Abstract: An implantable pulse generator system includes a stimulation unit delivering vagal nerve stimulation pulses, an activity sensor determining an exertion level of the user and generating a signal representing metabolic demand, an autonomic tone sensor determining an autonomic status of the user and generating a signal representing autonomic status, and a control unit in communication with the foregoing components, and which is adapted to control the stimulation unit depending on both the signal representing metabolic demand and the signal representing autonomic status.

Abstract: An implantable pulse generator (106) provides electric stimulation pulses for nerve stimulation via a stimulation lead (100) having stimulation electrodes (102, 104). The electric stimulation pulses form a pulse train including (i) an initial selective-arrest phase for the large-diameter fibers in the vicinity of selected electrodes; (ii) followed by a charge-balanced phase where a charge-balanced alternating current (AC) is applied between the same or other selected electrodes; and (iii) a therapy phase where the charge-balanced alternating current (AC) is briefly unbalanced to deliver nerve stimulation therapy pulses, with the pulse train returning to the charge-balanced phase in between therapy pulses.

Abstract: An implantable leadless pacemaker (iLP) for a human or animal heart, wherein the iLP includes a housing, at least two electrode poles for picking up electrical potentials and/or delivering electrical stimulation, a stimulation control unit in connection with the electrode poles, a sensing unit that is in connection with at least one electrode pole, a signal processing unit in connection with the sensing unit, a signal evaluation unit in connection with the signal processing unit and/or the sensing unit, and an energy source. The sensing unit is configured to sense a first signal associated with an activity of the first heart chamber, and the stimulation control unit is configured to deliver electrical stimulation in the first heart chamber via the at least two electrode poles. wherein the sensing unit is configured to sense a second signal associated with an activity of a second heart chamber.

Abstract: An implantable leadless pacemaker (iLP) for a human or animal heart is provided that includes a housing, at least two electrode poles for picking up electrical potentials and/or delivering electrical stimulation, a stimulation control unit in connection with the electrode poles, a sensing unit that is in connection with at least one electrode pole, a signal processing unit in connection with the sensing unit, a signal evaluation unit in connection with the signal processing unit and/or the sensing unit, and an energy source. The sensing unit is configured to sense a first signal associated with an activity of the first heart chamber, and the stimulation control unit is configured to deliver electrical stimulation in the first heart chamber via the at least two electrode poles. The sensing unit is configured to sense a second signal associated with an activity of a second heart chamber.

Abstract: An intravascular electrode lead and an intravascular stimulation device including the same. The intravascular electrode lead includes an electrode shaft; a plurality of filaments being made of a conductive, non-biodegradable material, running in longitudinal direction within the electrode shaft and protruding distally beyond a distal end of the electrode shaft, each filament terminating in at least one electrically active area; and a support member being arranged distally from the distal end of the electrode shaft and being dilatable from a compressed state to an radially expanded state, wherein the support member is attached to the filaments and made of a biodegradable material.

Abstract: An implantable pulse generator system includes a nerve stimulation unit providing vagal nerve stimulation (VNS) pulses; an autonomic tone sensor which determines the patient's autonomic status; and a control unit connected to the nerve stimulation unit and the autonomic tone sensor. The control unit controls the nerve stimulation unit to generate VNS with varying intensity, depending on the autonomic status (which is evaluated in a moving window). The control unit gradually increases VNS intensity when the autonomic status indicates a shift toward more sympathetic dominance, and it gradually decreases VNS intensity when the autonomic status indicates a shift toward more parasympathetic dominance, wherein the gradual increase and the gradual decrease of the VNS intensity follow two different paths.

Abstract: System, method, and tool for implanting an electrode cuff. The system can include a cuff and a slider implement, where the cuff is temporarily retained within and/or onto the slider implement by a retainer mechanism during implantation. The cuff can be structured to exhibit a natural rolled shape, but can be resiliently bendable so as to flex from the rolled shape while having a tendency to move back to the rolled shape. The cuff can be releasably secured to a portion of the slider implement, which may include holding the cuff in an unrolled shape. The cuff can then be positioned adjacent the nerve. The retainer mechanism can then be actuated to allow the cuff to advance towards its naturally rolled shape, thereby wrapping around the nerve.

Abstract: A delivery systems for an intravascular electrode lead of an intravascular neurostimulation device, as well as corresponding delivery methods and catheters.

Abstract: A nerve cuff stimulation electrode for cervical VNS is provided and configured to be arranged so as to at least partially surround or enclose one of the vagus nerves. The cuff stimulation electrode has at least two contacts configured to deliver electric stimulation pulses to a vagus nerve. The cuff stimulation electrode further has or may be attached or connected to a tilt sensor, a kinematic sensor, and/or a pulsation sensor configured to generate a signal representative of arterial and venous pressures. The implantable tilt sensor is configured to output a posture signal indicating a patient's posture, thus allowing discrimination between supine and semi-recumbent or erect postures.

Abstract: An implantable medical device including a data communication device that includes a device to alter and/or generate an oscillatory electric field imposed on body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state. The device that alters an oscillatory electric field modulates an impedance of body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state and within an oscillatory electric field. The device that alters an oscillatory electric field includes a device that generates an oscillatory electric field that is phase-synchronized with an oscillatory electric field imposed on body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state.

Abstract: An implantable pulse generator (106) provides electric stimulation pulses for nerve stimulation via a stimulation lead (100) having stimulation electrodes (102, 104). The electric stimulation pulses form a pulse train including (i) an initial selective-arrest phase for the large-diameter fibers in the vicinity of selected electrodes; (ii) followed by a charge-balanced phase where a charge-balanced alternating current (AC) is applied between the same or other selected electrodes; and (iii) a therapy phase where the charge-balanced alternating current (AC) is briefly unbalanced to deliver nerve stimulation therapy pulses, with the pulse train returning to the charge-balanced phase in between therapy pulses.

Abstract: An implantable medical device including a data communication device that includes a device to alter and/or generate an oscillatory electric field imposed on body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state. The device that alters an oscillatory electric field modulates an impedance of body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state and within an oscillatory electric field. The device that alters an oscillatory electric field includes a device that generates an oscillatory electric field that is phase-synchronized with an oscillatory electric field imposed on body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state.

Abstract: An implantable medical device including a data communication device that includes a device to alter and/or generate an oscillatory electric field imposed on body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state. The device that alters an oscillatory electric field modulates an impedance of body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state and within an oscillatory electric field. The device that alters an oscillatory electric field includes a device that generates an oscillatory electric field that is phase-synchronized with an oscillatory electric field imposed on body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state.

Abstract: An implantable pulse generator system includes a stimulation unit delivering vagal nerve stimulation pulses, an activity sensor determining an exertion level of the user and generating a signal representing metabolic demand, an autonomic tone sensor determining an autonomic status of the user and generating a signal representing autonomic status, and a control unit in communication with the foregoing components, and which is adapted to control the stimulation unit depending on both the signal representing metabolic demand and the signal representing autonomic status.

Abstract: An intravascular electrode lead and an intravascular stimulation device including the same. The intravascular electrode lead includes an electrode shaft; a plurality of filaments being made of a conductive, non-biodegradable material, running in longitudinal direction within the electrode shaft and protruding distally beyond a distal end of the electrode shaft, each filament terminating in at least one electrically active area; and a support member being arranged distally from the distal end of the electrode shaft and being dilatable from a compressed state to an radially expanded state, wherein the support member is attached to the filaments and made of a biodegradable material.

Abstract: A nerve cuff stimulation electrode for cervical VNS is provided and configured to be arranged so as to at least partially surround or enclose one of the vagus nerves. The cuff stimulation electrode has at least two contacts configured to deliver electric stimulation pulses to a vagus nerve. The cuff stimulation electrode further has or may be attached or connected to a tilt sensor, a kinematic sensor, and/or a pulsation sensor configured to generate a signal representative of arterial and venous pressures. The implantable tilt sensor is configured to output a posture signal indicating a patient's posture, thus allowing discrimination between supine and semi-recumbent or erect postures.

Abstract: A sterilizable container for an implantable medical device, including an inner packaging and an outer packaging that encloses said inner packaging. The inner packaging includes an enclosure and at least two electric contacts that are arranged inside the enclosure and that are placed so as to contact an implantable medical device electrode when such implantable medical device is placed in said inner packaging. Each electric contact of said inner packaging is electrically connected to a respective planar electrode arranged at or close to an outer surface of said inner packaging so as to provide a capacitive communication interface. The inner packaging further includes fixture means that are configured to securely hold an implantable medical device in place to ensure electric contact between the at least two electric contacts and a respective implantable medical device electrode when such implantable medical device is placed in the inner packaging.

Abstract: An implantable medical device including a data communication device that includes a device to alter and/or generate an oscillatory electric field imposed on body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state. The device that alters an oscillatory electric field modulates an impedance of body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state and within an oscillatory electric field. The device that alters an oscillatory electric field includes a device that generates an oscillatory electric field that is phase-synchronized with an oscillatory electric field imposed on body tissue surrounding the implantable medical device when the implantable medical device is in its implanted state.