Abstract: A catheter (e.g., high-density mapping catheter) and related catheter system is described herein. The catheter includes an elongated catheter shaft, and an electrode assembly. The electrode assembly includes a first spline assembly, a second spline assembly, and a distal coupler assembly. Each of the spline assembly includes a distal portion and spline assembly electrodes distributed along the spline assembly. The distal coupler assembly includes a base member and a distal electrode. The base member defines an opening configured to receive and accommodate the distal portion of the second spline assembly. The distal electrode is configured to be mounted to the base member to secure the distal portion of the second spline assembly within the opening. The distal electrode can be configured for cardiac mapping, tissue ablation, and/or bipolar pacing.

Abstract: Magnetic position sensors include features to enhance performance and durability. In many embodiments, a magnetic position sensor includes a magnetically permeable core and a coil. The core has a central axis and a core length along the central axis. The coil is configured to generate output an electric signal in response to a magnetic field. The coil has a coil length along the central axis that is less than the core length. In some embodiments, a magnetic position sensor includes a magnetically permeable core, a coil, a pair of signal wires, and a third wire. The coil is configured to output an electric signal in response to a magnetic field. The pair of signal wires is connected to and extends from the coil. The third wire extends along a length of the pair of signal wires and is configured to reinforce the pair of signal wires.

Abstract: A position sensor used in medical devices for use with medical positioning systems. The position sensor includes a core (80) having a body and one or more projections (841,842) extending from the body, wherein the core comprises a high-permeability material. The position sensor further includes a coil (74) surrounding the body, wherein the coil is configured to generate a voltage when subject to a magnetic field. The one or more projections extending from the body of the core are configured to concentrate the magnetic field into the coil and increase the voltage. Thus, various core designs are described which have projections which may increase the electrical and/or mechanical integrity of the position sensor and/or which may also induce magnetic flux flow within the position sensor thereby increasing the signals generated by the position sensor.

Abstract: A steerable sheath includes an inner liner extending from a proximal end to a distal end of the steerable sheath. The inner liner includes a non-deflectable portion and a deflectable portion. The steerable sheath includes a first pull wire positioned along a first helical path around the circumference of the inner liner from a proximal end to a distal end of the non-deflectable portion of the inner liner and along a first straight path from a proximal end of the deflectable portion to a distal end of the deflectable portion. The steerable sheath includes a second pull wire positioned along a second helical path around the circumference of the inner liner from the proximal end to the distal end of the non-deflectable portion and along a second straight path from the proximal end of the deflectable portion to the distal end of the deflectable portion.

Abstract: A splittable sheath for an implantable medical device can include a jacket having an outer diameter and an inner diameter. A lumen can be defined by the inner diameter and extended from a proximal end to a distal end of the jacket. An electrode can be located at the distal end of the jacket. A signal wire can be disposed within the jacket and can be electrically coupled to the electrode. A rail can be configured to shield the signal wire from a cut path of a sheath splitter. In some examples, the sheath can further include a second rail. For instance, the signal wire can be located between a first rail and a second rail along the length of the sheath. The cut path can be located between the first rail and the second rail on a radially opposing side of the sheath from the signal wire.

Abstract: Various embodiments of the present disclosure can include a high-density electrode catheter. In some embodiments, the high-density electrode catheter can include a catheter shaft including a proximal end and a distal end, the catheter shaft defining a catheter shaft longitudinal axis. In some embodiments, the high-density electrode catheter can include a shaft magnetic position sensor disposed along a distal portion of the catheter shaft. In some embodiments, the high-density electrode catheter can include a flexible tip portion located adjacent to the distal end of the catheter shaft, wherein the flexible tip portion includes a flexible framework. In some embodiments, the high-density electrode catheter can include a plurality of electrodes disposed on the flexible framework. In some embodiments, the high-density electrode catheter can include a tip magnetic position sensor disposed on a portion of the flexible framework.

Abstract: Aspects of the present disclosure are directed to an intravascular catheter with a coupler near a distal end which facilitates precise positioning of an end effector and one or more magnetic localization sensors.

Abstract: A medical device includes an elongate shaft extending along a shaft longitudinal axis and includes a shaft proximal portion and a shaft distal portion. The medical device can include an electrode disposed on the shaft distal portion. The medical device can include a first conductor lead and a second conductor lead, each of the conductor leads electrically being coupled to the electrode. A thermocouple junction formed via a thermocouple conductor can be electrically coupled to the electrode and the first conductor lead.

Abstract: Aspects of the instant disclosure relate to an electrophysiological catheter system for performing diagnostics and therapies within a cardiac muscle; more specifically, to a wireless force sensor, mounted to an external surface of a catheter shaft, that detects force exerted on a catheter tip and wirelessly transmits a signal indicative of the sensed force to a wireless transceiver in proximity thereto.

Abstract: A position sensor used in medical devices for use with medical positioning systems. The position sensor includes a core (80) having a body and one or more projections (841,842) extending from the body, wherein the core comprises a high-permeability material. The position sensor further includes a coil (74) surrounding the body, wherein the coil is configured to generate a voltage when subject to a magnetic field. The one or more projections extending from the body of the core are configured to concentrate the magnetic field into the coil and increase the voltage. Thus, various core designs are described which have projections which may increase the electrical and/or mechanical integrity of the position sensor and/or which may also induce magnetic flux flow within the position sensor thereby increasing the signals generated by the position sensor.

Abstract: A steerable sheath includes an inner liner extending from a proximal end to a distal end of the steerable sheath. The inner liner includes a non-deflectable portion and a deflectable portion. The steerable sheath includes a first pull wire positioned along a first helical path around the circumference of the inner liner from a proximal end to a distal end of the non-deflectable portion of the inner liner and along a first straight path from a proximal end of the deflectable portion to a distal end of the deflectable portion. The steerable sheath includes a second pull wire positioned along a second helical path around the circumference of the inner liner from the proximal end to the distal end of the non-deflectable portion and along a second straight path from the proximal end of the deflectable portion to the distal end of the deflectable portion.

Abstract: Aspects of the present disclosure are directed to an intravascular catheter with a coupler near a distal end which facilitates precise positioning of an end effector and one or more magnetic localization sensors.

Abstract: Medical devices with radiopaque three dimensional filtration matrices provide for improved visualization of the device within a vessel. In some embodiments, the three dimensional filtration matrix comprises fibers, such as surface capillary fibers. Visualization of the three dimensional filtration matrix provides for an evaluation of the proper deployment of the three dimensional filtration matrix. Radiopaque surface capillary fibers can be advantageously incorporated into other medical devices. Radiopaque surface capillary fibers can be formed by extrusion of a radiopaque polymer or polymer composite.

Abstract: A catheter incorporating an insert molded tip and an improved method of manufacture that is simple, efficient, and significantly reduces current scrap rates for soft tip attachment to catheters. One catheter shaft embodiment includes a counterbored distal portion having anchor holes through the wall of the catheter body in this distal portion. In another embodiment, the catheter shaft has a reduced diameter portion including anchor holes. In yet another embodiment the catheter shaft has external longitudinal and external grooves. The tip is injection molded onto the body with tip material filling the counterbore, reduced diameter portion, anchor holes, and grooves to form integral anchors to secure the tip.