Abstract: An implantable medical device (IMD) is configured with a pressure sensor. The IMD includes a housing, a pressure sensor and a fluid filled cavity. The housing has a diaphragm that is exposed to the environment outside of the housing. The pressure sensor has a pressure sensor diaphragm that is responsive to a pressure applied to the pressure sensor diaphragm and provides a pressure sensor output signal that is representative of the pressure applied to the pressure sensor diaphragm. The fluid filled cavity is in fluid communication with both the diaphragm of the housing and the pressure sensor diaphragm of the pressure sensor. The fluid filled cavity is configured to communicate a measure related to the pressure applied by the environment to the diaphragm of the housing to the pressure sensor diaphragm of the pressure sensor.

Abstract: Delivery devices, systems, and methods for delivering implantable leadless pacing devices are disclosed. An example delivery device may an outer tubular member and an inner tubular member slidably disposed within the lumen of the outer tubular member. A distal holding section may extend distally of a distal end of the inner tubular member and define a cavity therein for receiving an implantable leadless pacing device. The device may further include a hub portion including at least a first hub portion affixed adjacent to the proximal end of the outer tubular member and a second hub portion affixed adjacent to the proximal end of the inner tubular member. A first locking mechanism configured to releasably couple the outer tubular member and the inner tubular member may be disposed within the hub portion.

Abstract: Methods and devices for configuring the use of a motion sensor in an implantable cardiac device. The electrical signals of the patient's heart are observed and may be correlated to the physical motion of the heart as detected by the motion sensor of the implantable cardiac device in order to facilitate temporal configuration of motion sensor data collection that avoids detecting cardiac motion in favor of overall motion of the patient.

Abstract: An implantable cardiac monitor (ICM) may be configured to be deployed subcutaneous, submuscular, or substernal at a position that enables the ICM to detect cardiac activity. In some cases, the ICM includes a housing that includes a body portion and a tail portion. A first electrode may be disposed adjacent a first end of the body portion, a second electrode may be disposed adjacent a second end of the body portion and a third electrode may be disposed adjacent a tail end of the tail portion. A controller may be disposed within the housing and may be operably coupled to the first electrode, the second electrode and the third electrode. The controller may be configured to select a pair of the first electrode, the second electrode and the third electrode to use for sensing cardiac electrical activity and to communicate information about the sensed activity to a second medical device.

Abstract: An implantable leadless cardiac pacing device and associated retrieval features. The implantable device includes a docking member extending from the proximal end of the housing of the implantable device including a covering surrounding at least a portion of the docking member configured to facilitate retrieval of the implantable leadless cardiac pacing device.

Abstract: Systems, methods and implantable devices configured to provide cardiac resynchronization therapy and/or bradycardia pacing therapy. A first device located in the heart of the patient is configured to receive a communication from a second device and deliver a pacing therapy in response to or in accordance with the received communication. A second device located elsewhere is configured to determine an atrial event has occurred and communicate to the first device to trigger the pacing therapy. The second device may be configured for sensing the atrial event by the use of vector selection and atrial event windowing, among other enhancements. Exception cases are discussed and handled as well.

Abstract: A leadless cardiac pacemaker (LCP) may be deployed within a patient's vasculature at a location near the patient's heart in order to pace the patient's heart and/or to sense electrical activity within the patient's heart. In some cases, an LCP may be implanted within the patient's superior vena cava or inferior vena cava. The LCP may include an expandable anchoring mechanism configured to secure the LCP in place.

Abstract: An implantable medical device (IMD) may include an outer housing having a titanium outer surface, the titanium outer surface including a plurality of titanium atoms. A tissue growth-inhibiting layer may extend over the titanium outer surface. In some cases, the tissue growth-inhibiting layer may include a plurality of polyethylene glycol molecules, at least some of the plurality of polyethylene glycol molecules covalently bonded via an ether bond to one of the plurality of titanium atoms.

Abstract: An implantable medical device may include a housing configured to be positioned at least in part in a right ventricle (RV) proximate an RV facing side of the ventricular septum. A power source and circuitry may be disposed within the housing and may be operatively coupled together. An RV electrode may be fixed relative to the housing to be proximate the RV facing side of the ventricular septum and may be operatively coupled with the circuitry. An LV electrode support may extend away from the housing into the ventricular septum toward the LV facing side of the ventricular septum and may support an LV electrode that is operatively coupled with the circuitry. The circuitry may be configured to pace the RV of the patient's heart using the RV electrode and to pace the LV of the patient's heart using the LV electrode.

Abstract: Implantable medical devices such as leadless cardiac pacemakers (LCP) may be configured to be delivered to a target location within the heart over a guide wire. In some cases, using a guide wire for delivery facilitates placement of devices in regions not otherwise easily reached. An LCP may include a housing and a wire lumen disposed relative to the housing. The wire lumen may be configured to allow the LCP to slide over a guide wire. In some cases, the guide wire may include a guide wire electrode that may be used to test potential implantation sites.

Abstract: An implantable leadless cardiac pacing device and associated retrieval features. The implantable device includes a docking member extending from the proximal end of the housing of the implantable device including a covering surrounding at least a portion of the docking member configured to facilitate retrieval of the implantable leadless cardiac pacing device.

Abstract: An implantable medical device includes operational circuitry and a power source configured to deliver energy to the operational circuitry. The operational circuitry includes, for example, a therapy circuit. The implantable medical device also includes a deactivation element configured to disable the therapy circuit. The implantable medical device also includes a power manager configured to detect an end-of-life condition of the power source and, in response to detecting the end-of-life condition, to cause the deactivation element to disable the therapy circuit.

Abstract: A battery having flat, stacked, anode and cathode layers. The battery can be adapted to fit within an implantable medical device.

Abstract: Delivery devices, systems, and methods for delivering implantable leadless pacing devices are disclosed. An example delivery system may comprise a delivery device, an implantable leadless pacing device, and a tether. The tether may be made of a material which allows for a lubricious, strong, no stretch, no memory tether. The tether may releasably secure the implantable leadless pacing device to the delivery device.

Abstract: Delivery devices, systems, and methods for delivering implantable leadless pacing devices are disclosed. An example delivery device may include an intermediate tubular member and an inner tubular member slidably disposed within a lumen of the intermediate tubular member. A distal holding section may extend distally of a distal end of the intermediate tubular member and define a cavity therein for receiving an implantable leadless pacing device. The device may further include a handle assembly including at least an intermediate hub portion affixed adjacent to the proximal end of the intermediate tubular member and a proximal hub portion affixed adjacent to the proximal end of the inner tubular member. A longitudinally extending groove having a proximal end and a distal end may be disposed in the intermediate hub portion. A first locking mechanism may be configured to releasably couple the intermediate hub portion and the proximal hub portion.

Abstract: A battery having flat, stacked, anode and cathode layers. The battery can be adapted to fit within an implantable medical device.

Abstract: Fixation mechanism assemblies and methods are disclosed. A fixation mechanism assembly can include a first fixation member and a second fixation member moveably engaged with the first fixation member. The first fixation member can include a housing having a tissue facing surface and an opposing non-tissue facing surface, one or more guide apertures extending between the tissue facing surface and the non-tissue facing surface, and one or more first fixation elements. The first fixation member includes a longitudinal body and a proximal end attached to, or integrated with, the tissue facing surface of the housing. The second fixation member can include one or more second fixation elements. The second fixation element can correspond to a guide aperture and includes a longitudinal body, a proximal end attached to, or integrated with, the second fixation member, and a distal end movable through the corresponding guide aperture.

Abstract: A temporary implantable medical device lead includes a connector, a helically coiled conductor and a first mechanical element. The connector is configured to connect the lead to an external control module. The helically coiled conductor has a proximal end mechanically and electrically connected to the connector. The conductor includes a plurality of filars mechanically and electrically connected to the connector. The first mechanical element includes a metal tube having a plurality of longitudinally spaced grooves formed along an exterior of the tube. The plurality of longitudinally spaced grooves receives at least some of the plurality of filars. The at least some of the plurality of filars electrically connected to the first mechanical element such that the first mechanical element is configured as an electrode to deliver electrical stimulation to portions or systems of a body from the external control module.

Abstract: Systems, methods, and devices for detecting or confirming fibrillation are discussed. In one example, a method for detecting a cardiac arrhythmia of a patients' heart comprises receiving, by a leadless cardiac pacemaker fixed in the patients' heart, an indication from a remote device that a cardiac arrhythmia is detected, monitoring by the leadless cardiac pacemaker a signal generated by a sensor that is located within the patients' heart, and based at least in part on the monitored signal, confirming whether a cardiac arrhythmia is occurring or not. In some embodiments, the method may further comprise, if a cardiac arrhythmia is confirmed, delivering a therapy to treat the cardiac arrhythmia.

Abstract: A leadless cardiac pacing system includes first and second leadless pacing seeds configured to deliver pacing therapy to a first and second location in a patient, respectively. The second seed includes an electrode, a therapy circuit configured to provide electrostimulation energy to the electrode, a communications component, and a power source. The second seed also includes a power manager configured to detect an end-of-life condition associated with the seed and, in response to detecting the end-of-life condition, to communicate a signal that causes the first seed to change from a first operational state to a second operational state, in which the first seed implements one or more operational parameters configured to adapt to a change in an output from the second seed resulting from the second seed entering the end-of-life condition.