Estimation of Serum Potassium and Calcium Concentrations from Electrocardiographic Depolarization and Repolarization Waveforms

Chronic kidney disease (CKD), a condition defined by a gradual decline in kidney function over time, has become a global health concern affecting between 11 and 13% of the world population [1]. As renal function declines, CKD patients gradually lose their ability to maintain normal values of potassium concentration ([K+]) in their blood. Elevated serum [K+], known as hyperkalemia, increases the risk for life-threatening arrhythmias and sudden cardiac death [2].An increase in serum [K+] outside the physiological range is commonly silent and is only detected when hyperkalemia is already very severe or when a blood test is performed. Maintenance and monitoring of [K+] in the blood is an important component in the treatment of CKD patients because therapies for hyperkalemia management in CKD patients are designed to prevent arrhythmias and to immediately lower serum [K+] to safe ranges. However, this is currently only possible by taking a blood sample and is associated with a long analysis time. Therefore it is useful to have a simple, noninvasive method to estimate serum [K+], particularly using the electrocardiogram (ECG). Indeed, variations in serum electrolyte levels have been shown to alter the electrical behavior of the heart and to induce changes in the ECG [3¿6]. However, large inter-individual variability existsin the relationship between ion concentrations and ECG features. Previous attempts to estimate serum [K+] from the ECG have therefore shown limitations [7¿9], such as not being applicable to some common types of ECG waveforms or relying on specific ECG characteristics that may present large variations not necessarily associated with hyperkalemia.The aim of this thesis is to develop novel estimates of serum [K+] that are robust enough to detect hypokalemia (reduced [K+]) or hyperkalemia in a timely manner to provide life-saving treatment. Additionally, the effect of changes in other electrolyte levels, like calcium concentration ([Ca2+]), and in heart rate are investigated. These aims are achieved by combining novel ECG signal processing techniques with in silico modeling and simulation of cardiac electrophysiology.The specific objectives are:1. Characterization of hypokalemia or hyperkalemia and hypocalcemia (reduced [Ca2+]) or hypercalcemia (elevated [Ca2+])-induced changes in ventricular repolarization from ECGs (T wave) of CKD patients. This is addressed in chapter 3 and chapter 4. In these chapters, we describe how T waves are extracted from ECGs and how we characterize changes in T waves at varying potassium, calcium and heart rate using analyses based on time warping and Lyapunov exponents. Next, univariable and multivariable regression models including markers of T wave nonlinear dynamics in combination with warping-based markers of T wave morphology are built and their performance for [K+] estimation is assessed.2. Characterization of hypo- or hyperkalemia and hypo- or hypercalcemia-induced changes in ventricular depolarization from the QRS complex of CKD patients. This is reported in chapter 5. In this chapter, we present how QRS complexes from ECGs of CKD patients are processed and how we measure changes at varying [K+], [Ca2+] and heart rate. Univariate and multivariate regression analyses including novel QRS morphological markers in combination with T wave morphological markers are performed to assess the contribution of depolarization and repolarization features for electrolyte monitoring in CKD patients.3. Identification of potential sources underlying inter-individual variability in ECG markers in response to changes in [K+] and [Ca2+]. In silico investigations of cardiac electrophysiology are conducted and ECG features are computed. Simulation results are compared with patient data. This is explained in chapter 3 using one-dimensional (1D) fibers and in chapter 6 using three-dimensional (3D) human heart-torso models. Chapter 6 includes the development of a population of realistic computational models of human ventricular electrophysiology, based on human anatomy and electrophysiology, to better understand how changes in individual characteristics influence the ECG (QRS and T wave) markers that we introduced in previous chapters. ECG waveforms are characterized by their amplitude, duration and morphology. Simulations are performed with the most realistic available techniques to model the electrophysiology of the heart and the resulting ECG. We establish mechanisms that contribute to inter-individual differences in the characterized ECG features.In conclusion, we identify several markers of ECG morphology, including depolarization and repolarization features, that are highly correlated with serum electrolyte (potassium and calcium) concentrations. ECG morphological variability markers vary significantly with [K+] and [Ca2+] in both simulated and measured ECGs, with a wide range of patterns observed for such relationships. The proportions of endocardial, midmyocardial and epicardial cells have a large impact on ECG markers, particularly for serum electrolyte concentrations out of their physiological levels. This suggests that transmural heterogeneities can modulate ECG responses to changes in electrolyte concentrations in CKD patients. Agreement between actual potassium and calcium levels and their estimates derived from the ECG is promising, with lower average errors than previously proposed markers in the literature. These findings can have major relevance for noninvasive monitoring of serum electrolyte levels and prediction of arrhythmic events in these patients.<br /

Serum potassium concentration monitoring by ECG time warping analysis on the T wave

This doctoral thesis was developed within the joint Ph.D. program in biomedical engineering at Universitat Politècnica de Catalunya (Barcelona, Spain) and University of Zaragoza (Zaragoza, Spain) in the framework of Doctorats Industrials program co-financed by Laboratorios Rubió S.A. (Castellbisbal, Spain) and Agència de Gestió d’Ajuts Universitaris i de Recerca, Generalitat de Catalunya (Spain). This thesis was performed in partnership with the Nephrology ward from Hospital Clínico Universitario Lozano Blesa (Zaragoza, Spain) and in collaboration with Dr J. Ramírez from the William Harvey Research Institute, Queen Mary University of London (London, UK).End-stage renal disease (ESRD) patients demonstrate an increased incidence of sudden cardiac death (SCD) with declining kidney functioning as a consequence of blood potassium ([K+]) homeostasis impairment, which is restored by hemodialysis (HD) therapy. The clinically established method for the diagnosis of [K+] imbalance is blood tests, an invasive and costly procedure that limits continuous monitoring of ESRD patients. A non-invasive ambulatory index, able to quantify changes in [K+] level is an open issue. In this context, the electrocardiogram (ECG) and in particular, the T wave (TW) morphology, has been shown to be strongly correlated with [K+] imbalance. Therefore, the aim of this dissertation is to investigate and to propose TW-derived markers able to monitor changes in [K+] levels in ESRD patients undergoing HD. For that purpose, the time warping analysis, a technique that allows the comparison and quantification of differences between two different TW shapes, was investigated. The application of TW time warping based markers in monitoring [K+ ] variations (Δ [K+]) and the derivation of a heart-rate corrected marker is proposed and compared with respect to two well-established Δ [K+]-related TW-based indexes. All the markers are evaluated in a single lead approach and after having emphasised the TW energy content through spatial transformation by Principal Component Analysis (PCA). Results demonstrate that the proposed biomarkers outperform the already proposed indexes, also proving that the use of PCA transformed lead generates markers with a higher correlation with Δ [K+] than the single lead approach. The possibility to improve markers robustness in the case of low signal-to-noise ratio ECGs, by spatially transforming the signal maximising the beat-to-beat TW periodicity criteria through the so-called Periodic Component Analysis (pCA), is then explored. pCA-based markers show superior performance during and after the HD than those obtained by PCA suggesting improved stability for continuous Δ [K+] tracking. The thesis studies also the application of regressions models to quantify Δ [K+] from pCA-based time warping markers. The accuracy of the regression models is evaluated by correlation and estimation error between the actual and the corresponding model-estimated Δ [K+] values, and the smallest estimation error is found for quadratic regression models. Being the time warping derived markers sensitive to TW boundary delineation errors, which may endanger their prognostic power, the advantages of using a weighting stage is investigated for their robust computation. The performance of two weighting functions (WF)s is tested and compared with respect to the control no weighting case, in simulated scenarios and in real scenarios (i.e. for [K+] monitoring and SCD risk stratification). No improvements in [K+] monitoring are found, probably due to the considerable marked [K+]-induced TW morphological changes. On the contrary, both simulation tests and SCD risk stratification analysis show that the proposed WFs can enhance the robustness of TW time warping analysis against TW delineation errors. In conclusion, this Doctoral Thesis confirms the hypothesis that enhanced perforce in Δ [K+] tracking and quantification can be achieved by analysing the overall TW morphology by time warping analysis. The simplicity of the technology, together with its low cost and ease of acquisition, should provide a new opportunity for TW analysis to reach standard clinical practice. Moreover, the use of WFs to minimise the undesired effects of TW delineation errors on the computation of time warping markers revealed a noticeable improvement of the SCD risk stratification power of time warping derived indexes.Los pacientes con enfermedad renal en etapa terminal (ESRD) demuestran una mayor incidencia de muerte cardíaca súbita (SCD) tras el deterioro del funcionamiento renal como consecuencia del desequilibrio del potasio ([K+]) en sangre. Este último se restablece mediante la terapia de hemodiálisis (HD). El desequilibrio de [K+] se diagnostica a través del análisis de sangre, un procedimiento invasivo y costoso que limita la monitorización de los pacientes con ESRD. Se necesita un índice ambulatorio no invasivo, capaz de cuantificar los cambios en el nivel de [K+] (Δ [K+]). En este contexto, se ha demostrado que el electrocardiograma (ECG) y en particular la onda T (TW), están correlacionados con Δ [K+]. El objetivo de esta tesis es evaluar marcadores derivados de la TW capaces de monitorizar ¿[K+] en pacientes con ESRD sometidos a HD. Para ello, se aplicó el análisis time warping, una técnica que permite la comparación de dos formas diferentes de TW. En primer lugar, se evalúa la aplicación de marcadores basados en el time warping para el seguimiento de Δ [K+] así como la derivación de un marcador corregido por la frecuencia cardíaca, comparando los marcadores con respecto a dos índices basados en TW bien establecidos y relacionados con Δ [K+]. Todos los marcadores se evalúan en las derivaciones independientes y después de haber enfatizado el contenido de energía de TW a través del Análisis de Componentes Principales (PCA). Los resultados demuestran mejores prestaciones de los marcadores time warping respecto a los ya propuestos y que el uso de PCA genera marcadores con una correlación más alta con Δ [K+] respecto a las derivaciones independientes. A continuación, se explora la posibilidad de mejorar la robustez de los marcadores en el caso de ECG con una relación señal/ruido baja, maximizando la periodicidad de TW latido a latido mediante el Análisisde Componentes Periódicos (pCA). Los marcadores basados en pCA muestran un rendimiento superior durante y después de la HD que los obtenidos por PCA, lo que sugiere una estabilidad mejorada para el seguimiento continuo de Δ [K+]. Luego, se evalúan modelos de regresión para cuantificar [K+] a partir de marcadores basados en pCA. La precisión de los modelos de regresión se evalúa mediante el error de estimación entre valores reales de Δ [K+] y los correspondientes estimados por el modelo. Con el error de estimación más pequeño, el modelo cuadrático es el más adecuado para la cuantificación de [K+].Siendo el análisis time warping sensible a los errores de delineación de los límites de TW, lo que supone un riesgo para su poder pronóstico, se investigan las ventajas de usar una etapa de ponderación para el cálculo de marcadores time warping. El rendimiento de dos funciones de ponderación (WF) se prueba y se compara con respecto al caso de control sin ponderación, en escenarios simulados y en escenarios reales (para el seguimiento de [K+] y la estratificación del riesgo de SCD). No se encontraron mejoras en la monitorización de [K+] debido a los considerables cambios morfológicos de TW inducidos por Δ [K+]. Por otro lado, tanto las pruebas de simulación como el análisis de estratificación de riesgo de SCD muestran que los WF propuestos pueden mejorar la robustez del análisis time warping de TW contra los errores dedelineación de TW. En conclusión, esta tesis doctoral confirma la hipótesis de que se puede lograr un mejor seguimiento y cuantificación de Δ [K+] mediante el análisis de la morfología de TW mediante el análisis time warping. La simplicidad de la tecnología, junto con su bajo costo y facilidad de adquisición del ECG, debería brindar una nueva oportunidad para que el análisis de TW en la práctica clínica rutinaria. Además, el uso de WF para minimizar los efectos no deseados de errores de delineación de TW en el cálculo de los marcadores time warping reveló una mejora del poder de estratificación del riesgoEnginyeria biomèdic

Serum potassium concentration monitoring by ECG time warping analysis on the T wave

This doctoral thesis was developed within the joint Ph.D. program in biomedical engineering at Universitat Politècnica de Catalunya (Barcelona, Spain) and University of Zaragoza (Zaragoza, Spain) in the framework of Doctorats Industrials program co-financed by Laboratorios Rubió S.A. (Castellbisbal, Spain) and Agència de Gestió d’Ajuts Universitaris i de Recerca, Generalitat de Catalunya (Spain). This thesis was performed in partnership with the Nephrology ward from Hospital Clínico Universitario Lozano Blesa (Zaragoza, Spain) and in collaboration with Dr J. Ramírez from the William Harvey Research Institute, Queen Mary University of London (London, UK).End-stage renal disease (ESRD) patients demonstrate an increased incidence of sudden cardiac death (SCD) with declining kidney functioning as a consequence of blood potassium ([K+]) homeostasis impairment, which is restored by hemodialysis (HD) therapy. The clinically established method for the diagnosis of [K+] imbalance is blood tests, an invasive and costly procedure that limits continuous monitoring of ESRD patients. A non-invasive ambulatory index, able to quantify changes in [K+] level is an open issue. In this context, the electrocardiogram (ECG) and in particular, the T wave (TW) morphology, has been shown to be strongly correlated with [K+] imbalance. Therefore, the aim of this dissertation is to investigate and to propose TW-derived markers able to monitor changes in [K+] levels in ESRD patients undergoing HD. For that purpose, the time warping analysis, a technique that allows the comparison and quantification of differences between two different TW shapes, was investigated. The application of TW time warping based markers in monitoring [K+ ] variations (Δ [K+]) and the derivation of a heart-rate corrected marker is proposed and compared with respect to two well-established Δ [K+]-related TW-based indexes. All the markers are evaluated in a single lead approach and after having emphasised the TW energy content through spatial transformation by Principal Component Analysis (PCA). Results demonstrate that the proposed biomarkers outperform the already proposed indexes, also proving that the use of PCA transformed lead generates markers with a higher correlation with Δ [K+] than the single lead approach. The possibility to improve markers robustness in the case of low signal-to-noise ratio ECGs, by spatially transforming the signal maximising the beat-to-beat TW periodicity criteria through the so-called Periodic Component Analysis (pCA), is then explored. pCA-based markers show superior performance during and after the HD than those obtained by PCA suggesting improved stability for continuous Δ [K+] tracking. The thesis studies also the application of regressions models to quantify Δ [K+] from pCA-based time warping markers. The accuracy of the regression models is evaluated by correlation and estimation error between the actual and the corresponding model-estimated Δ [K+] values, and the smallest estimation error is found for quadratic regression models. Being the time warping derived markers sensitive to TW boundary delineation errors, which may endanger their prognostic power, the advantages of using a weighting stage is investigated for their robust computation. The performance of two weighting functions (WF)s is tested and compared with respect to the control no weighting case, in simulated scenarios and in real scenarios (i.e. for [K+] monitoring and SCD risk stratification). No improvements in [K+] monitoring are found, probably due to the considerable marked [K+]-induced TW morphological changes. On the contrary, both simulation tests and SCD risk stratification analysis show that the proposed WFs can enhance the robustness of TW time warping analysis against TW delineation errors. In conclusion, this Doctoral Thesis confirms the hypothesis that enhanced perforce in Δ [K+] tracking and quantification can be achieved by analysing the overall TW morphology by time warping analysis. The simplicity of the technology, together with its low cost and ease of acquisition, should provide a new opportunity for TW analysis to reach standard clinical practice. Moreover, the use of WFs to minimise the undesired effects of TW delineation errors on the computation of time warping markers revealed a noticeable improvement of the SCD risk stratification power of time warping derived indexes.Los pacientes con enfermedad renal en etapa terminal (ESRD) demuestran una mayor incidencia de muerte cardíaca súbita (SCD) tras el deterioro del funcionamiento renal como consecuencia del desequilibrio del potasio ([K+]) en sangre. Este último se restablece mediante la terapia de hemodiálisis (HD). El desequilibrio de [K+] se diagnostica a través del análisis de sangre, un procedimiento invasivo y costoso que limita la monitorización de los pacientes con ESRD. Se necesita un índice ambulatorio no invasivo, capaz de cuantificar los cambios en el nivel de [K+] (Δ [K+]). En este contexto, se ha demostrado que el electrocardiograma (ECG) y en particular la onda T (TW), están correlacionados con Δ [K+]. El objetivo de esta tesis es evaluar marcadores derivados de la TW capaces de monitorizar ¿[K+] en pacientes con ESRD sometidos a HD. Para ello, se aplicó el análisis time warping, una técnica que permite la comparación de dos formas diferentes de TW. En primer lugar, se evalúa la aplicación de marcadores basados en el time warping para el seguimiento de Δ [K+] así como la derivación de un marcador corregido por la frecuencia cardíaca, comparando los marcadores con respecto a dos índices basados en TW bien establecidos y relacionados con Δ [K+]. Todos los marcadores se evalúan en las derivaciones independientes y después de haber enfatizado el contenido de energía de TW a través del Análisis de Componentes Principales (PCA). Los resultados demuestran mejores prestaciones de los marcadores time warping respecto a los ya propuestos y que el uso de PCA genera marcadores con una correlación más alta con Δ [K+] respecto a las derivaciones independientes. A continuación, se explora la posibilidad de mejorar la robustez de los marcadores en el caso de ECG con una relación señal/ruido baja, maximizando la periodicidad de TW latido a latido mediante el Análisisde Componentes Periódicos (pCA). Los marcadores basados en pCA muestran un rendimiento superior durante y después de la HD que los obtenidos por PCA, lo que sugiere una estabilidad mejorada para el seguimiento continuo de Δ [K+]. Luego, se evalúan modelos de regresión para cuantificar [K+] a partir de marcadores basados en pCA. La precisión de los modelos de regresión se evalúa mediante el error de estimación entre valores reales de Δ [K+] y los correspondientes estimados por el modelo. Con el error de estimación más pequeño, el modelo cuadrático es el más adecuado para la cuantificación de [K+].Siendo el análisis time warping sensible a los errores de delineación de los límites de TW, lo que supone un riesgo para su poder pronóstico, se investigan las ventajas de usar una etapa de ponderación para el cálculo de marcadores time warping. El rendimiento de dos funciones de ponderación (WF) se prueba y se compara con respecto al caso de control sin ponderación, en escenarios simulados y en escenarios reales (para el seguimiento de [K+] y la estratificación del riesgo de SCD). No se encontraron mejoras en la monitorización de [K+] debido a los considerables cambios morfológicos de TW inducidos por Δ [K+]. Por otro lado, tanto las pruebas de simulación como el análisis de estratificación de riesgo de SCD muestran que los WF propuestos pueden mejorar la robustez del análisis time warping de TW contra los errores dedelineación de TW. En conclusión, esta tesis doctoral confirma la hipótesis de que se puede lograr un mejor seguimiento y cuantificación de Δ [K+] mediante el análisis de la morfología de TW mediante el análisis time warping. La simplicidad de la tecnología, junto con su bajo costo y facilidad de adquisición del ECG, debería brindar una nueva oportunidad para que el análisis de TW en la práctica clínica rutinaria. Además, el uso de WF para minimizar los efectos no deseados de errores de delineación de TW en el cálculo de los marcadores time warping reveló una mejora del poder de estratificación del riesgoPostprint (published version

Robust Algorithms for Unattended Monitoring of Cardiovascular Health

Cardiovascular disease is the leading cause of death in the United States. Tracking daily changes in one’s cardiovascular health can be critical in diagnosing and managing cardiovascular disease, such as heart failure and hypertension. A toilet seat is the ideal device for monitoring parameters relating to a subject’s cardiac health in his or her home, because it is used consistently and requires no change in daily habit. The present work demonstrates the ability to accurately capture clinically relevant ECG metrics, pulse transit time based blood pressures, and other parameters across subjects and physiological states using a toilet seat-based cardiovascular monitoring system, enabled through advanced signal processing algorithms and techniques. The algorithms described herein have been designed for use with noisy physiologic signals measured at non-standard locations. A key component of these algorithms is the classification of signal quality, which allows automatic rejection of noisy segments before feature delineation and interval extractions. The present delineation algorithms have been designed to work on poor quality signals while maintaining the highest possible temporal resolution. When validated on standard databases, the custom QRS delineation algorithm has best-in-class sensitivity and precision, while the photoplethysmogram delineation algorithm has best-in-class temporal resolution. Human subject testing on normative and heart failure subjects is used to evaluate the efficacy of the proposed monitoring system and algorithms. Results show that the accuracy of the measured heart rate and blood pressure are well within the limits of AAMI standards. For the first time, a single device is capable of monitoring long-term trends in these parameters while facilitating daily measurements that are taken at rest, prior to the consumption of food and stimulants, and at consistent times each day. This system has the potential to revolutionize in-home cardiovascular monitoring

Alteraciones en la modulación respiratoria del vector cardíaco en pacientes con enfermedad de Chaga

Proyecto Integrador (I. Biom.)--FCEFN-UNC, 2014Hace hincapié a que pueden existir alteraciones eléctricas en el sistema de conducción del corazón y cambios de propagación y modulación del potencial de acción cardíaco (PAC) debido a la invasión miocardia del Trypanosoma Cruzi. Se analizan registros ECGAR y evalúan parámetros que podrían ayudar a la detección y diagnóstico temprano del chagas indeterminado. Mediante el algoritmo propuesto para ello, se encuentran diferencias significativas entre individuos sin la enfermedad e individuos asintomáticos sin alteraciones en test diagnósticos convencionales pero con serología positiv

Assessment of ventricular repolarization instability and cardiac risk stratification in different pathological and abnormal conditions

Cardiovascular diseases (CVDs) represents the leading cause of mortality worldwide [1,2]. These pathological conditions are mainly characterized by a structurally abnormal heart, that is, a vulnerable substrate, prone to the abnormal generation and/or propagation of the electrical impulse, determining the onset of ventricular arrhythmias, which can result in sudden cardiac death (SCD) [3]. In this context, the assessment of ventricular repolarization from the electrocardiogram (ECG) signal has been shown to provide with valuable information for risk stratification and several electrocardiographic indices have been proposed in the literature [4]. The main objective of this thesis is to propose methodological advances for the assessment of ventricular repolarization instability in pathological and abnormal conditions. These contributions are aimed at improving the prediction of ventricular arrhythmias and, consequently, better identifying SCD risk. In particular, we have addressed this objective by developing robust methodologies for the assessment of T-wave alternans (TWA) and ventricular repolarization instability, in invasive and non-invasive cardiac signals, that have been evaluated in both experimental and clinical conditions. In the first part of the thesis, TWA was simultaneously characterized (prevalence, magnitude, time-course, and alternans waveform) in body-surface ECG and intracardiac electrograms (EGMs) signals during coronary artery occlusion. Signals from both body surface ECG and intracardiac EGMs recorded from 4 different anatomical heart locations (coronary sinus, epicardial space and left and right ventricles) were analyzed following a multilead strategy. Leads were linearly combined using the periodic component analysis (πCA) [5], which maximizes the 2-beat periodicity (TWA periodicity) content present on the available leads. Then the Laplacian Likelihood Ratio method (LLRM) [6] was applied for TWA detection and estimation. A sensitivity study for TWA detection from the 5 different locations of leads was performed, revealing that it is the combination of the ECG leads that better performs. In addition, this multilead approach allowed us to find the optimal combination of intracardiac leads usable for in-vivo monitorization of TWA directly from an implantable device, with a sensitivity comparable to the ECG analysis. These results encourage further research to determine the feasibility of predicting imminent VT/VF episodes by TWA analysis implemented in implantable cardioverter defibrillator’s (ICD) technology.Then, we have studied the potential changes induced by a prolonged exposure to simulated microgravity on ventricular repolarization in structurally normal hearts. It is well known that this environmental condition affects the control of autonomic and cardiovascular systems [7], with a potential increase on cardiac electrical instability. The effects of short- (5 days), mid- (21 days) and long- (60 days) exposure to simulated microgravity on TWA using the head-down bed-rest (HDBR) model [8] were assessed. TWA was evaluated before (PRE), during and after (POST) the immobilization period, by the long-term averaging technique in ambulatory ECG Holter recordings [9]. Additionally, we proposed an adapted short-term averaging approach for shorter, non-stationary ECG signals obtained during two stress manoeuvres (head-up tilt-table and bicycle exercise tests). Both approaches are based on the multilead analysis used in the previous study. The absence of significant changes between PRE and POST-HDBR on TWA indices suggests that a long-term exposure to simulated microgravity is not enough to induce alterations in healthy myocardial substrate up to the point of reflecting electrical instability in terms of TWA on the ECG. Finally, methodological advances were proposed for the assessment of ventricular repolarization instability from the ECG signal in the presence of sporadic (ventricular premature contractions, VPCs) and sustained (atrial fibrillation) rhythm disturbances.On the one hand, a methodological improvement for the estimation of TWA amplitude in ambulatory ECG recordings was proposed, which deals with the possible phase reversal on the alternans sequence induced by the presence of VPCs [10]. The performance of the algorithm was first evaluated using synthetic signals. Then, the effect of the proposed method in the prognostic value of TWA amplitude was assessed in real ambulatory ECG recordings from patients with chronic heart failure (CHF). Finally, circadian TWA changes were evaluated as well as the prognostic value of TWA at different times of the day. A clinical study demonstrated the enhancement in the predictive value of the index of average alternans (IAA) [9] for SCD stratification. In addition, results suggested that alternans activity is modulated by the circadian pattern, preserving its prognostic information when computed just during the morning, which is also the day interval with the highest reported SCD incidence. Thus, suggesting that time of the day should be considered for SCD risk prediction. On the other hand, the high irregularity of the ventricular response in atrial fibrillation (AF) limits the use of the most common ECG-derived markers of repolarization heterogeneity, including TWA, under this clinical condition [11]. A new method for assessing ventricular repolarization changes based on a selective averaging technique was developed and new non-invasive indices of repolarization variation were proposed. The positive impact in the prognostic value of the computed indices was demonstrated in a clinical study, by analyzing ECG Holter recordings from CHF patients with AF. To the best of our knowledge, this is the first study that attempts a non-invasive SCD stratification of patients under AF rhythm by assessing ventricular repolarization instability from the ECG signal. To conclude, the research presented in this thesis sheds some light in the identification of pro-arrhythmic factors, which plays an important role in adopting efficient therapeutic strategies. In particular, the optimal configuration for real-time monitoring of repolarization alternans from intracardiac EGMs, together with the prognostic value of the proposed non-invasive indices of alternans activity and ventricular instability variations in case of AF rhythms demonstrated in two clinical studies, would increase the effectiveness of (ICD) therapy. Finally, the analysis of ECG signals recorded during HDBR experiments in structurally healthy hearts, also provides interesting information on cardiovascular alterations produced in immobilized or bedridden patients.<br /