Causality of cortical and cardiovascular activity during cyclic alternating pattern in non-rapid eye movement sleep

Hartmann, Simon; Ferri, Raffaele; Bruni, Oliviero; Baumert, Mathias

doi:10.1098/rsta.2020.0248

Cited by 11 publications

(14 citation statements)

References 67 publications

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“…An example is the study by Hartmann et al, where GC was used to study the brain-heart interactions during the cyclic alternating pattern of non-rapid eye movement sleep (Hartmann et al, 2021). According to the authors, their study provided the first evidence on the causal interplay between cortical and cardiovascular activities during cyclic alternating pattern.…”

Section: Introductionmentioning

confidence: 99%

“…Despite the popularity of GC in neuroscience applications, including in the study of physiological states similar to sleep, such as anesthesia ( Nicolaou et al, 2012 ; Pullon et al, 2020 ), there are only a handful of studies applying it in sleep. An example is the study by Hartmann et al, where GC was used to study the brain-heart interactions during the cyclic alternating pattern of non-rapid eye movement sleep ( Hartmann et al, 2021 ). According to the authors, their study provided the first evidence on the causal interplay between cortical and cardiovascular activities during cyclic alternating pattern .…”

Section: Introductionmentioning

confidence: 99%

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Brain and brain-heart Granger causality during wakefulness and sleep

Abdalbari

Durrani²,

Pancholi³

et al. 2022

Front. Neurosci.

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In this exploratory study we apply Granger Causality (GC) to investigate the brain-brain and brain-heart interactions during wakefulness and sleep. Our analysis includes electroencephalogram (EEG) and electrocardiogram (ECG) data during all-night polysomnographic recordings from volunteers with apnea, available from the Massachusetts General Hospital’s Computational Clinical Neurophysiology Laboratory and the Clinical Data Animation Laboratory. The data is manually annotated by clinical staff at the MGH in 30 second contiguous intervals (wakefulness and sleep stages 1, 2, 3, and rapid eye movement (REM). We applied GC to 4-s non-overlapping segments of available EEG and ECG across all-night recordings of 50 randomly chosen patients. To identify differences in GC between the different sleep stages, the GC for each sleep stage was subtracted from the GC during wakefulness. Positive (negative) differences indicated that GC was greater (lower) during wakefulness compared to the specific sleep stage. The application of GC to study brain-brain and brain-heart bidirectional connections during wakefulness and sleep confirmed the importance of fronto-posterior connectivity during these two states, but has also revealed differences in ipsilateral and contralateral mechanisms of these connections. It has also confirmed the existence of bidirectional brain-heart connections that are more prominent in the direction from brain to heart. Our exploratory study has shown that GC can be successfully applied to sleep data analysis and captures the varying physiological mechanisms that are related to wakefulness and different sleep stages.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Brain and brain-heart Granger causality during wakefulness and sleep

Abdalbari

Durrani²,

Pancholi³

et al. 2022

Front. Neurosci.

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show abstract

“…SA and its associated causes are quite hazardous to one's health, most notably in patients with pre-existing cardiac and bronchopulmonary pathology. Three hundred to four hundred thousand of these patients die during sleep each year in the USA alone [2,[88][89][90][91]. We have already discussed SIDS and its impact on infants.…”

Section: Sleep Apnea and Sudden Unexplained Death During Sleep (Suds)mentioning

confidence: 99%

Sleep apnea pathophysiology

Andrisani

2023

Sleep Breath

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Objective The purpose of this study is to examine the pathophysiology underlying sleep apnea (SA). Background We consider several critical features of SA including the roles played by the ascending reticular activating system (ARAS) that controls vegetative functions and electroencephalographic findings associated with both SA and normal sleep. We evaluate this knowledge together with our current understanding of the anatomy, histology, and physiology of the mesencephalic trigeminal nucleus (MTN) and mechanisms that contribute directly to normal and disordered sleep. MTN neurons express γ-aminobutyric acid (GABA) receptors which activate them (make chlorine come out of the cells) and that can be activated by GABA released from the hypothalamic preoptic area. Method We reviewed the published literature focused on sleep apnea (SA) reported in Google Scholar, Scopus, and PubMed databases. Results The MTN neurons respond to the hypothalamic GABA release by releasing glutamate that activates neurons in the ARAS. Based on these findings, we conclude that a dysfunctional MTN may be incapable of activating neurons in the ARAS, notably those in the parabrachial nucleus, and that this will ultimately lead to SA. Despite its name, obstructive sleep apnea (OSA) is not caused by an airway obstruction that prevents breathing. Conclusions While obstruction may contribute to the overall pathology, the primary factor involved in this scenario is the lack of neurotransmitters.

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“…The proposed framework relies on a maximal information coefficient analysis between nonlinear multiscale features derived from electroencephalographic spectra and from an inhomogeneous point-process model for heartbeat dynamics. Hartmann et al [15] study the dynamic interplay between the central and autonomic nervous system activity during sleep. Focusing on non-rapid eye movement sleep stages, they show the causal interplay between cortical and cardiovascular activity during cyclic alternating patterns.…”

Section: Editorialmentioning

confidence: 99%

Advanced computation in cardiovascular physiology: new challenges and opportunities

Valenza

Faes

Toschi

et al. 2021

Phil. Trans. R. Soc. A.

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Recent developments in computational physiology have successfully exploited advanced signal processing and artificial intelligence tools for predicting or uncovering characteristic features of physiological and pathological states in humans. While these advanced tools have demonstrated excellent diagnostic capabilities, the high complexity of these computational 'black boxes’ may severely limit scientific inference, especially in terms of biological insight about both physiology and pathological aberrations. This theme issue highlights current challenges and opportunities of advanced computational tools for processing dynamical data reflecting autonomic nervous system dynamics, with a specific focus on cardiovascular control physiology and pathology. This includes the development and adaptation of complex signal processing methods, multivariate cardiovascular models, multiscale and nonlinear models for central-peripheral dynamics, as well as deep and transfer learning algorithms applied to large datasets. The width of this perspective highlights the issues of specificity in heartbeat-related features and supports the need for an imminent transition from the black-box paradigm to explainable and personalized clinical models in cardiovascular research. This article is part of the theme issue 'Advanced computation in cardiovascular physiology: new challenges and opportunities'.

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Causality of cortical and cardiovascular activity during cyclic alternating pattern in non-rapid eye movement sleep

Cited by 11 publications

References 67 publications

Brain and brain-heart Granger causality during wakefulness and sleep

Brain and brain-heart Granger causality during wakefulness and sleep

Sleep apnea pathophysiology

Advanced computation in cardiovascular physiology: new challenges and opportunities

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