Abstract: Percutaneous transvenous defibrillator and/or pacing devices with integrated cardiac assist devices and method of use. In some embodiments, a device may comprise a shared catheter, a defibrillator assembly, an automated external defibrillator (AED) and a cardiac assist assembly, wherein the defibrillator assembly includes at least two defibrillation coils in communication with the AED and wherein the defibrillator assembly and the cardiac assist assembly use the shared catheter for percutaneous and intravenous implantation into a patient. In some embodiments, a device may comprise a shared catheter, a pacing assembly, a pacing controller and a cardiac assist assembly, wherein the pacing assembly includes at least two electrodes in communication with the pacing controller, and wherein the pacer assembly and the cardiac assist assembly use the shared catheter for percutaneous and intravenous implantation into a patient.

Abstract: Subcutaneous implantable string shaped defibrillator for providing cardiac resynchronization therapy (CRT), including a flexible elongated body, at least two defibrillation leads, at least one sensor, at least two transition units and at least one epicardial lead, the defibrillation leads for providing at least one cardioversion defibrillation shock, the sensor being positioned on at least one of the defibrillation leads, for determining at least one metric of a heart, the transition units for respectively coupling the defibrillation leads to opposite ends of the elongated body, and the epicardial lead, coupled with the elongated body via at least one of the transition units, for providing at least one CRT pulse, the elongated body including a plurality of linked units, the linked units encapsulating at least one capacitor, at least one power source and a processor, wherein the processor provides at least one signal to the epicardial lead for providing the CRT pulse.

Abstract: An automated wearable belt cardiac defibrillator (BCD) for wearing by a subject, comprising: at least two patches adapted for adhering to the subject each comprising a defibrillation electrode and an ECG sensor; and a BCD controller connected to each of the patches, wherein the patches comprise an adhesive adapted for long-term adhering of the patches to the subject, wherein the adhesive is a biocompatible adhesive, wherein the patches and adhesive are adapted for movement of the subject while the patches are adhered to the subject, wherein the patches are replaceable, wherein the controller is housed in a belt for wearing by the subject, wherein the belt is adapted for being flexible, wherein the adaptation for being flexible comprises a plurality of compartments for housing components of the controller, wherein a method for usage of the BCD comprises: following completion of an operational period, positioning of the patches to alternative locations on the subject wherein each of the alternate locations repr

Abstract: Pill-sized pacemaker system including a pill-size pacemaker and a lead connector, the pacemaker having a distal end including a first screw hook and a proximal end including a first magnetic coupler, the lead connector having a distal end including a second screw hook and a proximal end including a second magnetic coupler, the first and second magnetic couplers being disc-shaped, each including at least one depth-wise electrode, wherein the first screw hook is for screwing the pacemaker to inner heart tissue and for sensing at least one signal from the inner heart tissue, the second screw hook is for screwing the lead connector to inner heart tissue and for sensing at least one signal from the inner heart tissue, and the pacemaker and the lead connector are electrically coupled via each depth-wise electrode of the first and second magnetic couplers when the first and second magnetic couplers are magnetically coupled.

Abstract: Subcutaneous implantable medical device (IMD) recharging system, including a flexible rechargeable subcutaneous IMD and a charger transmitter, the flexible rechargeable subcutaneous IMD implanted in a patient and including at least one receiver antenna and at least one rechargeable battery, the charger transmitter including at least one transmitter antenna and a modulator, the charger transmitter for providing electromagnetic (EM) radiation to the receiver antenna wirelessly for recharging the rechargeable battery, the transmitter antenna being encased in a structure for temporarily coupling the transmitter antenna to the skin of the patient and the modulator being for modulating the EM radiation and for simultaneously transmitting programming information to the flexible rechargeable subcutaneous IMD as modulated EM radiation.

Abstract: Flexible semi-hermetic implantable medical device (IMD) structure, including a flexible device body, at least one flexible lead and at least one respective transition unit, for respectively coupling each flexible lead to the flexible device body, the flexible device body including a plurality of hermetically sealed components, at least one electrical cable harness and an external flexible polymer structure, each one of the hermetically sealed components including at least one hermetically sealed electrical connection and at least some of the hermetically sealed components including at least one separation dome, the electrical cable harness for electrically and mechanically coupling the plurality of hermetically sealed components together and the external flexible polymer structure for encapsulating the hermetically sealed components, the electrical cable harness and the respective transition unit.

Abstract: A system for superimposing virtual anatomical landmarks on an image includes a medical positioning system (MPS) for producing location readings with respect to points within a region of interest in accordance with an output of a location sensor disposed in a medical device. A coordinate system of the MPS is registered with an image coordinate system. A control unit receives a signal from a user to record a location reading when the medical device is at a desired point in the region of interest where the user desires to place a virtual landmark, modifies the recorded location reading for motion compensation, transforms the motion-compensated location reading from the MPS coordinate system to the image coordinate system to produce a target location, and then superimposes a representation of the virtual landmark on the image at the target location.

Abstract: An implantable rechargeable telemetry device (IRTD) for injection into a subject comprising: an ECG monitor in electrical communication with an electrode and adapted for collecting ECG data of a subject, a rechargeable battery adapted for powering the IRTD; and a wireless charging receiver adapted to receive charging current from a charging device to recharge the battery, wherein the collected ECG data is continuously monitored ECG data and wherein the IRTD further comprises a wireless communication device adapted for continuous transmission of the collected continuously monitored ECG data to an external computing device.

Abstract: A method for registering a three dimensional (3D) coordinates system with a Medical Positioning System (MPS) coordinate system and with a two dimensional (2D) coordinate system, includes acquiring at least one 2D image of a volume of interest, the volume of interest including at least one tubular organ within the body of a patient. The 2D image is associated with the 2D coordinate system, and a plurality of MPS points is acquired, within the at least one tubular organ. The MPS points are associated with the MPS coordinate system, the MPS coordinate system being registered with the 2D coordinate system. A 3D image model is extracted of the at least one tubular organ form a pre-acquired 3D image of the volume of interest.

Abstract: Subcutaneous implantable string shaped defibrillator for providing cardiac resynchronization therapy (CRT), including a flexible elongated body, at least two defibrillation leads, at least one sensor, at least two transition units and at least one epicardial lead, the defibrillation leads for providing at least one cardioversion defibrillation shock, the sensor being positioned on at least one of the defibrillation leads, for determining at least one metric of a heart, the transition units for respectively coupling the defibrillation leads to opposite ends of the elongated body, and the epicardial lead, coupled with the elongated body via at least one of the transition units, for providing at least one CRT pulse, the elongated body including a plurality of linked units, the linked units encapsulating at least one capacitor, at least one power source and a processor, wherein the processor provides at least one signal to the epicardial lead for providing the CRT pulse.

Abstract: An encapsulation configuration for electronic components in a flexible implantable medical device, including at least one set of folded circuit boards and a filler material, the set of folded circuit boards including a plurality of circuit boards and a plurality of connection cables, each one of the circuit boards including at least one electronics component, each one of the circuit boards having a generally rectangular shape, the connection cables electrically coupling adjacent ones of the circuit boards and the circuit boards being folded over one another in a pleated manner, the filler material surrounding the set of folded circuit boards, the filler material and the set of folded circuit boards together having a cylindrical shape, the set of folded circuit boards being positioned lengthwise in the cylindrical shape and the electronics component being positioned on the set of folded circuit boards to achieve optimal volume consumption in the electronics encapsulation.

Abstract: Flexible implantable subcutaneous heart device (HD) structure, including a flexible device body, at least one flexible lead and at least one respective transition unit, the transition unit for respectively coupling each flexible lead to the flexible device body, the flexible device body including a plurality of inner components and a respective plurality of hollow outer units, the hollow outer units for encasing and protecting the inner components, each one of the hollow outer units including at least one hollow rigid element and a hollow flexible element, the hollow flexible element coupled with the hollow rigid element for enabling the outer unit a degree of flexibility, wherein the hollow flexible element is covered with a covering and wherein the flexible device body is covered with a polymer.

Abstract: A method for registering a three dimensional (3D) coordinates system with a Medical Positioning System (MPS) coordinate system and with a two dimensional (2D) coordinate system, includes acquiring at least one 2D image of a volume of interest, the volume of interest including at least one tubular organ within the body of a patient. The 2D image is associated with the 2D coordinate system, and a plurality of MPS points is acquired, within the at least one tubular organ. The MPS points are associated with the MPS coordinate system, the MPS coordinate system being registered with the 2D coordinate system. A 3D image model is extracted of the at least one tubular organ form a pre-acquired 3D image of the volume of interest.

Abstract: System for registering a first image with a second image, the system including a first medical positioning system for detecting a first position and orientation of the body of a patient, a second medical positioning system for detecting a second position and orientation of the body, and a registering module coupled with a second imager and with the second medical positioning system, the first medical positioning system being associated with and coupled with a first imager, the first imager acquiring the first image from the body, the first imager producing the first image by associating the first image with the first position and orientation, the second medical positioning system being associated with and coupled with the second imager, the second imager acquiring the second image and associating the second image with the second position and orientation, the registering module registering the first image with the second image, according to the first position and orientation and the second position and orienta

Abstract: Subcutaneous implantable medical device (IMD) recharging system, including a flexible rechargeable subcutaneous IMD and a charger transmitter, the flexible rechargeable subcutaneous IMD implanted in a patient and including at least one receiver antenna and at least one rechargeable battery, the charger transmitter including at least one transmitter antenna and a modulator, the charger transmitter for providing electromagnetic (EM) radiation to the receiver antenna wirelessly for recharging the rechargeable battery, the transmitter antenna being encased in a structure for temporarily coupling the transmitter antenna to the skin of the patient and the modulator being for modulating the EM radiation and for simultaneously transmitting programming information to the flexible rechargeable subcutaneous IMD as modulated EM radiation.

Abstract: A method for determining and graphically marking a position within a lumen of the body of a patient indicative of occlusion includes providing a user interface, using a processor, configured to allow a user to select an occlusion percentage threshold, determining, using the processor, a percentage of occlusion in the lumen, comparing, using the processor, the determined percentage of occlusion with the selected occlusion percentage threshold and identifying a region of the lumen that is occluded more than the selected occlusion percentage threshold, and designating, using the processor, the identified region on an image of the lumen with at least one mark.

Abstract: Flexible subcutaneous implantable medical device (IMD), including an elongated and flexible body, a plurality of electronic components, at least one rechargeable battery, at least one antenna, at least one lead and at least one transition unit, the antenna for receiving and transmitting electromagnetic radiation and the lead for providing an electric shock, wherein the elongated and flexible body is structured from a plurality of units, wherein a first one of the plurality of units encapsulates the rechargeable battery, wherein each one of the other plurality of units respectively encapsulates a respective one of the plurality of electronic components, wherein the antenna is positioned in the transition unit, wherein the transition unit is covered with a biocompatible polymer, wherein the antenna receives electromagnetic radiation for recharging the rechargeable battery and wherein the antenna includes a copper coil having a generally cylindrical shape.

Abstract: Flexible semi-hermetic implantable medical device (IMD) structure, including a flexible device body, at least one flexible lead and at least one respective transition unit, for respectively coupling each flexible lead to the flexible device body, the flexible device body including a plurality of hermetically sealed components, at least one electrical cable harness and an external flexible polymer structure, each one of the hermetically sealed components including at least one hermetically sealed electrical connection and at least some of the hermetically sealed components including at least one separation dome, the electrical cable harness for electrically and mechanically coupling the plurality of hermetically sealed components together and the external flexible polymer structure for encapsulating the hermetically sealed components, the electrical cable harness and the respective transition unit.

Abstract: Apparatus for generating an organ timing signal relating to an inspected organ within the body of a patient, including a medical positioning system, and a processor coupled with the medical positioning system, the medical positioning system including at least one reference electromagnetic transducer placed at a reference location, at least one inner electromagnetic transducer attached to a surgical tool inserted in a blood vessel in the vicinity of the inspected organ, and a medical positioning system processor coupled with the reference electromagnetic transducer and the inner electromagnetic transducer, the medical positioning system processor determining the three-dimensional position of the inner electromagnetic transducer, by processing transmitted electromagnetic signals transmitted from one of the reference electromagnetic transducer and the inner electromagnetic transducer with detected electromagnetic signals detected by the other of the reference electromagnetic transducer and the inner electromagne

Abstract: A method for registering a three dimensional (3D) coordinates system with a Medical Positioning System (MPS) coordinate system and with a two dimensional (2D) coordinate system, includes acquiring at least one 2D image of a volume of interest, the volume of interest including at least one tubular organ within the body of a patient. The 2D image is associated with the 2D coordinate system, and a plurality of MPS points is acquired, within the at least one tubular organ. The MPS points are associated with the MPS coordinate system, the MPS coordinate system being registered with the 2D coordinate system. A 3D image model is extracted of the at least one tubular organ form a pre-acquired 3D image of the volume of interest.