Computerized systems and methods for stability-theoretic prediction and prevention of sudden cardiac death

What is claimed is: 1. One or more computer-readable storage devices having computer-executable instructions embodied thereon that when executed, facilitate a method for automatically providing a notification for ventricular arrhythmias in an individual that are likely to result in sudden cardiac death (SCD), the method comprising: obtaining, from one or more sensors, signals representative of electrical activity of the heart of said individual; determining, utilizing an objective function, a QT dispersion stability index (QTdSI) from said signals, the objective function comprising a timeseries calculated from serially-acquired waveform data; the determining comprising calculating a moving average of Lyapunov exponents; determining a difference between the determined QTdSI and a reference value to detect the presence of instability of QT interval dispersion or other measurements in said signals; and providing a notification when an increased risk for SCD is determined; a significant difference being indicative of an increased risk of said individual of sudden cardiac death (SCD); the results of the objective function being used by a decision-support algorithm to determine a quantitative risk for SCD; and the decision-support algorithm comprising at least one of a support vector machine, logistic regression equation, or a neural network. 2. The computer-readable storage devices of claim 1 , wherein the objective function evaluates digitized electrocardiographic waveforms from one or a plurality of previous time intervals to classify a likelihood of a cascade of events leading to SCD within a future time interval. 3. The computer-readable storage devices of claim 1 , wherein the Lyapunov exponent is evaluated on one or a plurality of ECG or other physiologic variables as functions of time. 4. The computer-readable storage devices of claim 1 , wherein the decision-support algorithm comprises a support vector machine utilizing timeseries of calculated ECG variables including: width of root-mean-square (RMS) T-wave, total cosine T-wave dispersion, T-wave loop dispersion, normalized T-wave loop area, and relative T-wave residuum. 5. The computer-readable storage devices of claim 1 , wherein the decision-support algorithm comprises a combination of two or more of a Lyapunov-based algorithm, a decision tree algorithm, or a support vector machine. 6. The computer-readable storage devices of claim 1 , wherein the QTdSI is determined as a function of a continuous QT interval timeseries. 7. The computer-readable storage devices of claim 1 , wherein the QTdSI is determined as a function of a discrete QT interval timeseries. 8. The computer-readable storage devices of claim 1 , wherein the Lyapunov exponent is calculated for each new heart beat. 9. The computer-readable storage devices of claim 1 , wherein the timeseries comprises approximately 400 samples. 10. The computer-readable storage devices of claim 1 , wherein the objective function comprises a second-order polynomial function determined using Taylor series regression or spectral analysis. 11. A method for automatically providing a notification for ventricular arrhythmias in an individual that are likely to result in sudden cardiac death (SCD), the method comprising: obtaining, from one or more sensors, ECG signals representative of electrical activity of the heart of said individual; and determining, utilizing an objective function, a QT dispersion stability index (QTdSI) from said signals, the objective function comprising a timeseries calculated from serially-acquired waveform data as functions of time the determining comprising calculating a moving average of Lyapunov exponents of a plurality of ECG or other physiologic variables; determining a difference between the determined QTdSI and a reference value to detect the presence of instability of QT interval dispersion or other measurements in said signals; a significant difference being indicative of an increased risk of said individual of SCD; and providing a notification to a health care provider when said increased risk for SCD is indicated; the results of the objective function being used by a decision-support algorithm to determine a quantitative risk for SCD; and the decision-support algorithm comprising at least one of a support vector machine, logistic regression equation, or a neural network. 12. The method of claim 11 , wherein the objective function evaluates digitized electrocardiographic waveforms from one or a plurality of previous time intervals to classify a likelihood of a cascade of events leading to SCD within a future time interval. 13. The method of claim 11 , wherein the decision-support algorithm comprises a support vector machine utilizing timeseries of calculated ECG variables including: width of root-mean-square (RMS) T-wave, total cosine T-wave dispersion, T-wave loop dispersion, normalized T-wave loop area, and relative T-wave residuum. 14. The method of claim 11 , wherein the decision-support algorithm comprises a combination of two or more of a Lyapunov-based algorithm, a decision tree algorithm, or a support vector machine. 15. The method of claim 11 , wherein the QTdSI is determined as a function of a continuous QT interval timeseries. 16. The method of claim 11 , wherein the QTdSI is determined as a function of a discrete QT interval timeseries.