Your search keyword '"Luca Faes"' showing total 7 results

1. Univariate and multivariate conditional entropy measures for the characterization of short-term cardiovascular complexity under physiological stress

Author

Alberto Porta, Martina Valente, Vlasta Bari, Michal Javorka, Barbora Czippelova, Jana Krohova, Luca Faes, Giandomenico Nollo, Zuzana Turianikova, Valente, M., Javorka, M., Porta, A., Bari, V., Krohova, J., Czippelova, B., Turianikova, Z., Nollo, G., and Faes, L.

Subjects

Male, Multivariate statistics, Adolescent, Physiology, Entropy, Biomedical Engineering, Biophysics, Diastole, Blood Pressure, 030204 cardiovascular system & hematology, network physiology, Cardiovascular Physiological Phenomena, Entropy estimation, 03 medical and health sciences, 0302 clinical medicine, head-up tilt, Heart Rate, Stress, Physiological, Physiology (medical), Statistics, Humans, Vagal tone, Mathematics, Conditional entropy, mental stre, Resting state fMRI, Respiration, Models, Cardiovascular, Univariate, Blood pressure, Biophysic, Settore ING-INF/06 - Bioingegneria Elettronica E Informatica, Multivariate Analysis, Female, cardiovascular variability, complexity, 030217 neurology & neurosurgery

Abstract

Objective: A defining feature of physiological systems under the neuroautonomic regulation is their dynamical complexity. The most common approach to assess physiological complexity from short-term recordings, i.e. to compute the rate of entropy generation of an individual system by means of measures of conditional entropy (CE), does not consider that complexity may change when the investigated system is part of a network of physiological interactions. This study aims at extending the concept of short-term complexity towards the perspective of network physiology, defining multivariate CE measures whereby multiple physiological processes are accounted for in the computation of entropy rates. Approach: Univariate and multivariate CE measures are computed using state-of-the-art methods for entropy estimation and applied to the time series of heart period (H), systolic (S) and diastolic (D) arterial pressure, and respiration (R) variability measured in healthy subjects monitored in a resting state and during conditions of postural and mental stress. Main results: Compared with the traditional univariate metric of short-term complexity, multivariate measures provide additional information with plausible physiological interpretation, such as: (i) the dampening of respiratory sinus arrhythmia and activation of the baroreflex control during postural stress; (ii) the increased complexity of heart period and blood pressure variability during mental stress, reflecting the effect of respiratory influences and upper cortical centers; (iii) the strong influence of D on S, mediated by left ventricular ejection fraction and vascular properties; (iv) the role of H in reducing the complexity of D, related to cardiac run-off effects; and (v) the unidirectional role of R in influencing cardiovascular variability. Significance: Our results document the importance of employing a network perspective in the evaluation of the short-term complexity of cardiovascular and respiratory dynamics across different physiological states.

Published

2018

2. A stochastic approach for automatic registration and fusion of left atrial electroanatomic maps with 3D CT anatomical images.

Author

Alessandro Cristoforetti, Michela Mas, Luca Faes, Maurizio Centonze, Maurizio Del, Renzo Antolini, Giandomenico Nollo, and Flavia Ravelli

Subjects

STOCHASTIC processes, NUMERICAL analysis, ARRHYTHMIA, HEART beat

Abstract

The integration of electroanatomic maps with highly resolved computed tomography cardiac images plays an important role in the successful planning of the ablation procedure of arrhythmias. In this paper, we present and validate a fully-automated strategy for the registration and fusion of sparse, atrial endocardial electroanatomic maps (CARTO maps) with detailed left atrial (LA) anatomical reconstructions segmented from a pre-procedural MDCT scan. Registration is accomplished by a parameterized geometric transformation of the CARTO points and by a stochastic search of the best parameter set which minimizes the misalignment between transformed CARTO points and the LA surface. The subsequent fusion of electrophysiological information on the registered CT atrium is obtained through radial basis function interpolation. The algorithm is validated by simulation and by real data from 14 patients referred to CT imaging prior to the ablation procedure. Results are presented, which show the validity of the algorithmic scheme as well as the accuracy and reproducibility of the integration process. The obtained results encourage the application of the integration method in post-intervention ablation assessment and basic AF research and suggest the development for real-time applications in catheter guiding during ablation intervention. [ABSTRACT FROM AUTHOR]

Published

2007

3. Time, frequency and information domain analysis of short-term heart rate variability before and after focal and generalized seizures in epileptic children.

Author

Riccardo Pernice, Luca Faes, Ivan Kotiuchyi, Salvatore Stivala, Alessandro Busacca, Anton Popov, and Volodymyr Kharytonov

Subjects

*CHILDREN with epilepsy, *HEART beat, *FREQUENCY-domain analysis, *EPILEPSY, *PARTIAL epilepsy

Abstract

Objective: In this work we explore the potential of combining standard time and frequency domain indexes with novel information measures, to characterize pre- and post-ictal heart rate variability (HRV) in epileptic children, with the aim of differentiating focal and generalized epilepsy regarding the autonomic control mechanisms. Approach: We analyze short-term HRV in 37 children suffering from generalized or focal epilepsy, monitored 10 s, 300 s, 600 s and 1800 s both before and after seizure episodes. Nine indexes are computed in time (mean, standard deviation of normal-to-normal intervals, root mean square of the successive differences (RMSSD)), frequency (low-to-high frequency power ratio LF/HF, normalized LF and HF power) and information (entropy, conditional entropy and self-entropy) domains. Focal and generalized epilepsy are compared through statistical analysis of the indexes and using linear discriminant analysis (LDA). Main results: In children with focal epilepsy, early post-ictal phase is characterized by significant tachycardia, depressed HRV, increased LF power and LF/HF, and decreased complexity, progressively recovered across time windows after the episodes. Children with generalized seizures instead show significant tachycardia, lower RMSSD, higher LF power and LF/HF ratio before the seizure. These different behaviors are exploited by LDA analysis to separate focal and generalized epilepsy up to an accuracy of 75%. Results suggest a shift of the sympatho-vagal balance towards sympathetic dominance and vagal withdrawal, noticeable just after the termination of seizure episodes and then reverted in focal epilepsy, and persistent during inter-ictal and pre-ictal periods in generalized epilepsy. Significance: Our analysis helps in elucidating the pathophysiology of inter-ictal HRV autonomic control and the differential diagnosis of generalized and focal epilepsy. These findings may have clinical relevance since altered sympatho-vagal control can be related to a higher danger of morbidity and mortality, may reduce thresholds for life-threatening arrhythmias, and could be a biomarker of risk for sudden unexpected death in epilepsy. [ABSTRACT FROM AUTHOR]

Published

2019

4. Cerebrovascular and cardiovascular variability interactions investigated through conditional joint transfer entropy in subjects prone to postural syncope.

Author

Vlasta Bari, Beatrice De Maria, Claudio Enrico Mazzucco, Gianluca Rossato, Davide Tonon, Giandomenico Nollo, Luca Faes, and Alberto Porta

Subjects

CARDIOVASCULAR system physiology, CEREBRAL circulation, ELECTROCARDIOGRAPHS, SYSTOLIC blood pressure, PLETHYSMOGRAPHY

Abstract

Objective: A model-based conditional transfer entropy approach was exploited to quantify the information transfer in cerebrovascular (CBV) and cardiovascular (CV) systems in subjects prone to develop postural syncope. Approach: Spontaneous beat-to-beat variations of mean cerebral blood flow velocity (MCBFV) derived from a transcranial Doppler device, heart period (HP) derived from surface electrocardiogram, mean arterial pressure (MAP) and systolic arterial pressure (SAP) derived from finger plethysmographic arterial pressure device were monitored at rest in supine position (REST) and during 60° head-up tilt (TILT) in 13 individuals (age mean  ±  standard deviation: 28  ±  9 years, min–max range: 18–44 years, 5 males) with a history of recurrent episodes of syncope (SYNC) and in 13 age- and gender-matched controls (NonSYNC). Respiration (R) obtained from a thoracic belt was acquired as well and considered as a conditioning signal in transfer entropy assessment. Synchronous sequences of 250 consecutive MCBFV, HP, MAP, SAP and R values were utilized to estimate the information genuinely transferred from MAP to MCBFV (i.e. disambiguated from R influences) and vice versa. Analogous indexes were computed from SAP to HP and vice versa. Traditional time and frequency domain analyses were carried out as well. Main results: SYNC subjects showed an increased genuine information transfer from MAP to MCBFV during TILT, while they did not exhibit the expected rise of the genuine information transfer from SAP to HP. Significance: We conclude that SYNC individuals featured an impaired cerebral autoregulation visible during TILT and were unable to activate cardiac baroreflex to cope with the postural challenge. Traditional frequency domain markers based on transfer function modulus, phase and coherence functions were less powerful or less specific in typifying the CBV and CV controls of SYNC individuals. Conditional transfer entropy approach can identify the impairment of CBV and CV controls and provide specific clues to identify subjects prone to develop postural syncope. [ABSTRACT FROM AUTHOR]

Published

2017

5. Basic cardiovascular variability signals: mutual directed interactions explored in the information domain.

Author

Michal Javorka, Jana Krohova, Barbora Czippelova, Zuzana Turianikova, Zuzana Lazarova, Kamil Javorka, and Luca Faes

Subjects

CARDIOVASCULAR system physiology, DIASTOLE (Cardiac cycle), SYSTOLIC blood pressure, ELECTROCARDIOGRAPHY, MENTAL arithmetic, BIVARIATE analysis

Abstract

The study of short-term cardiovascular interactions is classically performed through the bivariate analysis of the interactions between the beat-to-beat variability of heart period (RR interval from the ECG) and systolic blood pressure (SBP). Recent progress in the development of multivariate time series analysis methods is making it possible to explore how directed interactions between two signals change in the context of networks including other coupled signals. Exploiting these advances, the present study aims at assessing directional cardiovascular interactions among the basic variability signals of RR, SBP and diastolic blood pressure (DBP), using an approach which allows direct comparison between bivariate and multivariate coupling measures. To this end, we compute information-theoretic measures of the strength and delay of causal interactions between RR, SBP and DBP using both bivariate and trivariate (conditioned) formulations in a group of healthy subjects in a resting state and during stress conditions induced by head-up tilt (HUT) and mental arithmetics (MA). We find that bivariate measures better quantify the overall (direct  +  indirect) information transferred between variables, while trivariate measures better reflect the existence and delay of directed interactions. The main physiological results are: (i) the detection during supine rest of strong interactions along the pathway RR  →  DBP  →  SBP, reflecting marked Windkessel and/or Frank–Starling effects; (ii) the finding of relatively weak baroreflex effects SBP  →  RR at rest; (iii) the invariance of cardiovascular interactions during MA, and the emergence of stronger and faster SBP  →  RR interactions, as well as of weaker RR  →  DBP interactions, during HUT. These findings support the importance of investigating cardiovascular interactions from a network perspective, and suggest the usefulness of directed information measures to assess physiological mechanisms and track their changes across different physiological states. [ABSTRACT FROM AUTHOR]

Published

2017

6. Interictal cardiorespiratory variability in temporal lobe and absence epilepsy in childhood.

Author

Carolina Varon, Alessandro Montalto, Katrien Jansen, Lieven Lagae, Daniele Marinazzo, Luca Faes, and Sabine Van Huffel

Subjects

TEMPORAL lobe epilepsy, CARDIOPULMONARY system physiology, AUTONOMIC nervous system, SEIZURES in children, HEART beat, RESPIRATION, SYMPATHETIC nervous system physiology

Abstract

It is well known that epilepsy has a profound effect on the autonomic nervous system, especially on the autonomic control of heart rate and respiration. This effect has been widely studied during seizure activity, but less attention has been given to interictal (i.e. seizure-free) activity. The studies that have been done on this topic, showed that heart rate and respiration can be affected individually, even without the occurrence of seizures. In this work, the interactions between these two individual physiological variables are analysed during interictal activity in temporal lobe and absence epilepsy in childhood. These interactions are assessed by decomposing the predictive information about heart rate variability, into different components like the transfer entropy, cross-entropy, self- entropy and the conditional self entropy. Each one of these components quantifies different types of shared information. However, when using the cross-entropy and the conditional self entropy, it is possible to split the information carried by the heart rate, into two main components, one related to respiration and one related to different mechanisms, like sympathetic activation. This can be done after assuming a directional link going from respiration to heart rate. After analysing all the entropy components, it is shown that in subjects with absence epilepsy the information shared by respiration and heart rate is significantly lower than for normal subjects. And a more remarkable finding indicates that this type of epilepsy seems to have a long term effect on the cardiac and respiratory control mechanisms of the autonomic nervous system. [ABSTRACT FROM AUTHOR]

Published

2015

7. Bridging the gap between the development of advanced biomedical signal processing tools and clinical practice.

Author

Alberto Porta, Giandomenico Nollo, and Luca Faes

Subjects

CARDIOVASCULAR system, BIOMEDICAL signal processing, CONFERENCES & conventions

Abstract

An introduction is presented in which the editor discusses various articles within the issue on topics including use of cardiovascular variability to detect toxic effect of chemotherapeutic agent, the European Study Group on Cardiovascular Oscillations' meeting and biomedical signals processing.

Published

2015