Abstract: An anatomical mapping system and method includes mapping electrodes configured to detect activation signals of cardiac activity. A processing system is configured to record the detected activation signals and generate a vector field for each sensed activation signal during each instance of the physiological activity. The processing system determines an onset time and alternative onset time candidates, identifies an initial vector field template based on a degree of similarity between the initial vector field and a vector field template from a bank of templates, then determines an optimized onset time for each activation signal based on a degree similarity between the onset time candidates and initial vector field template.

Abstract: A method and system for mapping an anatomical structure includes sensing activation signals of intrinsic physiological activity with a plurality of mapping electrodes disposed in or near the anatomical structure. The activation signals are used to determine a dominant frequency for each electrode from which a wavefront vector for each electrode is determined based on a difference between the dominant frequency at a first electrode location and the dominant frequency at neighboring electrodes. An anatomical map is generated based on the determined wavefront vectors.

Abstract: A device and method for delivering electrical stimulation to the heart in order to improve cardiac function in heart failure patients. The stimulation is delivered as high-output pacing in which the stimulation is excitatory and also of sufficient energy to augment myocardial contractility. The device may be configured to deliver high-output pacing upon detection of cardiac decompensation.

Abstract: A system and method for mapping an anatomical structure includes sensing activation signals of intrinsic physiological activity with a plurality of electrodes disposed in or near the anatomical structure. A most recent intrinsic event at a selected time is determined based on the sensed activation signals and a persistent display of relevant characteristics is generated based on the sensed activation signals of the most recent intrinsic event. The persistent display is updated upon detection of a subsequent intrinsic event.

Abstract: A method and system for mapping an anatomical structure includes sensing activation signals of intrinsic physiological activity with a plurality of electrodes disposed in or near the anatomical structure. Substantially similar activation signals are binned according to a self-correlation algorithm which identifies patterns among the sensed activation signals. A template is generated for each bin and compared to a characteristic template to identify at least one bin which corresponds to a far-field activation signal.

Abstract: System and methods for programming and delivering electrical stimulation to treat hypertension are discussed. In various embodiments, an ambulatory stimulator system, such as an implantable medical device, can receive a power-saving command and deliver the electrical stimulation to a target site in a patient according to one or more simulation parameters including a therapy on-off pattern. In some embodiments, stimulation with therapy on-off pattern can reduce the power consumption while maintaining the anti-hypertension therapy efficacy. In some embodiments, the ambulatory stimulator system can include one or more of a physiologic response detector, a patient status detector, or a battery longevity detector. The power-saving command can be generated using one or more of the detected physiologic signal, the patient status, or the information about the battery longevity.

Abstract: System and methods for programming and delivering electrical stimulation to treat hypertension are described. In various embodiments, an ambulatory stimulator system, such as an implantable medical device, can detect a respiration-mediated heart rate variation (RM-HRV), monitor the efficacy of hypertension therapy and adjust the stimulation parameters using the detected RM-HRV to achieve desired therapy outcome. In some embodiments, the system can be configured to synchronize the detected heart rates to one or more respiration cycles or respiration phases within the respiration cycles, and determine the RM-HRV using the heart rates synchronized with the respiration cycles or the respiration phases. The RM-HRV may be presented to the system operator to monitor the efficacy of the AHT therapy. The ambulatory stimulator system can adjust the stimulation parameters using at least the RM-HRV.

Abstract: Disclosed herein, among other things, is a device for providing a localized vasomodulation of a vessel. According to an embodiment, the device includes a thermal element configured to conduct thermal energy between the thermal element and a desired region of the vessel wall to elicit the localized vasomodulation of the vessel at the desired region. The device also includes a controller operationally connected to the thermal element. The controller is adapted to control the conduction of thermal energy between the thermal element and the desired region of the vessel wall to control the localized vasomodulation of the vessel at the desired region. In various embodiments, a sensor connected to the device provides feedback to the controller.

Abstract: Some embodiments provide a system for delivering neurostimulation. Some system embodiments comprise a lead configured to be implanted in the body, a stimulation output circuit configured to deliver neurostimulation pulses to the vagus nerve through the lead, an EMG sensing circuit configured to use the lead to sense EMG signals from laryngeal muscle activity, and an evoked muscular response detection circuit configured to use the EMG signals sensed by the EMG sensing circuit to detect evoked laryngeal muscle activity evoked by the neurostimulation pulse.

Abstract: Various system embodiments comprise a myocardial stimulator, at least one sensor adapted for use in detecting heart rate to determine heart rate turbulence (HRT), and a controller connected to the myocardial stimulator and the at least one sensor. The myocardial stimulator is adapted to deliver pacing pulses through at least one electrode to provide cardiac pacing. The controller is adapted to intermittently deliver a sequence of stress-inducing pacing pulses adapted to increase sympathetic tone during the stress-inducing pacing. The controller is further adapted to determine HRT from the detected heart rate to assess cardiac stress to the stress-inducing pacing pulses, and adjust at least one parameter of the stress-inducing pacing pulses to adjust cardiac stress if the cardiac stress to the stress-inducing pacing pulses is undesirable.

Abstract: Cardioprotective pre-excitation pacing may be applied to stress or de-stress a particular myocardial region delivering of pacing pulses in a manner that causes a dyssynchronous contraction. Such dyssynchronous contractions are responsible for the desired cardioprotective effects of pre-excitation pacing but may also be hazardous. Described herein is a method and system that uses measures of a patient's heart rate or exertion level to control the duty cycles of intermittent pre-excitation pacing.

Abstract: A method for mapping a cardiac chamber includes sensing activation signals of intrinsic physiological activity with a plurality of electrodes disposed in or near the cardiac chamber, the activation signals including a near-field activation signal component and a far-field activation signal component, isolating R-wave events in the activation signals, generating a far-field activation template representative of the far-field activation signal component based on the R-wave events, and filtering the far-field activation template from the activation signals to identify the near-field activation signal components in the activation signals.

Abstract: A method for mapping an anatomical structure includes sensing activation signals of physiological activity with a plurality of electrodes disposed in or near the anatomical structure, each activation signal having an associated cycle length, estimating an action potential duration and diastolic interval for each cycle length, generating a restitution curve based on the estimated action potential duration and diastolic interval from a preceding cycle length, iteratively optimizing each estimated action potential duration and corresponding diastolic interval to maximize a functional relationship between the estimated action potential duration and estimated diastolic interval from preceding cycle length, and generating an action potential duration restitution curve based on the optimized action potential durations and diastolic intervals.

Abstract: An anatomical mapping system includes a plurality of mapping electrodes each having an electrode location and configured to detect activation signals of intrinsic physiological activity within an anatomical structure. A mapping processor is associated with the plurality of mapping electrodes and is configured to record the detected activation signals and associate one of the plurality of mapping electrodes with each recorded activation signal. The mapping processor is further configured to analyze the recorded activation signals to identify at least one recurring pattern based on a relationship between a timing of the detected activation signals and the electrode locations of the mapping electrode associated with each detected activation signal.

Abstract: A catheter system includes a mapping catheter including a plurality of mapping electrodes, each mapping electrode configured to sense signals associated with an anatomical structure. The catheter system further includes a processor operatively coupled to the plurality of mapping electrodes and configured to receive the signals sensed by the plurality of mapping electrodes, characterize the signals sensed by the plurality of mapping electrodes based on amplitudes of the sensed signals, and generate an output of a quality of contact of the plurality of mapping electrodes with the anatomical structure based on the signal characterization.

Abstract: A method for mapping an anatomical structure includes sensing activation signals of intrinsic physiological activity with a plurality of electrodes disposed in or near the anatomical structure, identifying at least one of the electrodes not in direct contact with the anatomical structure, and adjusting the activation signals sensed by each of the plurality of electrodes based on the activation signals sensed by the identified at least one of the electrodes not in direct contact with the anatomical structure.

Abstract: A catheter system includes a mapping catheter having a plurality of splines, each of the plurality of splines including a plurality of mapping electrodes. The system further includes a processor operatively coupled to the plurality of mapping electrodes and configured to receive signals sensed by the plurality of mapping electrodes. The processor is further configured to estimate an interspline distance between adjacent splines in the plurality of splines based on the signals sensed by the mapping electrodes on the adjacent splines.

Abstract: Stimulation energy can be provided to a His-bundle to activate natural cardiac contraction mechanisms. Interval information can be used to describe a cardiac response to His-bundle stimulation, and the interval information can provide cardiac stimulation diagnostic information. For example, interval information can be used to discriminate between intrinsic conduction cardiac contractions and contractions responsive to His-bundle pacing.

Abstract: Methods and systems to modulate timing intervals for pacing therapy are described. For each cardiac cycle, one or both of an atrioventricular (A-V) timing interval and an atrial (A-A) timing interval are modulated to oppose beat-to-beat ventricular (V-V) timing variability. Pacing therapy is delivered using the modulated timing intervals.

Abstract: In an example, configuring an implantable medical device by determining port usage can include, receiving a port data object, determining a lead configuration, configuring access to a programmable parameter, and displaying a visual indication of the lead configuration. The port data object can be received from the implantable medical device and can include data associated with a port of the implantable medical device capable of connecting to a lead. The determining a lead configuration can be based on the port data object. The configuring access to a programmable parameter can be based on the lead configuration of the implantable medical device.