Abstract: The subject of this disclosure includes systems, devices and methods to treat a predetermined patient population for paroxysmal atrial fibrillation, the method including ablating tissue of one or more targeted pulmonary veins with one or more of a plurality of the electrodes of an independently controlled multi-electrode radiofrequency balloon catheter, the balloon catheter comprising the plurality of electrodes for radiofrequency ablation that are independently controllable; determining a predictor, based on ablation parameters of the balloon catheter, of single shot pulmonary vein isolation (PVI) success rate; and achieving, based on the predictor and step of ablating tissue, a single shot isolation PVI success rate in the isolation of all targeted pulmonary veins for the predetermined patient population.

Abstract: A medical probe includes a hollow guidewire, a balloon, and a magnetic position sensor. The hollow guidewire is configured for insertion into a channel of an organ of a patient. The balloon is fixed to a distal end of the hollow guidewire, is configured to be inserted into the channel using the hollow guidewire, and is further configured to be inflated by pumping of fluid through the hollow guidewire. The magnetic position sensor is fitted at the distal end of the hollow guidewire.

Abstract: A medical tool for use with an electromagnetic navigation system includes a catheter configured to be navigated within patient anatomy and at least one electromagnetic sensor, disposed at the catheter, configured to generate electrical signals indicative of a location of the catheter in response to receiving at least one magnetic field. The medical tool also includes a sheath configured to receive the catheter, a first electromagnetic sensor and a second electromagnetic sensor, disposed at a first region of the sheath, each configured to generate electrical signals indicative of a location of the sheath in response to receiving the at least one magnetic field and a third electromagnetic sensor, disposed at a second region of the sheath spaced from the first region, configured to generate electrical signals indicative of a location of the sheath in response to receiving the at least one magnetic field.

Abstract: A medical probe includes a shaft, an expandable membrane and a probe maneuvering assembly (PMA). The shaft is configured for insertion into a cavity of an organ of a patient. The PMA is located inside the expandable membrane and includes a first elastic element, which is fitted along a longitudinal axis of the PMA and is configured to expand the membrane by shortening the PMA, and to collapse the membrane by elongating the PMA. The PMA further includes a second elastic element, which surrounds at least a portion of the first elastic element and is configured to deflect the membrane relative to the longitudinal axis.

Abstract: A medical probe includes a tubular distal end section, which is configured to be inserted into a cavity of a patient, and includes (a) a visually guiding object disposed over a perimeter of the distal end section, and (b) a magnetic field sensor including two sensor coils aligned non-parallel with each other, the sensor attached to the distal end section, and having:(i) a first axis of symmetry, of one of the coils, which is aligned perpendicular to a central longitudinal axis of the distal end section, and (ii) a second axis of symmetry, of the remaining coil, which is aligned perpendicular to the central longitudinal axis of the distal end section and not parallel to the first axis of symmetry.

Abstract: A catheter apparatus, including an elongated deflectable element, a distal assembly, a force sensor disposed between the elongated deflectable element and the distal assembly, and comprising a spring including a tube with at least one helical cut extending around a circumference of the tube, the at least one helical cut including deviations extending in a longitudinal direction of the tube, the deviations being configured to prevent overstretching and overbending of the spring.

Abstract: One embodiment includes a catheter apparatus, including an elongated deflectable element including a distal end, a coupler connected to the distal end, a pusher including a distal portion, and configured to be advanced and retracted through the deflectable element, a nose connector connected to the distal portion, and including a distal receptacle having an inner surface and a distal facing opening, and an expandable assembly including flexible polymer circuit strips, each strip including electrodes disposed thereon, the strips being disposed circumferentially around the distal portion of the pusher, with first ends of the strips being connected to the coupler and second ends of the strips including respective hinges entering the distal facing opening and connected to the inner surface of the distal receptacle, the strips being configured to bow radially outward when the pusher is retracted expanding the expandable assembly from a collapsed form to an expanded form.

Abstract: A catheter has a multifunctional “virtual” tip electrode with a porous substrate and a multitude of surface microelectrodes. The surface microelectrodes are in close proximity to each other and in a variety of configurations so as to sense tissue for highly localized intracardiac signal detection, and high density local electrograms and mapping. The porous substrate allows for flow of conductive fluid for ablating tissue. The surface microelectrodes can be formed via a metallization process that allows for any shape or size and close proximity, and the fluid “weeping” from the porous substrate provides more uniform irrigation in the form of a thin layer of saline. The delivery of RF power to the catheter tip is based on the principle of “virtual electrode,” where the conductive saline flowing through the porous tip acts as the electrical connection between the tip electrode and the heart surface.

Abstract: A catheter having a catheter shaft that has a more uniform construction throughout a length of the catheter shaft and is able to provide more than one deflection curvature. The catheter shaft includes a flexible outer tubular member, and a less flexible inner tubular member extending through the outer tubular member in a proximal section of the catheter shaft, wherein the inner tubular member is afforded longitudinal movement relative to the outer tubular member. The catheter also includes at least one puller wire extending through the inner tubular member to deflect a distal deflection section of the catheter shaft, wherein the longitudinal movement of the inner tubular member relative to the outer tubular member enables an operator to select and set a deflection curvature of the distal deflection section.

Abstract: A medical probe includes a shaft and an expandable balloon. The shaft is configured for insertion into an organ of a patient. The expandable balloon is coupled to a distal end of the shaft, with the expandable balloon including: (a) an expandable membrane having an outer surface and an inner surface, wherein the expandable membrane is configured to be expanded from a collapsed shape to a balloon shaped member, (b) a plurality of electrodes disposed on the outer surface of the expandable membrane, (c) one or more wires connected to the plurality of electrodes, the wires extending from the distal end to the electrode, (d) and an expandable cover that encapsulates the wires between the expandable cover and the expandable membrane so that the wires are constrained between the cover and the expandable membrane but the electrodes are exposed to ambient environment.

Abstract: A method includes receiving two or more surface representations of at least a portion of an organ of a patient. The two or more received surface representations are registered one with the other. One of the surface representations is selected as a base map. A draggable geodesic region is generated for at least one of the two or more surface representations not selected as a base map, wherein the geodesic region is configured to follow varying anatomy as the region is dragged over the base map. The draggable geodesic region is overlaid on the base map to generate a mixed multilayer representation, and the mixed multilayer representation is presented to a user.

Abstract: A medical probe for insertion has at least one distal electrode coupled to an energy source to apply energy to tissue inside the body. A plurality of apertures are formed in the electrode. A fluid-directing assembly is disposed in the distal section of the probe having an axial channel that is in fluid communication with at least one trans-axial channel disposed at right angles to the axial channel and leading to an exterior of the assembly. A blocking terminus is disposed forward of the at least one trans-axial channel that prevents irrigation fluid from flowing axially in a forward direction so that the fluid flows outwardly into the lumen of the electrode in at least one trans-axial direction.

Abstract: An apparatus includes a flexible electrically-insulating substrate including an inner surface and an outer surface. The substrate is shaped to define multiple channels passing between the inner surface and the outer surface, at least some of the channels being concave channels. The apparatus further includes an outer layer of an electrically-conducting metal covering at least part of the outer surface, an inner layer of the electrically-conducting metal covering at least part of the inner surface, and respective columns of the electrically-conducting metal that fill the channels such as to connect the outer layer to the inner layer.

Abstract: A catheter includes an insertion tube, a flexible substrate and one or more electrical devices. The insertion tube is configured for insertion into a patient body. The flexible substrate is configured to wrap around a distal end of the insertion tube and includes electrical interconnections. The electrical devices are coupled to the flexible substrate and are connected to the electrical interconnections.

Abstract: A contact force sensor is constructed using a spring in which a resilient member is interposed between two contacting elements. Extensions connected to the resilient member are in contact with the elements. A force applied to at least one of the elements causes a deformation of the spring that correlates with a displacement of the elements relative to one another.

Abstract: A distal-end assembly of a medical device, the distal-end assembly includes a flexible substrate and electrical conductors. The flexible substrate is configured to be coupled to a distal end of an insertion tube. The electrical conductors are disposed on the flexible substrate and are shaped to form: (i) one or more electrodes, configured to exchange electrical signals with a proximal end of the medical device, and (ii) one or more printed filters, which are disposed adjacently to at least one of the electrodes and are configured to filter signals in a predefined frequency range from the electrical signals exchanged between the at least one of the electrodes and the proximal end.

Abstract: A catheter having a catheter shaft that has a more uniform construction throughout its length and is able to provide more than one deflection curvature. The catheter shaft includes a flexible outer tubular member, and a less flexible inner tubular member extending through the outer tubular member in a proximal section of the catheter shaft, wherein the inner tubular member is afforded longitudinal movement relative to the outer tubular member. The catheter also includes at least one puller wire extending through the inner tubular member to deflect a distal deflection section of the catheter shaft, wherein longitudinal movement of the inner tubular member relative to the outer tubular member enables an operator to select and set a deflection curvature of the distal deflection section.

Abstract: Medical apparatus includes one or more magnetic field generators, which are configured to generate magnetic fields within a body of a patient. An invasive probe includes an insertion tube having a distal end, which is configured for insertion into the body, and a plurality of flexible splines configured to be deployed from the distal end of the insertion tube. Each spline includes a flexible, multilayer circuit board and a conductive trace that is formed in at least one layer of the circuit board and is configured to define one or more coils, which are disposed along a length of the spline and output electrical signals in response to the magnetic fields. A processor is coupled to receive and process the electrical signals output by the coils in order to derive respective positions of the flexible splines in the body.

Abstract: A method includes, in a processor, receiving signals from (i) a first position sensor disposed on a shaft of a catheter, and (ii) a second position sensor disposed on a distal end of a sheath of the catheter. Based on the signals received from the first position sensor and the second position sensor, an event is detected in which an expandable distal-end assembly of the catheter is being withdrawn into the sheath while still at least partially expanded. A responsive action is initiated in response to detecting the event.

Abstract: A medical probe includes a hollow guidewire, a balloon, and a magnetic position sensor. The hollow guidewire is configured for insertion into a channel of an organ of a patient. The balloon is fixed to a distal end of the hollow guidewire, is configured to be inserted into the channel using the hollow guidewire, and is further configured to be inflated by pumping of fluid through the hollow guidewire. The magnetic position sensor is fitted at the distal end of the hollow guidewire.