFC) and the hippocampus (HPC). Whether the NR controls neuronal assemblies, a hallmark of information exchange between the HPC and mPFC for memory transfer/consolidation, is not known. Using simultaneous local field potential and unit recordings in NR, HPC, and mPFC in male rats during slow oscillations under anesthesia, we identified a reliable sequential activation of NR neurons at the beginning of UP states, which preceded mPFC ones. NR sequences were spatially organized, from dorsal to ventral NR. Chemical inactivation of the NR disrupted mPFC sequences at the onset of UP states as well as HPC sequences present during sharp-wave ripples. We conclude that the NR contributes to the coordination and stabilization of mPFC and HPC neuronal sequences during slow oscillations, possibly via the early activation of its own sequences. [ABSTRACT FROM AUTHOR]

Published

2020

75. Sleep slow oscillations favour local cortical plasticity underlying the consolidation of reinforced procedural learning in human sleep.

Author

Menicucci, Danilo, Piarulli, Andrea, Laurino, Marco, Zaccaro, Andrea, Agrimi, Jacopo, and Gemignani, Angelo

Subjects

*LEARNING, *SLEEP spindles, *OSCILLATIONS, *SLEEP, *BEHAVIOR, *THETA rhythm, *REINFORCEMENT learning, *TASK performance

Abstract

Summary: We investigated changes of slow‐wave activity and sleep slow oscillations in the night following procedural learning boosted by reinforcement learning, and how these changes correlate with behavioural output. In the Task session, participants had to reach a visual target adapting cursor's movements to compensate an angular deviation introduced experimentally, while in the Control session no deviation was applied. The task was repeated at 13:00 hours, 17:00 hours and 23:00 hours before sleep, and at 08:00 hours after sleep. The deviation angle was set at 15° (13:00 hours and 17:00 hours) and increased to 45° (reinforcement) at 23:00 hours and 08:00 hours. Both for Task and Control nights, high‐density electroencephalogram sleep recordings were carried out (23:30−19:30 hours). The Task night as compared with the Control night showed increases of: (a) slow‐wave activity (absolute power) over the whole scalp; (b) slow‐wave activity (relative power) in left centro‐parietal areas; (c) sleep slow oscillations rate in sensorimotor and premotor areas; (d) amplitude of pre‐down and up states in premotor regions, left sensorimotor and right parietal regions; (e) sigma crowning the up state in right parietal regions. After Task night, we found an improvement of task performance showing correlations with sleep slow oscillations rate in right premotor, sensorimotor and parietal regions. These findings suggest a key role of sleep slow oscillations in procedural memories consolidation. The diverse components of sleep slow oscillations selectively reflect the network activations related to the reinforced learning of a procedural visuomotor task. Indeed, areas specifically involved in the task stand out as those with a significant association between sleep slow oscillations rate and overnight improvement in task performance. [ABSTRACT FROM AUTHOR]

Published

2020

76. Hippocampal and medial prefrontal cortical volume is associated with overnight declarative memory consolidation independent of specific sleep oscillations.

Author

Frase, Lukas, Regen, Wolfram, Kass, Stéphanie, Rambach, Albena, Baglioni, Chiara, Feige, Bernd, Hennig, Jürgen, Riemann, Dieter, Nissen, Christoph, and Spiegelhalder, Kai

Subjects

*SLEEP spindles, *EXPLICIT memory, *AGE factors in memory, *SLEEP, *OSCILLATIONS, *PREFRONTAL cortex

Abstract

Summary: The current study was designed to further clarify the influence of brain morphology, sleep oscillatory activity and age on memory consolidation. Specifically, we hypothesized, that a smaller volume of hippocampus, parahippocampal and medial prefrontal cortex negatively impacts declarative, but not procedural, memory consolidation. Explorative analyses were conducted to demonstrate whether a decrease in slow‐wave activity negatively impacts declarative memory consolidation, and whether these factors mediate age effects on memory consolidation. Thirty‐eight healthy participants underwent an acquisition session in the evening and a retrieval session in the morning after night‐time sleep with polysomnographic monitoring. Declarative memory was assessed with the paired‐associate word list task, while procedural memory was tested using the mirror‐tracing task. All participants underwent high‐resolution magnetic resonance imaging. Participants with smaller hippocampal, parahippocampal and medial prefrontal cortex volumes displayed a reduced overnight declarative, but not procedural memory consolidation. Mediation analyses showed significant age effects on overnight declarative memory consolidation, but no significant mediation effects of brain morphology on this association. Further mediation analyses showed that the effects of age and brain morphology on overnight declarative memory consolidation were not mediated by polysomnographic variables or sleep electroencephalogram spectral power variables. Thus, the results suggest that the association between age, specific brain area volume and overnight memory consolidation is highly relevant, but does not necessarily depend on slow‐wave sleep as previously conceptualized. [ABSTRACT FROM AUTHOR]

Published

2020

77. Early Disruption of Cortical Sleep-Related Oscillations in a Mouse Model of Dementia With Lewy Bodies (DLB) Expressing Human Mutant (A30P) Alpha-Synuclein.

Author

Stylianou, Myrto, Zaaimi, Boubker, Thomas, Alan, Taylor, John-Paul, and LeBeau, Fiona E. N.

Subjects

LEWY body dementia, ALPHA-synuclein, OSCILLATIONS, IMPULSE control disorders, PARKINSON'S disease, SLEEP interruptions, PREFRONTAL cortex

Abstract

Changes in sleep behavior and sleep-related cortical activity have been reported in conditions associated with abnormal alpha-synuclein (α-syn) expression, in particular Parkinson's disease (PD) and dementia with Lewy bodies (DLB). Notably, changes can occur in patients years before the onset of cognitive decline. Sleep-related network oscillations play a key role in memory function, but how abnormal α-syn impacts the generation of such activity is currently unclear. To determine whether early changes in sleep-related network activity could also be observed, prior to any previously reported cognitive dysfunction, we used mice that over-express human mutant α-syn (A30P). Recordings in vivo were performed under urethane anesthesia in the medial prefrontal cortex (mPFC) and CA1 region of the hippocampus in young male (2.5 – 4 months old) A30P and age-matched wild type (WT) mice. We found that the slow oscillation (SO) < 1 Hz frequency was significantly faster in both the mPFC and hippocampus in A30P mice, and Up-state-associated fast oscillations at beta (20 – 30 Hz) and gamma (30 – 80 Hz) frequencies were delayed relative to the onset of the Up-state. Spindle (8 – 15 Hz) activity in the mPFC was also altered in A30P mice, as spindles were shorter in duration and had reduced density compared to WT. These changes demonstrate that dysregulation of sleep-related oscillations occurs in young A30P mice long before the onset of cognitive dysfunction. Our data suggest that, as seen in patients, changes in sleep-related oscillations are an early consequence of abnormal α-syn aggregation in A30P mice. [ABSTRACT FROM AUTHOR]

Published

2020

78. Modulation of cortical slow oscillatory rhythm by GABAB receptors: an in vitro experimental and computational study.

Author

Perez‐Zabalza, Maria, Reig, Ramon, Manrique, Jesus, Jercog, Daniel, Winograd, Milena, Parga, Nestor, and Sanchez‐Vives, Maria V.

Subjects

*RHYTHM, *BRAIN damage, *COMPUTER simulation, *CHRONOBIOLOGY disorders, *OSCILLATIONS

Abstract

Key points: We confirm that GABAB receptors (GABAB‐Rs) are involved in the termination of Up‐states; their blockade consistently elongates Up‐states.GABAB‐Rs also modulate Down‐states and the oscillatory cycle, thus having an impact on slow oscillation rhythm and its regularity.The most frequent effect of GABAB‐R blockade is elongation of Down‐states and subsequent decrease of oscillatory frequency, with an increased regularity. In a quarter of cases, GABAB‐R blockade shortened Down‐states and increased oscillatory frequency, changes that are independent of firing rates in Up‐states.Our computer model provides mechanisms for the experimentally observed dynamics following blockade of GABAB‐Rs, for Up/Down durations, oscillatory frequency and regularity. The time course of excitation, inhibition and adaptation can explain the observed dynamics of the network.This study brings novel insights into the role of GABAB‐R‐mediated slow inhibition on the slow oscillatory activity, which is considered the default activity pattern of the cortical network. Slow wave oscillations (SWOs) dominate cortical activity during deep sleep, anaesthesia and in some brain lesions. SWOs are composed of periods of activity (Up states) interspersed with periods of silence (Down states). The rhythmicity expressed during SWOs integrates neuronal and connectivity properties of the network and is often altered under pathological conditions. Adaptation mechanisms as well as synaptic inhibition mediated by GABAB receptors (GABAB‐Rs) have been proposed as mechanisms governing the termination of Up states. The interplay between these two mechanisms is not well understood, and the role of GABAB‐Rs controlling the whole cycle of the SWO has not been described. Here we contribute to its understanding by combining in vitro experiments on spontaneously active cortical slices and computational techniques. GABAB‐R blockade modified the whole SWO cycle, not only elongating Up states, but also affecting the subsequent Down state duration. Furthermore, while adaptation tends to yield a rather regular behaviour, we demonstrate that GABAB‐R activation desynchronizes the SWOs. Interestingly, variability changes could be accomplished in two different ways: by either shortening or lengthening the duration of Down states. Even when the most common observation following GABAB‐Rs blocking is the lengthening of Down states, both changes are expressed experimentally and also in numerical simulations. Our simulations suggest that the sluggishness of GABAB‐Rs to follow the excitatory fluctuations of the cortical network can explain these different network dynamics modulated by GABAB‐Rs. Key points: We confirm that GABAB receptors (GABAB‐Rs) are involved in the termination of Up‐states; their blockade consistently elongates Up‐states.GABAB‐Rs also modulate Down‐states and the oscillatory cycle, thus having an impact on slow oscillation rhythm and its regularity.The most frequent effect of GABAB‐R blockade is elongation of Down‐states and subsequent decrease of oscillatory frequency, with an increased regularity. In a quarter of cases, GABAB‐R blockade shortened Down‐states and increased oscillatory frequency, changes that are independent of firing rates in Up‐states.Our computer model provides mechanisms for the experimentally observed dynamics following blockade of GABAB‐Rs, for Up/Down durations, oscillatory frequency and regularity. The time course of excitation, inhibition and adaptation can explain the observed dynamics of the network.This study brings novel insights into the role of GABAB‐R‐mediated slow inhibition on the slow oscillatory activity, which is considered the default activity pattern of the cortical network. [ABSTRACT FROM AUTHOR]

Published

2020

79. Targeting sleep oscillations to improve memory in schizophrenia.

Author

Manoach, Dara S., Mylonas, Dimitrios, and Baxter, Bryan

Subjects

*NON-REM sleep, *OSCILLATIONS, *SLEEP spindles, *BRAIN stimulation, *SCHIZOPHRENIA, *SLEEP hygiene

Abstract

Although schizophrenia is defined by waking phenomena, a growing literature documents a deficit in sleep spindles, a defining oscillation of stage 2 non-rapid eye movement sleep. Compelling evidence supports an important role for spindles in cognition, and particularly memory. In schizophrenia, although the spindle deficit correlates with impaired sleep-dependent memory consolidation, recent clinical trials find that increasing spindles does not improve memory. This may reflect that sleep-dependent memory consolidation relies not on spindles alone, but also on their precise temporal coordination with cortical slow oscillations and hippocampal sharp-wave ripples. Consequently, interventions to improve memory in schizophrenia must not only increase spindles, but also preserve or enhance slow oscillations, hippocampal ripples and their temporal relations. Because hippocampal ripples and the activity of the thalamic spindle generator are difficult to measure noninvasively, screening potential interventions requires complementary animal and human studies. In this review we (i) propose that sleep oscillations are novel pathophysiological targets for therapy to improve cognition in schizophrenia; (ii) summarize our understanding of how these oscillations interact to consolidate memory; (iii) suggest that a systems neuroscience strategy is essential to selecting and evaluating effective treatments, and illustrate this with findings from clinical trials; and (iv) selectively review the interventional literature relevant to sleep and cognition, covering both pharmacological and noninvasive brain stimulation approaches. We conclude that coordinated sleep oscillations are promising targets for improving cognition in schizophrenia and that effective therapies will need to preserve or enhance sleep oscillatory dynamics and restore function at the network level. [ABSTRACT FROM AUTHOR]

Published

2020

80. Slow Wave Sleep Is a Promising Intervention Target for Alzheimer's Disease.

Author

Lee, Yee Fun, Gerashchenko, Dmitry, Timofeev, Igor, Bacskai, Brian J., and Kastanenka, Ksenia V.

Subjects

SLOW wave sleep, ALZHEIMER'S disease, AMYLOID plaque, ALZHEIMER'S patients, SLEEP-wake cycle, NEUROFIBRILLARY tangles, EYE movements

Abstract

Alzheimer's disease (AD) is the major cause of dementia, characterized by the presence of amyloid-beta plaques and neurofibrillary tau tangles. Plaques and tangles are associated with sleep-wake cycle disruptions, including the disruptions in non-rapid eye movement (NREM) slow wave sleep (SWS). Alzheimer's patients spend less time in NREM sleep and exhibit decreased slow wave activity (SWA). Consistent with the critical role of SWS in memory consolidation, reduced SWA is associated with impaired memory consolidation in AD patients. The aberrant SWA can be modeled in transgenic mouse models of amyloidosis and tauopathy. Animal models exhibited slow wave impairments early in the disease progression, prior to the deposition of amyloid-beta plaques, however, in the presence of abundant oligomeric amyloid-beta. Optogenetic rescue of SWA successfully halted the amyloid accumulation and restored intraneuronal calcium levels in mice. On the other hand, optogenetic acceleration of slow wave frequency exacerbated amyloid deposition and disrupted neuronal calcium homeostasis. In this review, we summarize the evidence and the mechanisms underlying the existence of a positive feedback loop between amyloid/tau pathology and SWA disruptions that lead to further accumulations of amyloid and tau in AD. Moreover, since SWA disruptions occur prior to the plaque deposition, SWA disruptions may provide an early biomarker for AD. Finally, we propose that therapeutic targeting of SWA in AD might lead to an effective treatment for Alzheimer's patients. [ABSTRACT FROM AUTHOR]

Published

2020

81. A Glial‐Silicon Nanowire Electrode Junction Enabling Differentiation and Noninvasive Recording of Slow Oscillations from Primary Astrocytes.

Author

Saracino, Emanuela, Maiolo, Luca, Polese, Davide, Semprini, M., Borrachero‐Conejo, Ana Isabel, Gasparetto, Jacopo, Murtagh, Stefano, Sola, Margherita, Tomasi, Lorenzo, Valle, Francesco, Pazzini, Luca, Formaggio, Francesco, Chiappalone, Michela, Hussain, Saber, Caprini, Marco, Muccini, Michele, Ambrosio, Luigi, Fortunato, Guglielmo, Zamboni, Roberto, and Convertino, Annalisa

Subjects

ASTROCYTES, OSCILLATIONS, BRAIN physiology, ELECTRODES, SILICON nanowires, BIOMEDICAL engineering, SEMICONDUCTOR nanowires

Abstract

The correct human brain function is dependent on the activity of non‐neuronal cells called astrocytes. The bioelectrical properties of astrocytes in vitro do not closely resemble those displayed in vivo and the former are incapable of generating action potential; thus, reliable approaches in vitro for noninvasive electrophysiological recording of astrocytes remain challenging for biomedical engineering. Here it is found that primary astrocytes grown on a device formed by a forest of randomly oriented gold coated‐silicon nanowires, resembling the complex structural and functional phenotype expressed by astrocytes in vivo. The device enables noninvasive extracellular recording of the slow‐frequency oscillations generated by differentiated astrocytes, while flat electrodes failed on recording signals from undifferentiated cells. Pathophysiological concentrations of extracellular potassium, occurring during epilepsy and spreading depression, modulate the power of slow oscillations generated by astrocytes. A reliable approach to study the role of astrocytes function in brain physiology and pathologies is presented. [ABSTRACT FROM AUTHOR]

Published

2020

82. A Hierarchy of Autonomous Systems for Vocal Production.

Author

Zhang, Yisi S. and Ghazanfar, Asif A.

Subjects

*CENTRAL pattern generators, *PSYCHOLOGICAL feedback, *ANIMAL sound production, *HIERARCHIES, *DYNAMICAL systems

Abstract

Vocal production is hierarchical in the time domain. These hierarchies build upon biomechanical and neural dynamics across various timescales. We review studies in marmoset monkeys, songbirds, and other vertebrates. To organize these data in an accessible and across-species framework, we interpret the different timescales of vocal production as belonging to different levels of an autonomous systems hierarchy. The first level accounts for vocal acoustics produced on short timescales; subsequent levels account for longer timescales of vocal output. The hierarchy of autonomous systems that we put forth accounts for vocal patterning, sequence generation, dyadic interactions, and context dependence by sequentially incorporating central pattern generators, intrinsic drives, and sensory signals from the environment. We then show the framework's utility by providing an integrative explanation of infant vocal production learning in which social feedback modulates infant vocal acoustics through the tuning of a drive signal. Vocal production can be understood in terms of a timescale-based hierarchy of autonomous dynamical systems representing biomechanics and central pattern generators, internal drives, and the environment. Each level of the vocal system generates a dynamical aspect of vocal output at a specific timescale. This proposed autonomous systems framework can be used to illuminate how social reinforcement shapes the drive to generate mature sounding vocalizations in developing animals. [ABSTRACT FROM AUTHOR]

Published

2020

83. Impaired slow oscillation, sleep spindle, and slow oscillation-spindle coordination in patients with idiopathic restless legs syndrome.

Author

Cha, Kwang Su, Kim, Tae-Joon, Jun, Jin-Sun, Byun, Jung-Ick, Sunwoo, Jun-Sang, Shin, Jung-Won, Kim, Kyung Hwan, Lee, Sang Kun, and Jung, Ki-Young

Subjects

*SLEEP spindles, *RESTLESS legs syndrome, *OSCILLATIONS, *POWER density

Abstract

Objectives: Thalamocortical abnormalities have been implicated in the pathophysiology of restless legs syndrome (RLS). We hypothesized that sleep spindle and slow oscillation (SO) activity is impaired in RLS, and that this dysfunction may contribute to sleep disturbance in these patients. To address this issue, we characterized sleep spindle and SO activity in RLS.Methods: Fifteen drug-naive, idiopathic RLS patients (13 female and 2 male) and 15 female healthy controls participated in this study. Nineteen-channel electroencephalograms were obtained during polysomnographic (PSG) recordings. An automated sleep spindle and SO detection algorithm was used to detect sleep spindle (12-16 Hz) and SO (<1 Hz) activity. The quantitative characteristics of sleep spindle and SO activity were investigated.Results: Compared with the healthy controls, in RLS patients, we observed density and power reduction in sleep spindles. In SOs, density reduction and duration increment were shown in RLS patients. In addition, SO-spindle coordination was deficient in RLS as revealed by reduced SO locked spindle power, dispersed and delayed spindle phase, and decreased SO-spindle coupling. Although sleep spindle power was negatively correlated with wake after sleep onset (WASO) time, SO duration was positively correlated with the arousal index in RLS.Conclusions: Our study suggests that sleep disturbances may be mediated by a combined deficit in spindle and SO activity and SO-spindle coordination. The abnormal SO and spindle activity observed in RLS support the notion that thalamocortical abnormalities underlie this condition and may promote disturbed sleep integrity. [ABSTRACT FROM AUTHOR]

Published

2020

84. Altered Neocortical Dynamics in a Mouse Model of Williams–Beuren Syndrome.

Author

Dasilva, Miguel, Navarro-Guzman, Alvaro, Ortiz-Romero, Paula, Camassa, Alessandra, Muñoz-Cespedes, Alberto, Campuzano, Victoria, and Sanchez-Vives, Maria V.

Abstract

Williams–Beuren syndrome (WBS) is a rare neurodevelopmental disorder characterized by moderate intellectual disability and learning difficulties alongside behavioral abnormalities such as hypersociability. Several structural and functional brain alterations are characteristic of this syndrome, as well as disturbed sleep and sleeping patterns. However, the detailed physiological mechanisms underlying WBS are mostly unknown. Here, we characterized the cortical dynamics in a mouse model of WBS previously reported to replicate most of the behavioral alterations described in humans. We recorded the laminar local field potential generated in the frontal cortex during deep anesthesia and characterized the properties of the emergent slow oscillation activity. Moreover, we performed micro-electrocorticogram recordings using multielectrode arrays covering the cortical surface of one hemisphere. We found significant differences between the cortical emergent activity and functional connectivity between wild-type mice and WBS model mice. Slow oscillations displayed Up states with diminished firing rate and lower high-frequency content in the gamma range. Lower firing rates were also recorded in the awake WBS animals while performing a marble burying task and could be associated with the decreased spine density and thus synaptic connectivity in this cortical area. We also found an overall increase in functional connectivity between brain areas, reflected in lower clustering and abnormally high integration, especially in the gamma range. These results expand previous findings in humans, suggesting that the cognitive deficits characterizing WBS might be associated with reduced excitability, plus an imbalance in the capacity to functionally integrate and segregate information. [ABSTRACT FROM AUTHOR]

Published

2020

85. Dampened Slow Oscillation Connectivity Anticipates Amyloid Deposition in the PS2APP Mouse Model of Alzheimer’s Disease.

Author

Leparulo, Alessandro, Mahmud, Mufti, Scremin, Elena, Pozzan, Tullio, Vassanelli, Stefano, and Fasolato, Cristina

Subjects

*ALZHEIMER'S disease, *AMYLOID beta-protein precursor, *TRANSGENIC mice, *MICE

Abstract

To fight Alzheimer’s disease (AD), we should know when, where, and how brain network dysfunctions initiate. In AD mouse models, relevant information can be derived from brain electrical activity. With a multi-site linear probe, we recorded local field potentials simultaneously at the posterior-parietal cortex and hippocampus of wild-type and double transgenic AD mice, under anesthesia. We focused on PS2APP (B6.152H) mice carrying both presenilin-2 (PS2) and amyloid precursor protein (APP) mutations, at three and six months of age, before and after plaque deposition respectively. To highlight defects linked to either the PS2 or APP mutation, we included in the analysis age-matched PS2.30H and APP-Swedish mice, carrying each of the mutations individually. Our study also included PSEN2−/− mice. At three months, only predeposition B6.152H mice show a reduction in the functional connectivity of slow oscillations (SO) and in the power ratio between SO and delta waves. At six months, plaque-seeding B6.152H mice undergo a worsening of the low/high frequency power imbalance and show a massive loss of cortico-hippocampal phase-amplitude coupling (PAC) between SO and higher frequencies, a feature shared with amyloid-free PS2.30H mice. We conclude that the PS2 mutation is sufficient to impair SO PAC and accelerate network dysfunctions in amyloid-accumulating mice. [ABSTRACT FROM AUTHOR]

Published

2020

86. Widespread slow oscillations support interictal epileptiform discharge networks in focal epilepsy.

Author

Ye, Hongyi, Ye, Lingqi, Hu, Lingli, Yang, Yuyu, Ge, Yi, Chen, Ruotong, Wang, Shan, Jin, Bo, Ming, Wenjie, Wang, Zhongjin, Xu, Sha, Xu, Cenglin, Wang, Yi, Ding, Yao, Zhu, Junming, Ding, Meiping, Chen, Zhong, Wang, Shuang, and Chen, Cong

Subjects

*PARTIAL epilepsy, *EPILEPTIFORM discharges, *OSCILLATIONS, *PEOPLE with epilepsy, *EYE movements

Abstract

Interictal epileptiform discharges (IEDs) often co-occur across spatially-separated cortical regions, forming IED networks. However, the factors prompting IED propagation remain unelucidated. We hypothesized that slow oscillations (SOs) might facilitate IED propagation. Here, the amplitude and phase synchronization of SOs preceding propagating and non-propagating IEDs were compared in 22 patients with focal epilepsy undergoing intracranial electroencephalography (EEG) evaluation. Intracranial channels were categorized into the irritative zone (IZ) and normal zone (NOZ) regarding the presence of IEDs. During wakefulness, we found that pre-IED SOs within the IZ exhibited higher amplitudes for propagating IEDs than non-propagating IEDs (delta band: p = 0.001, theta band: p < 0.001). This increase in SOs was also concurrently observed in the NOZ (delta band: p = 0.04). Similarly, the inter-channel phase synchronization of SOs prior to propagating IEDs was higher than those preceding non-propagating IEDs in the IZ (delta band: p = 0.04). Through sliding window analysis, we observed that SOs preceding propagating IEDs progressively increased in amplitude and phase synchronization, while those preceding non-propagating IEDs remained relatively stable. Significant differences in amplitude occurred approximately 1150 ms before IEDs. During non-rapid eye movement (NREM) sleep, SOs on scalp recordings also showed higher amplitudes before intracranial propagating IEDs than before non-propagating IEDs (delta band: p = 0.006). Furthermore, the analysis of IED density around sleep SOs revealed that only high-amplitude sleep SOs demonstrated correlation with IED propagation. Overall, our study highlights that transient but widely distributed SOs are associated with IED propagation as well as generation in focal epilepsy during sleep and wakefulness, providing new insight into the EEG substrate supporting IED networks. • An increase in slow oscillations (SOs) preceding IEDs was observed in the irritative zone and normal zone. • SOs have higher amplitudes before propagating IEDs than before non-propagating IEDs. • Pre-IED SOs show distinct evolution patterns for propagating IEDs versus non-propagating IEDs. • IEDs can exhibit a longer propagation delay (200–500 ms) than previously believed. • SOs correlate with IED generation and propagation during both sleep and wakefulness. [ABSTRACT FROM AUTHOR]

Published

2024

87. Shining a Light on the Mechanisms of Sleep for Memory Consolidation

Author

Frazer, Michelle A., Cabrera, Yesenia, Guthrie, Rockelle S., and Poe, Gina R.

Published

2021

88. Analysis Pipeline for Extracting Features of Cortical Slow Oscillations

Author

Giulia De Bonis, Miguel Dasilva, Antonio Pazienti, Maria V. Sanchez-Vives, Maurizio Mattia, and Pier Stanislao Paolucci

Subjects

slow-wave activity, slow oscillations, analysis pipeline, software tools, cortical areas, multi-electrode arrays (MEAs), Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Cortical slow oscillations (≲1 Hz) are an emergent property of the cortical network that integrate connectivity and physiological features. This rhythm, highly revealing of the characteristics of the underlying dynamics, is a hallmark of low complexity brain states like sleep, and represents a default activity pattern. Here, we present a methodological approach for quantifying the spatial and temporal properties of this emergent activity. We improved and enriched a robust analysis procedure that has already been successfully applied to both in vitro and in vivo data acquisitions. We tested the new tools of the methodology by analyzing the electrocorticography (ECoG) traces recorded from a custom 32-channel multi-electrode array in wild-type isoflurane-anesthetized mice. The enhanced analysis pipeline, named SWAP (Slow Wave Analysis Pipeline), detects Up and Down states, enables the characterization of the spatial dependency of their statistical properties, and supports the comparison of different subjects. The SWAP is implemented in a data-independent way, allowing its application to other data sets (acquired from different subjects, or with different recording tools), as well as to the outcome of numerical simulations. By using the SWAP, we report statistically significant differences in the observed slow oscillations (SO) across cortical areas and cortical sites. Computing cortical maps by interpolating the features of SO acquired at the electrode positions, we give evidence of gradients at the global scale along an oblique axis directed from fronto-lateral toward occipito-medial regions, further highlighting some heterogeneity within cortical areas. The results obtained using the SWAP will be essential for producing data-driven brain simulations. A spatial characterization of slow oscillations will also trigger a discussion on the role of, and the interplay between, the different regions in the cortex, improving our understanding of the mechanisms of generation and propagation of delta rhythms and, more generally, of cortical properties.

Published

2019

89. Individualized temporal patterns dominate cortical upstate and sleep depth in driving human sleep spindle timing.

Author

Chen S, He M, Brown RE, Eden UT, and Prerau MJ

Abstract

Sleep spindles are critical for memory consolidation and strongly linked to neurological disease and aging. Despite their significance, the relative influences of factors like sleep depth, cortical up/down states, and spindle temporal patterns on individual spindle production remain poorly understood. Moreover, spindle temporal patterns are typically ignored in favor of an average spindle rate. Here, we analyze spindle dynamics in 1008 participants from the Multi-Ethnic Study of Atherosclerosis using a point process framework. Results reveal fingerprint-like temporal patterns, characterized by a refractory period followed by a period of increased spindle activity, which are highly individualized yet consistent night-to-night. We observe increased timing variability with age and distinct gender/age differences. Strikingly, and in contrast to the prevailing notion, individualized spindle patterns are the dominant determinant of spindle timing, accounting for over 70% of the statistical deviance explained by all of the factors we assessed, surpassing the contribution of slow oscillation (SO) phase (~14%) and sleep depth (~16%). Furthermore, we show spindle/SO coupling dynamics with sleep depth are preserved across age, with a global negative shift towards the SO rising slope. These findings offer novel mechanistic insights into spindle dynamics with direct experimental implications and applications to individualized electroencephalography biomarker identification., Competing Interests: DISCLOSURE STATEMENT R.E.B. is a Research Health Scientist at VA Boston Healthcare System, West Roxbury, MA. The contents of this work do not represent the views of the US Department of Veterans Affairs or the United States Government.

Published

2024

90. Sounding It Out: Auditory Stimulation and Overnight Memory Processing

Author

Harrington, Marcus O. and Cairney, Scott A.

Published

2021

91. Analysis Pipeline for Extracting Features of Cortical Slow Oscillations.

Author

De Bonis, Giulia, Dasilva, Miguel, Pazienti, Antonio, Sanchez-Vives, Maria V., Mattia, Maurizio, and Paolucci, Pier Stanislao

Subjects

OSCILLATIONS, PIPELINES, WAVE analysis, ACQUISITION of data, SOFTWARE development tools

Abstract

Cortical slow oscillations (≲1 Hz) are an emergent property of the cortical network that integrate connectivity and physiological features. This rhythm, highly revealing of the characteristics of the underlying dynamics, is a hallmark of low complexity brain states like sleep, and represents a default activity pattern. Here, we present a methodological approach for quantifying the spatial and temporal properties of this emergent activity. We improved and enriched a robust analysis procedure that has already been successfully applied to both in vitro and in vivo data acquisitions. We tested the new tools of the methodology by analyzing the electrocorticography (ECoG) traces recorded from a custom 32-channel multi-electrode array in wild-type isoflurane-anesthetized mice. The enhanced analysis pipeline, named SWAP (Slow Wave Analysis Pipeline), detects Up and Down states, enables the characterization of the spatial dependency of their statistical properties, and supports the comparison of different subjects. The SWAP is implemented in a data-independent way, allowing its application to other data sets (acquired from different subjects, or with different recording tools), as well as to the outcome of numerical simulations. By using the SWAP, we report statistically significant differences in the observed slow oscillations (SO) across cortical areas and cortical sites. Computing cortical maps by interpolating the features of SO acquired at the electrode positions, we give evidence of gradients at the global scale along an oblique axis directed from fronto-lateral toward occipito-medial regions, further highlighting some heterogeneity within cortical areas. The results obtained using the SWAP will be essential for producing data-driven brain simulations. A spatial characterization of slow oscillations will also trigger a discussion on the role of, and the interplay between, the different regions in the cortex, improving our understanding of the mechanisms of generation and propagation of delta rhythms and, more generally, of cortical properties. [ABSTRACT FROM AUTHOR]

Published

2019

92. Altered slow (<1 Hz) and fast (beta and gamma) neocortical oscillations in the 3xTg-AD mouse model of Alzheimer's disease under anesthesia.

Author

Castano-Prat, Patricia, Perez-Mendez, Lorena, Perez-Zabalza, Maria, Sanfeliu, Coral, Giménez-Llort, Lydia, and Sanchez-Vives, Maria V.

Subjects

*ALZHEIMER'S disease, *OSCILLATIONS, *MICE, *ETIOLOGY of diseases

Abstract

The 3xTg-AD mouse model reproduces the main features associated with the etiology of familial Alzheimer's disease (AD). To investigate whether these features imply functional cortical network alterations and their evolution with age, we studied spontaneous slow oscillations, activity that integrates cellular and network properties. We quantified different parameters of the emergent slow oscillations—alternating Up and Down states—and of the embedded beta-gamma rhythms of 3xTg-AD and wild-type mice at 7 and 20 months of age. Most group differences occurred at 20 months of age: 3xTg-AD mice presented lower oscillatory frequency, higher cycle variability, and reduced relative (Up/Down) firing rate with respect to controls. The high-frequency analysis revealed a shift toward lower frequencies in older 3xTg-AD animals, reminiscent of one of the electroencephalography hallmarks of patients with AD. This first systematic characterization of the cortical emergent rhythms in 3xTg-AD strain provides insights into the network mechanisms underlying associated network activity alterations. • We characterized cortical dynamics in the 3xTg mouse model of Alzheimer's disease. • We studied 7- and 20-month-old 3xTg and wild type to study the effects of aging. • 20-mo-old 3xTg mice had lower oscillatory frequency and higher cycle variability. • High-frequency rhythms were shifted towards lower frequencies in older 3xTg-AD. • We bridge cellular and network studies with the features described in AD patients. [ABSTRACT FROM AUTHOR]

Published

2019

93. Slow oscillatory transcranial direct current stimulation (so-tDCS) during slow wave sleep has no effects on declarative memory in healthy young subjects.

Author

Bueno-Lopez, A., Eggert, T., Dorn, H., and Danker-Hopfe, H.

Abstract

The manipulation of specific brain oscillations by applying transcranial electrical stimulation techniques in order to enhance memory processes during sleep has become an intriguing field of research. A seminal study found a positive effect of slow-oscillatory transcranial direct current stimulation (so-tDCS) on sleep-dependent consolidation of declarative memories. Since then several studies have tried to replicate this result with inconsistent findings. This study aimed to reexamine effects of so-tDCS on declarative memory observed in young participants based on a previously described stimulation protocol used in elderly subjects. 23 healthy participants (mean ± SD: 23.2 ± 1.9 years; 13 women) completed a word-pair test and a sequential finger tapping test before and after sleep. Participants received anodal so-tDCS bifrontaly at a frequency of 0.75 Hz or sham stimulation during NREM sleep N2, following a double-blind, placebo controlled, counterbalanced, randomized crossover design. Data were analyzed with respect to possible effects of stimulation on memory performances, sleep staging, spindle densities and EEG power in eight frequency bands. Stimulation had no significant effect on sleep dependent memory consolidation or on sleep macro- and microstructure. Independent of stimulation, procedural memory performances increased and declarative memory performances decreased overnight. This decline was less pronounced when participants had more than one learning opportunity. Fast parietal but not slow frontal spindle densities diminished from baseline to stimulation-free intervals under both stimulation conditions. The present study could not reproduce the results of the seminal study in young subjects, but it is consistent with results observed in elderly subjects using the same protocol. Irrespective of stimulation, re-encoding opportunities in the word-pair test had an impact on memory strength and retrieval performance. • So-tDCS has no effect on sleep-dependent memory consolidation, sleep stages, sleep EEG-power, and sleep spindle densities. • In the procedural task, performances showed an overnight increased independent of stimulation. • Word-pair retention decreased independent of stimulation. • Re-encoding opportunities seem to be critical for learning and retrieval performance in declarative memory tasks. • The non-significant results may be explained by a lack of entrainment. [ABSTRACT FROM AUTHOR]

Published

2019

94. Hippocampal coupling with cortical and subcortical structures in the context of memory consolidation.

Author

Skelin, Ivan, Kilianski, Scott, and McNaughton, Bruce L.

Subjects

*MEMORY, *SLEEP spindles, *NON-REM sleep, *EPISODIC memory, *SEMANTIC memory, *OSCILLATIONS

Abstract

Highlights • Hippocampal-cortical/subcortical communication supports memory consolidation. • The precise dynamics and regulation of this process are not understood. • Memory reactivation throughout the brain is coupled with sharp wave/ripples. • Larger recording coverage is needed to fully characterize these interactions. Abstract Memory consolidation is a gradual process through which episodic memories become incorporated into long-term 'semantic' representations. It likely involves reactivation of neural activity encoding the recent experience during non-REM sleep. A critical prerequisite for memory consolidation is precise coordination of reactivation events between the hippocampus and cortical/subcortical structures, facilitated by the coupling of local field potential (LFP) oscillations (slow oscillations, sleep spindles and sharp wave/ripples) between these structures. We review the rapidly expanding literature on the qualitative and quantitative aspects of hippocampal oscillatory and neuronal coupling with cortical/subcortical structures in the context of memory reactivation. Reactivation in the hippocampus and cortical/subcortical structures is tightly coupled with sharp wave/ripples. Hippocampal-cortical/subcortical coupling is rich in dimensionality and this dimensionality is likely underestimated due to the limitations of the current methodology. [ABSTRACT FROM AUTHOR]

Published

2019

95. Stimulating the sleeping brain: Current approaches to modulating memory-related sleep physiology.

Author

Cellini, Nicola and Mednick, Sara C.

Subjects

*SLEEP, *EXPLICIT memory, *ACOUSTIC stimulation, *VESTIBULAR stimulation, *HISTORY of psychology, *SLEEP physiology

Abstract

Highlights • The sleeping brain can be manipulated to strengthen recent memories. • Olfactory and acoustic stimulation can modulate memory-related sleep physiology. • Transcranial electrical stimulation during sleep can improve declarative memories. • Pharmacological approaches can be use to enhance a specific sleep feature. • Different approaches can be combined to facilitate memory consolidation. Abstract Background One of the most audacious proposals throughout the history of psychology was the potential ability to learn while we sleep. The idea penetrated culture via sci-fi movies and inspired the invention of devices that claimed to teach foreign languages, facts, and even quit smoking by simply listening to audiocassettes or other devices during sleep. However, the promises from this endeavor didn't stand up to experimental scrutiny, and the dream was shunned from the scientific community. Despite the historic evidence that the sleeping brain cannot learn new complex information (i.e., words, images, facts), a new wave of current interventions are demonstrating that sleep can be manipulated to strengthen recent memories. New method Several recent approaches have been developed that play with the sleeping brain in order to modify ongoing memory processing. Here, we provide an overview of the available techniques to non-invasively modulate memory-related sleep physiology, including sensory, vestibular and electrical stimulation, as well as pharmacological approaches. Results N/A. Comparison with existing methods N/A. Conclusions Although the results are encouraging, suggesting that in general the sleeping brain may be optimized for better memory performance, the road to bring these techniques in free-living conditions is paved with unanswered questions and technical challenges that need to be carefully addressed. [ABSTRACT FROM AUTHOR]

Published

2019

96. Closed-loop auditory stimulation of sleep slow oscillations: Basic principles and best practices.

Author

Esfahani, Mahdad Jafarzadeh, Farboud, Soha, Ngo, Hong-Viet V., Schneider, Jules, Weber, Frederik D., Talamini, Lucia M., and Dresler, Martin

Subjects

*ACOUSTIC stimulation, *OSCILLATIONS, *SLEEP, *BEST practices, *MENTAL health

Abstract

Sleep is essential for our physical and mental well-being. During sleep, despite the paucity of overt behavior, our brain remains active and exhibits a wide range of coupled brain oscillations. In particular slow oscillations are characteristic for sleep, however whether they are directly involved in the functions of sleep, or are mere epiphenomena, is not yet fully understood. To disentangle the causality of these relationships, experiments utilizing techniques to detect and manipulate sleep oscillations in real-time are essential. In this review, we first overview the theoretical principles of closed-loop auditory stimulation (CLAS) as a method to study the role of slow oscillations in the functions of sleep. We then describe technical guidelines and best practices to perform CLAS and analyze results from such experiments. We further provide an overview of how CLAS has been used to investigate the causal role of slow oscillations in various sleep functions. We close by discussing important caveats, open questions, and potential topics for future research. • Slow oscillations during sleep associated with the functions of sleep. • Closed-loop auditory stimulation (CLAS) of sleep slow oscillations allow to modulate sleep function. • Procedural details between stimulation approaches differ, contributing to conflicting findings. • Basic principles and best practices for CLAS provide a unifying theoretical and practical manual for future research. [ABSTRACT FROM AUTHOR]

Published

2023

97. Electroencephalographic and neurophysiological changes

Author

Maurizio Gorgoni, Federico Salfi, Luigi De Gennaro, and Michele Ferrara

Subjects

Cortical topography, Fast fourier transform (FFT), Sleep onset, Homeostatic regulation, Slow oscillations, Sleep spindles, Synchronization, Hippocampus, Prefrontal cortex (PFC), Hyperfrontality of SWA, Two-process model, Intracranic recordings, Cortical topography, Fast fourier transform (FFT), Hippocampus, Homeostatic regulation, Hyperfrontality of SWA, Intracranic recordings, K-complex, Prefrontal cortex (PFC), Sleep onset, Sleep spindles, Slow oscillations, Slow-wave activity (SWA), Synchronization, Thalamocortical network, Two-process model, Thalamocortical network, K-complex, Slow-wave activity (SWA)

Published

2023

98. Boosting Slow Oscillations during Sleep to Improve Memory Function in Elderly People: A Review of the Literature

Author

Federico Salfi, Aurora D’Atri, Daniela Tempesta, Luigi De Gennaro, and Michele Ferrara

Subjects

slow oscillations, memory consolidation, acoustic stimulation, so-tDCS, aging, sleeping brain stimulation, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Sleep represents a crucial time window for the consolidation of memory traces. In this view, some brain rhythms play a pivotal role, first of all the sleep slow waves. In particular, the neocortical slow oscillations (SOs), in coordination with the hippocampal ripples and the thalamocortical spindles, support the long-term storage of the declarative memories. The aging brain is characterized by a disruption of this complex system with outcomes on the related cognitive functions. In recent years, the advancement of the comprehension of the sleep-dependent memory consolidation mechanisms has encouraged the development of techniques of SO enhancement during sleep to induce cognitive benefits. In this review, we focused on the studies reporting on the application of acoustic or electric stimulation procedures in order to improve sleep-dependent memory consolidation in older subjects. Although the current literature is limited and presents inconsistencies, there is promising evidence supporting the perspective to non-invasively manipulate the sleeping brain electrophysiology to improve cognition in the elderly, also shedding light on the mechanisms underlying the sleep-memory relations during healthy and pathological aging.

Published

2020

99. Quantification of Signal-to-Noise Ratio in Cerebral Cortex Recordings Using Flexible MEAs With Co-localized Platinum Black, Carbon Nanotubes, and Gold Electrodes

Author

Alex Suarez-Perez, Gemma Gabriel, Beatriz Rebollo, Xavi Illa, Anton Guimerà-Brunet, Javier Hernández-Ferrer, Maria Teresa Martínez, Rosa Villa, and Maria V. Sanchez-Vives

Subjects

SNR, neural recording, slow oscillations, low impedance, neural interfaces, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Developing new standardized tools to characterize brain recording devices is critical to evaluate neural probes and for translation to clinical use. The signal-to-noise ratio (SNR) measurement is the gold standard for quantifying the performance of brain recording devices. Given the drawbacks with the SNR measure, our first objective was to devise a new method to calculate the SNR of neural signals to distinguish signal from noise. Our second objective was to apply this new SNR method to evaluate electrodes of three different materials (platinum black, Pt; carbon nanotubes, CNTs; and gold, Au) co-localized in tritrodes to record from the same cortical area using specifically designed multielectrode arrays. Hence, we devised an approach to calculate SNR at different frequencies based on the features of cortical slow oscillations (SO). Since SO consist in the alternation of silent periods (Down states) and active periods (Up states) of neuronal activity, we used these as noise and signal, respectively. The spectral SNR was computed as the power spectral density (PSD) of Up states (signal) divided by the PSD of Down states (noise). We found that Pt and CNTs electrodes have better recording performance than Au electrodes for the explored frequency range (5–1500 Hz). Together with two proposed SNR estimators for the lower and upper frequency limits, these results substantiate our SNR calculation at different frequency bands. Our results provide a new validated SNR measure that provides rich information of the performance of recording devices at different brain activity frequency bands (

Published

2018

100. Dampened Slow Oscillation Connectivity Anticipates Amyloid Deposition in the PS2APP Mouse Model of Alzheimer’s Disease

Author

Alessandro Leparulo, Mufti Mahmud, Elena Scremin, Tullio Pozzan, Stefano Vassanelli, and Cristina Fasolato

Subjects

alzheimer’s disease, b6.152h, ps2app, amyloid precursor protein, presenilin-2, amyloid-β, slow oscillations, local field potentials, functional connectivity, phase-amplitude-coupling, Cytology, QH573-671

Abstract

To fight Alzheimer’s disease (AD), we should know when, where, and how brain network dysfunctions initiate. In AD mouse models, relevant information can be derived from brain electrical activity. With a multi-site linear probe, we recorded local field potentials simultaneously at the posterior-parietal cortex and hippocampus of wild-type and double transgenic AD mice, under anesthesia. We focused on PS2APP (B6.152H) mice carrying both presenilin-2 (PS2) and amyloid precursor protein (APP) mutations, at three and six months of age, before and after plaque deposition respectively. To highlight defects linked to either the PS2 or APP mutation, we included in the analysis age-matched PS2.30H and APP-Swedish mice, carrying each of the mutations individually. Our study also included PSEN2−/− mice. At three months, only predeposition B6.152H mice show a reduction in the functional connectivity of slow oscillations (SO) and in the power ratio between SO and delta waves. At six months, plaque-seeding B6.152H mice undergo a worsening of the low/high frequency power imbalance and show a massive loss of cortico-hippocampal phase-amplitude coupling (PAC) between SO and higher frequencies, a feature shared with amyloid-free PS2.30H mice. We conclude that the PS2 mutation is sufficient to impair SO PAC and accelerate network dysfunctions in amyloid-accumulating mice.

Published

2019