In this work, we extend to the multivariate case the classical correlation analysis used in the field of network physiology to probe dynamic interactions between organ systems in the human body. To this end, we define different correlation-based measures of the multivariate interaction (MI) within and between the brain and body subnetworks of the human physiological network, represented, respectively, by the time series of delta, theta, alpha, and beta electroencephalographic (EEG) wave amplitudes, and of heart rate, respiration amplitude, and pulse arrival time (PAT) variability. MI is computed: (i) considering all variables in the two subnetworks to evaluate overall brain–body interactions; (ii) focusing on a single target variable and di...
The heart begins to beat before the brain is formed. Whether conventional hierarchical central comma...
<div><p>The heart begins to beat before the brain is formed. Whether conventional hierarchical centr...
<p>Brain areas are represented by Frontal (Fp1 and Fp2), Central (C3 and C4) and Occipital (O1 and O...
In this work, we extend to the multivariate case the classical correlation analysis used in the fiel...
The brain continuously receives input from the internal and external environment. Using this informa...
In this work, we analyze brain-heart interactions during different mental states computing mutual in...
Introduction: Salience network (SN) has been proposed to play a role in the switchings between defau...
In this study, an analysis of brain, cardiovascular and respiratory dynamics was conducted combining...
The human organism is an integrated network where multi-component organ systems, each with its own r...
We acknowledge support from the W. M. Keck Foundation, and the US Israel Binational Science Foundati...
We present a method to analyze the dynamics of physiological networks beyond the framework of pairwi...
Functional neuroimaging and electrophysiological studies have documented a dynamic baseline of intri...
With combined EEG-fMRI a powerful combination of methods was developed in the last decade that seems...
Resting-state fMRI studies have shown that multiple functional networks, which consist of distribute...
<p>Interactions among organ systems are represented by weighted undirected graphs, where links refle...
The heart begins to beat before the brain is formed. Whether conventional hierarchical central comma...
<div><p>The heart begins to beat before the brain is formed. Whether conventional hierarchical centr...
<p>Brain areas are represented by Frontal (Fp1 and Fp2), Central (C3 and C4) and Occipital (O1 and O...
In this work, we extend to the multivariate case the classical correlation analysis used in the fiel...
The brain continuously receives input from the internal and external environment. Using this informa...
In this work, we analyze brain-heart interactions during different mental states computing mutual in...
Introduction: Salience network (SN) has been proposed to play a role in the switchings between defau...
In this study, an analysis of brain, cardiovascular and respiratory dynamics was conducted combining...
The human organism is an integrated network where multi-component organ systems, each with its own r...
We acknowledge support from the W. M. Keck Foundation, and the US Israel Binational Science Foundati...
We present a method to analyze the dynamics of physiological networks beyond the framework of pairwi...
Functional neuroimaging and electrophysiological studies have documented a dynamic baseline of intri...
With combined EEG-fMRI a powerful combination of methods was developed in the last decade that seems...
Resting-state fMRI studies have shown that multiple functional networks, which consist of distribute...
<p>Interactions among organ systems are represented by weighted undirected graphs, where links refle...
The heart begins to beat before the brain is formed. Whether conventional hierarchical central comma...
<div><p>The heart begins to beat before the brain is formed. Whether conventional hierarchical centr...
<p>Brain areas are represented by Frontal (Fp1 and Fp2), Central (C3 and C4) and Occipital (O1 and O...