| Patent application number | Description | Published |
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| 20090018595 | SYSTEMS AND METHODS FOR EMPLOYING MULTIPLE FILTERS TO DETECT T-WAVE OVERSENSING AND TO IMPROVE TACHYARRHYTHMIA DETECTION WITHIN AN IMPLANTABLE MEDICAL DEVICE - Techniques are described for detecting tachyarrhythmia and also for preventing T-wave oversensing using a narrowband bradycardia filter in combination with a narrowband tachycardia filter. In some embodiments, a separate wideband filter is also exploited. In one illustrative example, ventricular tachycardia (VT) is detected by: detecting a preliminary indication of VT using signals filtered by the bradycardia filter and, in response, confirming the detection of VT using signals filtered by the tachycardia filter. That is, the bradycardia filter, traditionally used only to detect bradycardia, is additionally used to provide a preliminary indication of VT. The tachycardia filter is then activated to confirm the detection of VT before therapy is delivered. In this manner, the tachycardia filter need not run continuously, but is instead activated only when there is some indication of possible VT, and hence power is saved. Numerous other exemplary techniques are set forth herein for arrhythmia detection and for T-wave oversensing detection. | 01-15-2009 |
| 20090264950 | MEDICAL DEVICES AND SYSTEMS HAVING SEPARATE POWER SOURCES FOR ENABLING DIFFERENT TELEMETRY SYSTEMS - An implantable medical device includes a first, short-range telemetry circuit; a second, long-range telemetry circuit; a first power system that powers the first telemetry circuit; and a second power system that powers the second telemetry circuit. The second power system includes an internal charging system and a rechargeable battery coupled to the internal charging system. The internal charging system may be configured for electromagnetic-inductive or RF-transmission coupling with an external charging system. A controller monitors the energy level of the rechargeable battery and provides an signal indicative of the level. | 10-22-2009 |
| 20100023083 | METHODS AND DEVICES INVOLVING AUTOMATIC ATRIAL BLANKING - During a period of time comprising a plurality of cardiac cycles, a time relationship between ventricular events and atrial detections is established. Based on the relationship, a post-ventricular atrial refractory period is defined. The period includes an absolute atrial refractory period and a segmented relative atrial refractory period, wherein the segmented relative atrial refractory period includes at least one blanking window during which atrial detections of ventricular events have or are likely to occur. | 01-28-2010 |
| 20100042176 | TEMPORAL-BASED CARDIAC CAPTURE THRESHOLD DETECTION - A cardiac capture threshold may be determined using a test pulse and a backup pulse. Here, delivery of a test pulse is followed almost immediately by a non-conditional backup pulse of sufficient energy such that the backup pulse should always capture in the event the test pulse does not capture. The timing of the evoked response that follows the backup pulse may then be used to determine whether the test pulse or the backup pulse captured the cardiac tissue. In some embodiments morphology discrimination may be employed to determine whether an evoked response was triggered by the test pulse or the backup pulse. In some embodiments timing information associated with one or more features of the evoked response may be analyzed to determine whether an evoked response was triggered by the test pulse or the backup pulse. | 02-18-2010 |
| 20100063561 | IMPLANTABLE CARDIAC STIMULATION DEVICES WITH SAFE-MODE OPERATION - A plurality of electrodes are implanted in, on or near the patient's heart and initially configured to define first circuits or vectors enabled for at least one of sensing and stimulating and second circuits or vectors which are idle for at least one of sensing and stimulating. Selected first circuits or second circuits are tested for fault indications related to one or both of sensing and stimulating and a status record is updated to indicate corresponding sensing fault indications and stimulating fault indications. If a sensing fault is found in one of the first circuits, the first circuit is redefined when enabled for sensing to include at least one electrode of a second circuit that does not have a record of a sensing fault indication. Likewise, if a stimulating fault is found in one of the first circuits, the first circuit is redefined when enabled for stimulating to include at least one electrode of a second circuit that does not have a record of a stimulating fault indication. | 03-11-2010 |
| 20100100148 | CAPTURE ASSESSMENT AND OPTIMIZATION OF TIMING FOR CARDIAC RESYNCHRONIZATION THERAPY - An exemplary method includes performing a ventricular capture assessment, determining a ventricular paced propagation delay (PPD) and/or an interventricular conduction delay (IVCD) using information acquired during the ventricular capture assessment and optimizing at least an interventricular delay (VV) based at least in part on the ventricular paced propagation delay (PPD) and/or the interventricular conduction delay (IVCD). Another exemplary method includes performing an atrial capture assessment, determining an atrial evoked response width (ΔA) and one or more atrio-ventricular intervals (AR) using information acquired during the atrial capture assessment and optimizing an atrio-ventricular (PV or AV) delay based at least in part on the atrial evoked response width (ΔA) and the one or more atrio-ventricular intervals (AR). Other exemplary methods, devices, systems, etc., are also disclosed. | 04-22-2010 |
| 20100114194 | SYSTEM AND METHOD FOR ACCURATELY DETECTING CARDIAC EVENTS USING MULTI-THRESHOLD PROCESSING - A system and method provide precise detection of the time of occurrence of a cardiac event of a heart. The method comprises the steps of sensing electrical activity of the heart to generate an electrogram of the heart and applying the electrogram to an event detector having a plurality of spaced apart thresholds. The thresholds are selected such that the electrogram has an amplitude for crossing at least one of the thresholds. The method further comprises determining a characteristic identifying feature of the electrogram at each threshold crossing of the electrogram, comparing the determined characteristic identifying features to an electrogram template, and identifying the time of occurrence of the cardiac event based upon the comparison. | 05-06-2010 |
| 20100114228 | SYSTEM AND METHOD FOR ACCURATELY DETECTING CARDIAC EVENTS USING RETROSPECTIVE CORRELATION - A system and method enables precise detection of the time of occurrence of a cardiac event of a heart. The method includes the steps of sensing electrical activity of the heart to generate an electrogram signal including the cardiac event, storing the electrogram signal, correlating the electrogram signal with an electrogram template, and identifying the time of occurrence of the cardiac event based upon the correlation. | 05-06-2010 |
| 20100318152 | METHOD AND SYSTEM FOR OVERDRIVING A HEART CHAMBER DURING A THRESHOLD SEARCH - An implantable medical device includes a lead, a pulse generator, an autothreshold module and a control module. The lead includes electrodes positioned within a heart. At least one of the electrodes senses cardiac signals. The pulse generator delivers a stimulus pulse through at least one of the electrodes. The autothreshold module performs a threshold search when operating in an autothreshold mode and causes atrial stimulus pulses to be delivered in an atrium of the heart at an overdrive rate during the threshold search. The control module determines an AV conduction time and applies an overdrive AV adjustment to the AV conduction time to generate an AV delay. The autothreshold module uses the AV delay in connection with delivering ventricular stimulus pulses to a ventricle of the heart. | 12-16-2010 |
| 20100318153 | METHOD AND SYSTEM FOR AUTOMATICALLY SWITCHING BETWEEN MODES OF AN IMPLANTABLE MEDICAL DEVICE - An implantable medical device includes a lead, a pulse generator, an autocapture module, an autothreshold module, a fusion detection module, and a control module. The lead includes electrodes configured to be positioned within a heart. At least one of the electrodes is capable of sensing cardiac signals. The pulse generator delivers a stimulus pulse through at least one of the electrodes. The autocapture module senses an evoked response of the heart after delivery of the stimulus pulse when operating in an autocapture mode. The autothreshold module performs a threshold search when operating in an autothreshold mode. The fusion detection module identifies fusion-based behavior in the heart. The control module automatically switches between the autothreshold and autocapture modes based on a presence of the fusion-based behavior. | 12-16-2010 |
| 20110112597 | SYSTEMS AND METHODS FOR OFF-LINE REPROGRAMMING OF IMPLANTABLE MEDICAL DEVICE COMPONENTS TO REDUCE FALSE DETECTIONS OF CARDIAC EVENTS - Techniques are provided for use by implantable medical devices such as pacemakers or by external systems in communication with such devices. An intracardiac electrogram (IEGM) is sensed within a patient in which the device is implanted using a cardiac signal sensing system. Cardiac events of interest such as arrhythmias, premature atrial contractions (PACs), premature ventricular contractions (PVCs) and pacemaker mediated tachycardias (PMTs) are detected within the patient using event detection systems and then portions of the IEGM representative of the events of interest are recorded in device memory. Subsequently, during an off-line or background analysis, the recorded IEGM data is retrieved and analyzed to identify false detections. In response to false detections, the cardiac signal sensing systems and/or the event detection systems of the implantable device are selectively adjusted or reprogrammed to reduce or eliminate any further false detections, including false-positives or false-negatives. Various adaptive reprogramming techniques are described. | 05-12-2011 |
| 20110125206 | SINGLE CHAMBER IMPLANTABLE MEDICAL DEVICE FOR CONFIRMING ARRHYTHMIA THROUGH RETROSPECTIVE CARDIAC SIGNALS - An implantable medical device is provided that comprises a housing, sensors configured to be located to proximate a heart, and a sensing module to sense cardiac signals originating from the heart over a channel defined by the sensors. The cardiac signals include intrinsic R-wave events and associated intrinsic confirmation events when the heart exhibits normal sinus rhythm. The device further includes memory to store the cardiac signals sensed over a channel, and a detection module. The detection module identifies an R-wave event within the cardiac signals. The detection module captures, in the memory, a segment of the cardiac signals that precedes the R-wave event as a retrospective segment. The detection module determines whether the retrospective segment includes an intrinsic confirmation event that is associated with and occurs before the R-wave event. The detection module declares an arrhythmia based at least in part on the determination of whether the retrospective segment includes the intrinsic confirmation event is absent from the retrospective segment. | 05-26-2011 |
