Abstract: An external programmer is provided with the capability of automatically resetting the programming state of an implantable medical device to a previous programming state. To this end, the pacemaker maintains parameters representative of current and past programming states. In response to a physician-initiated reset function using an external programmer, the pacemaker transfers information pertaining to the programming states to the external programmer along with a pointer identifying the current state. The physician selects one of the previous programming states and the external programmer then updates the pointer to identify the selected state and transmits the pointer back to the pacemaker. The pacemaker accesses the programming parameters stored therein corresponding to the programming state identified by the new pointer and is reprogrammed. Accordingly, the programming state of the pacemaker is reset to the previous programming state without requiring manual reentry of the parameters.

Abstract: The implant guiding programmer is configured to automatically determine a defibrillation threshold (DFT) for a particular patient and to further determine an optimal implantation configuration for an implantable cardioverter fibrillator (ICD). In one implementation, to determine the DFT for the patient, the programmer correlates patient specific data with a predictive data base containing DFT information for an entire population of patients. The programmer additionally determines an optimal implantation configuration for the patient, wherein the optimal configuration is one which is capable of exceeding the DFT for the patient using minimal electrical pulse energy.

Abstract: The implant guiding programmer is configured to automatically determine the defibrillation threshold (DFT) for a particular patient and to further determine an optimal implantation configuration for an implantable cardioverter fibrillator (ICD). In one implementation, to determine the DFT for the patient, the programmer correlates patient specific data with a predictive data base containing DFT information for an entire population of patients. The patient specific data includes the age, gender, heart size, chest size and medical history of the patient. The predictive database provides information correlating patient DFT with various ranges of the patient specific data for an entire population of data. In this manner, the programmer quickly approximates the DFT for the particular patient based upon the age, gender, heart size and medical history of the patient.

Abstract: An apparatus for treating an infection which may occur in the biofilm which surrounds an implanted cardiac stimulation device, e.g., a cardioverter-defibrillator (ICD) or pacemaker. Such infections are relatively untreatable by conventional antibiotics treatments. Thus, explanting of the implanted devices may be required. Accordingly, the present apparatus provides an electrical treatment that enables a biocide, i.e., an antibiotic, to successfully treat the infection within the biofilm and thus avoid the necessity to explant the device. Furthermore, the present invention provides this electrical treatment in a manner to not interfere with the stimulation pulses of the cardiac stimulation device by alternatively delivering current pulses during atrial and ventricular refractory periods or a high frequency square wave at a frequency that exceeds the frequency response of the heart muscle.

Abstract: An implantable cardiac stimulation system is disclosed which automatically optimizes its ability to rate-responsively pace by enabling calibration when the patient is at rest and has a functioning lead. Devices which employ physiologic sensors are based on a baseline value of the sensor signal corresponding to the resting state. Accordingly, the control system determines if the patient is at rest using a suitable sensor and also determines if the lead impedance is within normal values, i.e. functional and intact. If these conditions are met, the control system stores the current baseline of the sensor at rest and proceeds with normal sensing and stimulation commands until the next calibration is performed. In addition, the system can automatically calibrate a sleep value for the physiologic sensor using a sensor which can detect the sleep state.

Abstract: Methods and apparatus are provided for storing intracardiac electrogram (IEGM) and other cardiac data in an implantable cardiac device. When a physician wishes to create a cardiac data record containing the IEGM and other cardiac data, the physician directs the cardiac device to store the data on demand. A number of cardiac data records can be stored. Data records may also be stored after a delay period following a predetermined cardiac event. When the implantable cardiac device detects the predetermined cardiac event, the delay period begins. At the expiration of the delay period, the implantable cardiac device stores a cardiac data record. Cardiac data records can also be stored according to a predetermined schedule.

Abstract: An implantable tachyarrhythmia control system includes a patch electrode having a sensor integrated therein, such as a piezoelectric sensor, which is capable of monitoring mechanical heart activity. When the patch electrode is sutured to the cardiac tissue, the piezoelectric sensor will be deformed due to the mechanical activity of the heart muscle, and will generate a corresponding electrical signal. The electrical signal from the sensor will exhibit relatively low-frequency periodicity and relatively low amplitude during normal heart activity. In the event of tachycardia or fibrillation, the signal will exhibit excursions beyond those occurring for normal heart activity, and will consequently have a higher energy content. The signal is thus an indicator for the onset of these cardiac events. The signal can be supplied to an implantable defibrillator and can be used as a primary or secondary trigger for initiating defibrillation therapy, such as one or more defibrillating pulses.