초록 ▼

A surface electrocardiogram (EKG) is emulated using signals detected by the internal leads of an implanted device. The emulation is performed using a matrix-based technique that separately emulates each of the individual signals of a multiple-lead EKG, rather than merely emulating a single combined

A surface electrocardiogram (EKG) is emulated using signals detected by the internal leads of an implanted device. The emulation is performed using a matrix-based technique that separately emulates each of the individual signals of a multiple-lead EKG, rather than merely emulating a single combined EG. In one example, each of the twelve signals of a standard 12-lead EKG are individually emulated, allowing for separate processing and display. The emulation technique takes into account factors affecting the relative locations of the internal leads, such as respiration and posture, to thereby provide a more accurate emulation. A calibration technique is provided for calibrating the EKG emulation for use with a particular patient and a verification technique is provided for automatically verifying the reliability of the emulation. Any significant loss in emulation reliability is likely caused by lead dislodgment and so automatic detection of possible lead dislodgment is also achieved.

대표청구항 ▼

1. A method performed by an external programmer in combination with an implantable cardiac stimulation device implanted within a patient and a multiple-lead surface electrocardiogram (EKG) unit, the method comprising:inputting separate initial multiple-lead surface EKG signals from the EKG unit dete

1. A method performed by an external programmer in combination with an implantable cardiac stimulation device implanted within a patient and a multiple-lead surface electrocardiogram (EKG) unit, the method comprising:inputting separate initial multiple-lead surface EKG signals from the EKG unit detected using separate surface electrodes attached to the patient;inputting initial internal electrical cardiac signals sensed by the implanted device using internal electrodes;generating, based on a comparison of the initial surface EKG signals and the initial internal cardiac signals, a set of conversion values for converting additional internal cardiac signals into separate multiple-lead surface EKG signals; andemulating separate multiple-lead surface EKG signals based on additional internal electrical cardiac signals using the conversion values such that the surface EKG unit is no longer needed. 2. The method of claim 1 wherein the surface EKG unit is a 12-lead surface EKG and wherein generating the set of conversion values is performed to generate a set of values for converting internal electrical cardiac signals into each of the twelve signals associated with the 12-lead surface EKG. 3. The method of claim 1 wherein generating the set of conversion values comprisesconverting the initial internal cardiac signals into a time-varying vector F(t) having individual elements corresponding to the pairs of electrodes;converting the initial surface EKG signals into a time-varying vector E(t) having individual elements corresponding to the surface leads;generating a time-varying conversion matrix M (t) of weighting factors by calculating M (t)=E(t)*F −1 (t); andaveraging the time-varying conversion matrix M (t) over time to yield a single fixed matrix M . 4. The method of claim 3wherein the pairs of electrodes includes N pairs of electrodes and the surface EKG includes M surface leads; andwherein F(t) has N elements, n=1, 2, . . . , N; E(t) has M elements, m=1, 2, . . . , M; and matrix M (t) is an N by M matrix containing weighting factors K n m . 5. The method of claim 3 further comprising generating verification values for use in evaluating the reliability of the emulation of the multiple-lead surface EKG signals. 6. The method of claim 5 wherein generating verification values comprisesidentifying like phases of a plurality of cardiac cycles of the patient based on the internal electrical cardiac signals;generating cross-correlation values representative of cross-correlations between elements of vector F(t) during like phases of the plurality of cardiac cycles;averaging the cross-correlation values to yield baseline cross-correlation values for use as verification values. 7. The method of claim 1 further comprisinginputting a signal representative of factors affecting the positions of the internal electrodes; andwherein the step of generating a set of conversion values is performed to generate separate sets of conversion values based upon the factors affecting the positions of the electrodes. 8. The method of claim 7 wherein the factors affecting the positions of the electrodes include one or more of: phase of a respiratory cycle of the patient, phase of a cardiac cycle of the patient, and posture of the patient. 9. The method of claim 7wherein the signal representative of the factors affecting the positions of the electrodes specifies the phase of the cardiac cycle of the patient; andwherein the step of generating separate sets of conversion values generates separate sets distinguishing among, at least, P-waves, QRS-complexes and T-waves. 10. The method of claim 7wherein the signal representative of the factors affecting the positions of the electrodes specifies the phase of the respiratory cycle of the patient; andwherein the step of generating separate sets of conversion values generates separate sets distinguishing between, at least, inhalation and exhalation. 11. The method of claim 7wherein the signal representativ e of the factors affecting the positions of the electrodes specifies the posture of the patient; andwherein the step of generating separate sets of conversion values generates separate sets distinguishing among, at least, standing, sitting and lying down. 12. The method of claim 1 wherein the method further comprises transmitting the conversion values to the implanted device for use therein. 13. A method performed by an external programmer in combination with an implantable cardiac stimulation device implanted within a patient and a multiple-lead surface electrocardiogram (EKG) unit, the method comprising:inputting separate initial multiple-lead surface EKG signals from the EKG unit detected using separate surface electrodes attached to the patient;inputting initial internal electrical cardiac signals sensed by the implanted device using internal electrodes;generating, based on a comparison of the initial surface EKG signals and the initial internal cardiac signals, a set of conversion values for converting additional internal cardiac signals into separate multiple-lead surface EKG signals;transmitting the conversion values to the implanted device for use therein to emulate separate multiple-lead surface EKG signals based on additional internal electrical cardiac signals; andreceiving and displaying emulated separate multiple-lead surface EKG signals generated by the implanted device. 14. In an external programmer for use with an implantable cardiac stimulation device implanted within a patient and a multiple-lead surface electrocardiogram (EKG) unit, a system comprising:a telemetry system operative to input separate initial multiple-lead surface EKG signals from the EKG unit detected using separate surface electrodes attached to the patient;the telemetry system also operative to input initial internal electrical cardiac signals sensed by the implanted device using internal electrodes; anda set-up system operative to generate, based on a comparison of the initial surface EKG signals and the initial internal cardiac signals, a set of conversion values for converting additional internal cardiac signals into separate multiple-lead surface EKG signals. 15. The system of claim 14 further comprising:an on-board surface electrocardiogram (EKG) emulation system operative to emulate separate multiple-lead surface EKG signals using the conversion values applied to additional input cardiac signals. 16. In an external programmer for use with an implantable cardiac stimulation device implanted within a patient and a multiple-lead surface electrocardiogram (EKG) unit, a system comprising:means for inputting separate initial multiple-lead surface EKG signals from the EKG unit detected using separate surface electrodes attached to the patient;means for inputting initial internal electrical cardiac signals sensed by the implanted device using internal electrodes;means for generating, based on a comparison of the initial surface EKG signals and the initial internal cardiac signals, a set of conversion values for converting additional internal cardiac signals into separate multiple-lead surface EKG signals; andmeans for emulating separate multiple-lead surface EKG signals based on additional internal electrical cardiac signals using the conversion values.