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Assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia

Cerebral blood flow (CBF) reflects the rate of delivery of arterial blood to the brain. Since no nutrients, oxygen or water can be stored in the cranial cavity due to space and pressure restrictions, a continuous perfusion of the brain is critical for survival. Anesthetic procedures are known to aff...

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Autores principales: González, Carmen, Garcia-Hernando, Gabriel, Jensen, Erik W., Vallverdú-Ferrer, Montserrat
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2022
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10013012/
https://www.ncbi.nlm.nih.gov/pubmed/36926077
http://dx.doi.org/10.3389/fnetp.2022.912733
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author González, Carmen
Garcia-Hernando, Gabriel
Jensen, Erik W.
Vallverdú-Ferrer, Montserrat
author_facet González, Carmen
Garcia-Hernando, Gabriel
Jensen, Erik W.
Vallverdú-Ferrer, Montserrat
author_sort González, Carmen
collection PubMed
description Cerebral blood flow (CBF) reflects the rate of delivery of arterial blood to the brain. Since no nutrients, oxygen or water can be stored in the cranial cavity due to space and pressure restrictions, a continuous perfusion of the brain is critical for survival. Anesthetic procedures are known to affect cerebral hemodynamics, but CBF is only monitored in critical patients due, among others, to the lack of a continuous and affordable bedside monitor for this purpose. A potential solution through bioelectrical impedance technology, also known as rheoencephalography (REG), is proposed, that could fill the existing gap for a low-cost and effective CBF monitoring tool. The underlying hypothesis is that REG signals carry information on CBF that might be recovered by means of the application of advanced signal processing techniques, allowing to track CBF alterations during anesthetic procedures. The analysis of REG signals was based on geometric features extracted from the time domain in the first place, since this is the standard processing strategy for this type of physiological data. Geometric features were tested to distinguish between different anesthetic depths, and they proved to be capable of tracking cerebral hemodynamic changes during anesthesia. Furthermore, an approach based on Poincaré plot features was proposed, where the reconstructed attractors form REG signals showed significant differences between different anesthetic states. This was a key finding, providing an alternative to standard processing of REG signals and supporting the hypothesis that REG signals do carry CBF information. Furthermore, the analysis of cerebral hemodynamics during anesthetic procedures was performed by means of studying causal relationships between global hemodynamics, cerebral hemodynamics and electroencephalogram (EEG) based-parameters. Interactions were detected during anesthetic drug infusion and patient positioning (Trendelenburg positioning and passive leg raise), providing evidence of the causal coupling between hemodynamics and brain activity. The provided alternative of REG signal processing confirmed the hypothesis that REG signals carry information on CBF. The simplicity of the technology, together with its low cost and easily interpretable outcomes, should provide a new opportunity for REG to reach standard clinical practice. Moreover, causal relationships among the hemodynamic physiological signals and brain activity were assessed, suggesting that the inclusion of REG information in depth of anesthesia monitors could be of valuable use to prevent unwanted CBF alterations during anesthetic procedures.
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spelling pubmed-100130122023-03-15 Assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia González, Carmen Garcia-Hernando, Gabriel Jensen, Erik W. Vallverdú-Ferrer, Montserrat Front Netw Physiol Network Physiology Cerebral blood flow (CBF) reflects the rate of delivery of arterial blood to the brain. Since no nutrients, oxygen or water can be stored in the cranial cavity due to space and pressure restrictions, a continuous perfusion of the brain is critical for survival. Anesthetic procedures are known to affect cerebral hemodynamics, but CBF is only monitored in critical patients due, among others, to the lack of a continuous and affordable bedside monitor for this purpose. A potential solution through bioelectrical impedance technology, also known as rheoencephalography (REG), is proposed, that could fill the existing gap for a low-cost and effective CBF monitoring tool. The underlying hypothesis is that REG signals carry information on CBF that might be recovered by means of the application of advanced signal processing techniques, allowing to track CBF alterations during anesthetic procedures. The analysis of REG signals was based on geometric features extracted from the time domain in the first place, since this is the standard processing strategy for this type of physiological data. Geometric features were tested to distinguish between different anesthetic depths, and they proved to be capable of tracking cerebral hemodynamic changes during anesthesia. Furthermore, an approach based on Poincaré plot features was proposed, where the reconstructed attractors form REG signals showed significant differences between different anesthetic states. This was a key finding, providing an alternative to standard processing of REG signals and supporting the hypothesis that REG signals do carry CBF information. Furthermore, the analysis of cerebral hemodynamics during anesthetic procedures was performed by means of studying causal relationships between global hemodynamics, cerebral hemodynamics and electroencephalogram (EEG) based-parameters. Interactions were detected during anesthetic drug infusion and patient positioning (Trendelenburg positioning and passive leg raise), providing evidence of the causal coupling between hemodynamics and brain activity. The provided alternative of REG signal processing confirmed the hypothesis that REG signals carry information on CBF. The simplicity of the technology, together with its low cost and easily interpretable outcomes, should provide a new opportunity for REG to reach standard clinical practice. Moreover, causal relationships among the hemodynamic physiological signals and brain activity were assessed, suggesting that the inclusion of REG information in depth of anesthesia monitors could be of valuable use to prevent unwanted CBF alterations during anesthetic procedures. Frontiers Media S.A. 2022-08-29 /pmc/articles/PMC10013012/ /pubmed/36926077 http://dx.doi.org/10.3389/fnetp.2022.912733 Text en Copyright © 2022 González, Garcia-Hernando, Jensen and Vallverdú-Ferrer. https://creativecommons.org/licenses/by/4.0/This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Network Physiology
González, Carmen
Garcia-Hernando, Gabriel
Jensen, Erik W.
Vallverdú-Ferrer, Montserrat
Assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia
title Assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia
title_full Assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia
title_fullStr Assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia
title_full_unstemmed Assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia
title_short Assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia
title_sort assessing rheoencephalography dynamics through analysis of the interactions among brain and cardiac networks during general anesthesia
topic Network Physiology
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10013012/
https://www.ncbi.nlm.nih.gov/pubmed/36926077
http://dx.doi.org/10.3389/fnetp.2022.912733
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