Abstract: Sensing devices and methods of implanting sensing devices within an anatomical vessel network of a patient are provided. In one method, a fixation element (e.g., a stent or coil) of the sensing device is expanded into firm contact with a wall of a main anatomical vessel (e.g., a right pulmonary artery), and a stabilization element of the sensing device is placed into contact with a wall of an anatomical vessel branch of the main anatomical vessel. In another method, a first fixation element of the sensing device is expanded into firm contact with the wall of the main anatomical vessel (e.g., a right pulmonary artery) at a longitudinal location proximal to the anatomical vessel branch, and a second fixation element of the sensing device is expanded into firm contact with the wall of the main anatomical vessel at a longitudinal location distal to the anatomical vessel branch.

Abstract: Vasculature closure devices, and systems and methods for their use, are provided. In one or more embodiments, a vasculature closure device (200) includes an expandable support frame (210) deployable within a vessel (10), and a sealing membrane (205) at least partially supported by the support frame (210). Upon expanding the support frame (210) within the vessel (10), the device is configured to intraluminally position the sealing membrane (205) against a puncture site existing in a wall of the vessel. The sealing membrane includes an area of excess membrane (245) configured to facilitate coupling of the sealing membrane to the wall of the vessel.

Abstract: Vasculature closure device delivery systems and methods are provided. In one or more embodiments, a vasculature closure device delivery system for intraluminally positioning a vasculature closure device against a puncture site existing in a wall of a vessel includes a loading tube configured to receive the vasculature closure device therein, a push rod configured to extend through the loading tube and to push the vasculature closure device out of the loading tube and into a lumen of the vessel, and an automatic deployment mechanism configured to detect when the vasculature closure device is positioned at the puncture site and to automatically deploy the vasculature closure device thereabout.

Abstract: Vasculature closure devices, and systems and methods for their use, are provided. In one or more embodiments, a vasculature closure device (200) includes an expandable support frame (210) deployable within a vessel (10), and a sealing membrane (205) at least partially supported by the support frame (210). Upon expanding the support frame (210) within the vessel (10), the device is configured to intraluminally position the sealing membrane (205) against a puncture site existing in a wall of the vessel. The sealing membrane includes an area of excess membrane (245) configured to facilitate coupling of the sealing membrane to the wall of the vessel.

Abstract: Apparatus for positioning at least one sensor in a body lumen, the apparatus including a fixation element, a sensor, and a connecting element that connects the sensor to the fixation element, the connecting element extending at least partially into the lumen so that the sensor is located radially inward from a wall of the lumen.

Abstract: Methods, systems, and apparatus for recharging medical devices implanted within the body are disclosed. An illustrative rechargeable system includes a charging device that includes an elongate shaft having a proximal section and a distal section. The distal section is configured to be delivered to a location within the body adjacent to the implanted medical device. The charging device includes a charging element configured to transmit charging energy to a receiver of the implanted medical device.

Abstract: Vasculature closure devices, and systems and methods for their use, are provided. In one embodiment, the vasculature closure device includes an expandable support frame deployable into a vessel through a puncture site and a sealing membrane at least partially supported by the expandable support frame. The support frame is positioned along a periphery of the sealing membrane. Upon expanding the support frame within the vessel, the support frame is configured to intraluminally push the sealing membrane against the puncture site.

Abstract: Vasculature closure devices, and systems and methods for their use, are provided. In one embodiment, the method includes deploying a vasculature closure device including a support frame and a sealing membrane into a vessel through a puncture site, wherein the support frame is in a collapsed configuration during deployment, and expanding the support frame into an expanded configuration within the vessel such that the sealing membrane is pushed against the puncture site.

Abstract: Vasculature closure devices, and systems and methods for their use, are provided. In one embodiment, the vasculature closure device includes an expandable support frame deployable within a vessel, a sealing membrane at least partially supported by the support frame, and a cross-member support extending across at least a portion of the sealing membrane. Upon expanding the support frame, the device is configured to intraluminally position the sealing membrane against a puncture site existing in a wall of the vessel. The cross-member support includes a flexible wire coupled to the sealing membrane at an intermediate portion of the flexible wire and configured to maintain the sealing membrane against the puncture site.

Abstract: An implantable stimulation system comprises an implantable stimulator and a control device. The control device is configured to transmit acoustic waves to the implantable stimulator, and the implantable stimulator is configured to transform the acoustic waves into electrical current, and generate stimulation energy based on the electrical current. For example, the electrical current can be transformed into electrical energy that can be used to generate the stimulation energy. Or the electrical current can contain signals used to directly or indirectly control the generation of the stimulation energy.

Abstract: Vasculature closure devices, and systems and methods for their use, are provided. In one embodiment, the vasculature closure device includes an expandable support frame deployable within a vessel and a sealing membrane at least partially supported by the expandable support frame. Upon expanding the support frame, the vasculature closure device is configured to intraluminally position the sealing membrane against a puncture site existing in a vessel wall.

Abstract: An implantable medical device comprises a hermetically sealed housing having a housing wall with an interior surface, and an ultrasonic acoustic transducer, the transducer comprising one or more piezoelectric discs fixed to the interior surface of the housing wall, such that the housing wall acts as a diaphragm in response to induced movement by the one or more piezoelectric material discs.

Abstract: Methods, systems, and apparatus for recharging medical devices implanted within the body are disclosed. An illustrative rechargeable system includes a charging device that includes an elongate shaft having a proximal section and a distal section. The distal section is configured to be delivered to a location within the body adjacent to the implanted medical device. The charging device includes a charging element configured to transmit charging energy to a receiver of the implanted medical device.

Abstract: Systems and methods provide intrabody communication using acoustic telemetry. The system includes a first or control implant including a first acoustic transducer, and a second implant including a switch and a second acoustic transducer coupled to the switch. The second acoustic transducer receives acoustic signals from the first acoustic transducer for closing the switch to activate the second implant. The second implant may include a therapeutic device for providing therapy to the patient. For example, the second implant may provide pacing therapy, defibrillation therapy, pain control stimulation, or neuro-stimulation.

Abstract: An implantable stimulation system comprises an implantable stimulator and a control device. The control device is configured to transmit acoustic waves to the implantable stimulator, and the implantable stimulator is configured to transform the acoustic waves into electrical current, and generate stimulation energy based on the electrical current. For example, the electrical current can be transformed into electrical energy that can be used to generate the stimulation energy. Or the electrical current can contain signals used to directly or indirectly control the generation of the stimulation energy.

Abstract: Medical devices, systems, and methods are provided for providing respiratory therapy by electrically stimulating the phrenic nerves and/or the thoracic diaphragm. In one embodiment, at least one electrode is deployed to a position within the patient's airway and placed in proximity to a phrenic nerve or to the diaphragm. The electrode may be attached to a controller housing including a pulse generator using one or more electrical lead or leads or may be in wireless communication with the pulse generator. The controller housing may be implanted at a position within the patient or the controller housing may reside external to the patient.

Abstract: Medical devices, systems, and methods are provided for providing respiratory therapy by electrically stimulating the phrenic nerves and/or the thoracic diaphragm. In one embodiment, at least one electrode is deployed to a position within the patient's airway and placed in proximity to a phrenic nerve or to the diaphragm. The electrode may be attached to a controller housing including a pulse generator using one or more electrical lead or leads or may be in wireless communication with the pulse generator. The controller housing may be implanted at a position within the patient or the controller housing may reside external to the patient.

Abstract: Medical systems and devices are provided. A medical system includes implantable devices and an external device configured for wirelessly interacting with the implantable devices. The external device may be attachable to a patient and be configured for wirelessly communicating with a first implantable device, e.g., using acoustic energy, and wirelessly interacting with a second implantable device, e.g., using non-acoustic energy. The first implantable device may be a diagnostic device, in which case, the external device may wirelessly receive physiological information from the diagnostic device, and the second implantable device may be a therapeutic device, in which case, the external device may wirelessly interact with the therapeutic device to provide or optimize therapy to a patient.

Abstract: Vasculature closure devices, and systems and methods for their use, are provided. In one embodiment, the vasculature closure device includes an expandable support frame deployable within a vessel and a sealing membrane at least partially supported by the expandable support frame. Upon expanding the support frame, the vasculature closure device is configured to intraluminally position the sealing membrane against a puncture site existing in a vessel wall.

Abstract: Devices and methods are provided which include access port devices for implantation through a tissue wall of a lumen of patient's body and for containing electrical leads therein. An implantable port device includes a body with a first end having a first opening and an opposed second end having a second opening, and a channel extending from between and operably connecting the first opening and the second opening; a first retaining member extending radially from the first end of the body; and a second retaining member spaced apart from the first retaining member, the second retaining member being closer than the first retaining member to the second end of the body, and extending radially from the second end of the body. The first retaining member and the second retaining member are configured to cooperatively engage opposing sides of the tissue wall about edges of an aperture through the tissue wall to secure the body within the aperture.