Information Decomposition in Multivariate Systems: Definitions, Implementation and Application to Cardiovascular Networks

Faes, Luca; Porta, Alberto; Nollo, Giandomenico; Javorka, Michal

doi:10.3390/e19010005

Cited by 67 publications

(104 citation statements)

References 63 publications

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“…The lower complexity during HUT is detected up to = 0.225 Hz using RMSE (Figure 3(b)) and up to = 0.1 Hz using LMSE (Figure 3(a)). At scale 1 ( = 0.5 Hz), these results confirm a number of previous investigations documenting the decreased complexity of heart rate variability during postural stress and its unaltered complexity during mental stress [36,[38][39][40]. Here we extend these findings showing that during MA the complexity of HP is left unchanged at any time scale and during HUT it is kept at lower levels until both the high-frequency (HF, >0.15 Hz) and the low-frequency (LF, ∼0.1 Hz) oscillations are removed by filtering.…”

Section: Resultssupporting

confidence: 79%

“…This result, which is again more evident using LMSE than RMSE, has been previously observed at scale 1 [36] and is possibly related to complex patterns of autonomic activation following cognitive load [41,42] 0.15 Hz). The emergence of a significantly higher complexity of SAP during HUT when HF fluctuations are filtered out is a novel finding, suggesting that the postural stress decreases the regularity of LF arterial pressure oscillations, while HF oscillations display similar or even increased regularity.…”

Section: Resultssupporting

confidence: 59%

“…The analyzed time series belong to a database collected to assess the dynamics of HP, SAP, and RESP during two types of physiological stress commonly studied in cardiovascular variability, that is, postural stress induced by head-up tilt (HUT) and mental stress induced by mental arithmetics (MA); we refer to [35,36] for a detailed description of the population and the experimental setup. Briefly, a group of 61 young healthy subjects (37 females, 17.5 ± 2.4 years old) were monitored in a relaxed state in the resting supine position (SU), in the upright position during HUT, and in the supine position during MA, measuring the surface electrocardiogram (ECG), the finger arterial blood pressure collected noninvasively by the photoplethysmographic method, and the respiration signal measured through respiratory inductive plethysmography.…”

Section: Experimental Protocol and Data Analysismentioning

confidence: 99%

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Efficient Computation of Multiscale Entropy over Short Biomedical Time Series Based on Linear State-Space Models

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The most common approach to assess the dynamical complexity of a time series across multiple temporal scales makes use of the multiscale entropy (MSE) and refined MSE (RMSE) measures. In spite of their popularity, MSE and RMSE lack an analytical framework allowing their calculation for known dynamic processes and cannot be reliably computed over short time series. To overcome these limitations, we propose a method to assess RMSE for autoregressive (AR) stochastic processes. The method makes use of linear state-space (SS) models to provide the multiscale parametric representation of an AR process observed at different time scales and exploits the SS parameters to quantify analytically the complexity of the process. The resulting linear MSE (LMSE) measure is first tested in simulations, both theoretically to relate the multiscale complexity of AR processes to their dynamical properties and over short process realizations to assess its computational reliability in comparison with RMSE. Then, it is applied to the time series of heart period, arterial pressure, and respiration measured for healthy subjects monitored in resting conditions and during physiological stress. This application to short-term cardiovascular variability documents that LMSE can describe better than RMSE the activity of physiological mechanisms producing biological oscillations at different temporal scales.

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Section: Resultssupporting

confidence: 79%

Section: Resultssupporting

confidence: 59%

Section: Experimental Protocol and Data Analysismentioning

confidence: 99%

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Efficient Computation of Multiscale Entropy over Short Biomedical Time Series Based on Linear State-Space Models

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“…These elements essentially reflect the new information produced at each moment in time about a target system in the network [2], the information stored in the target system [3,4], the information transferred to it from the other connected systems [5,6] and the modification of the information flowing from multiple source systems to the target [7,8]. The measures of information dynamics have gained more and more importance in both theoretical and applicative studies in several fields of science [9][10][11][12][13][14][15][16][17][18]. While the information-theoretic approaches to the definition and quantification of new information, information storage and information transfer are well understood and widely accepted, the problem of defining, interpreting and using measures of information modification has not been fully addressed in the literature.…”

Section: Introductionmentioning

confidence: 99%

Multiscale Information Decomposition: Exact Computation for Multivariate Gaussian Processes

Faes

Marinazzo

Stramaglia

2017

Entropy

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111

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Exploiting the theory of state space models, we derive the exact expressions of the information transfer, as well as redundant and synergistic transfer, for coupled Gaussian processes observed at multiple temporal scales. All of the terms, constituting the frameworks known as interaction information decomposition and partial information decomposition, can thus be analytically obtained for different time scales from the parameters of the VAR model that fits the processes. We report the application of the proposed methodology firstly to benchmark Gaussian systems, showing that this class of systems may generate patterns of information decomposition characterized by prevalently redundant or synergistic information transfer persisting across multiple time scales or even by the alternating prevalence of redundant and synergistic source interaction depending on the time scale. Then, we apply our method to an important topic in neuroscience, i.e., the detection of causal interactions in human epilepsy networks, for which we show the relevance of partial information decomposition to the detection of multiscale information transfer spreading from the seizure onset zone.

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“…In the context of dynamical systems obeying Gaussian noise processes the formalism has been further extended by Barrett [55]. We note here that the measure of interaction information is the negative of the measure of net synergy [56]. Considering the interactions between two parallel MAPK pathway, we identify signal integration and signal bifurcation motif.…”

Section: Introductionmentioning

confidence: 99%

Information Theoretical Study of Cross-Talk Mediated Signal Transduction in MAPK Pathways

Maity

Chaudhury

Banik

2017

Entropy

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Abstract:Biochemical networks having similar functional pathways are often correlated due to cross-talk among the homologous proteins in the different networks. Using a stochastic framework, we address the functional significance of the cross-talk between two pathways. A theoretical analysis on generic MAPK pathways reveals cross-talk is responsible for developing coordinated fluctuations between the pathways. The extent of correlation evaluated in terms of the information theoretic measure provides directionality to net information propagation. Stochastic time series suggest that the cross-talk generates synchronisation in a cell. In addition, the cross-interaction develops correlation between two different phosphorylated kinases expressed in each of the cells in a population of genetically identical cells. Depending on the number of inputs and outputs, we identify signal integration and signal bifurcation motif that arise due to inter-pathway connectivity in the composite network. Analysis using partial information decomposition, an extended formalism of multivariate information calculation, also quantifies the net synergy in the information propagation through the branched pathways. Under this formalism, signature of synergy or redundancy is observed due to the architectural difference in the branched pathways.

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Information Decomposition in Multivariate Systems: Definitions, Implementation and Application to Cardiovascular Networks

Cited by 67 publications

References 63 publications

Efficient Computation of Multiscale Entropy over Short Biomedical Time Series Based on Linear State-Space Models

Efficient Computation of Multiscale Entropy over Short Biomedical Time Series Based on Linear State-Space Models

Multiscale Information Decomposition: Exact Computation for Multivariate Gaussian Processes

Information Theoretical Study of Cross-Talk Mediated Signal Transduction in MAPK Pathways

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