A balloon catheter includes a flexible outer cylinder shaft, a holding member connected to a proximal end portion of the outer cylinder shaft, a sealing member that maintains liquid tightness incorporated in the holding member, a flexible inner cylinder shaft, a tube having a Rockwell hardness of R 115 or more, a flexural modulus of 3.0 to 4.5 GPa, and a thickness of 0.06 to 0.12 mm, a push-in member connected to a proximal end portion of the inner cylinder shaft, a pull-out prevention member connected to the push-in member, and a balloon composed of an elastic material and connected to each of the distal end portion of the outer cylinder shaft and the proximal end portion of the inner cylinder shaft, wherein the tube is inserted over the inner cylinder shaft over an area thereof except for a connecting portion between the balloon and the inner cylinder shaft.

A catheter with basket-shaped electrode assembly with spines configured for hyper-flexing in a predetermined, predictable manner when a compressive force acts on the assembly from either its distal end or its proximal end. At least one spine has at least one region of greater (or hyper) flexibility that allows the electrode assembly to deform, for example, compress, for absorbing and dampening excessive force that may otherwise cause damage or injury to tissue wall in contact with the assembly, without compromising the structure and stiffness of the remaining regions of the spine, including its distal and proximal regions. The one or more regions of greater flexibility in the spine allow the spine to flex into a generally V-shape configuration or a generally U-shape configuration.

A device having an optical element with a conductive coating. The device may include an optical element, a conductive material and at least one connector. The conductive material is disposed on at least a portion of the optical element. The optical element, for example, may be an object lens of an endoscope or an optical coupler. The connectors (acting as terminal(s)) are capable of providing energy (such as electrical energy) to the conductive material. In one aspect, the conductive material is an optically transparent material. Advantageously, the device may allow visualization of an objectsuch as body tissue or other matterconcurrent with the application of energy to the object via the conductive coating. This allows the user to observe the alteration of tissue and other matter in real time as the energy is delivered.

A system for mechanical cutting and radiofrequency (RF) treatment of bone and soft tissue includes a probe and an RF power supply. The probe includes an elongated sleeve having a longitudinal axis, a proximal end and a distal end. A cutting member formed of a dielectric material is mounted on the elongated sleeve, and a metal electrode is attached to a surface of the cutting member and configured to deliver RF current. The RF power supply generates current having a pulsed RF waveform and may be connected to the metal electrode to deliver the current having the pulsed RF waveform to the tissue. The use of a pulsed RF waveform reduces a thermal stress on the dielectric material at the interface of the metal electrode and the dielectric material of the cutting member.

An example medical system for ablating and occluding the left atrial appendage is disclosed. The example system includes a catheter sized and shaped for vascular access and including an elongate body extending between a proximal end and a distal end. A first expandable member may be positioned near the distal end of the elongate body and have a first region configured to permeate a liquid therethrough. A first set of one or more electrodes may be arranged within the first expandable member and may be configured to deliver energy to the tissue region. An occlusive implant may be releasably secured to the distal end of the elongate body.

Tumors in portions of a subject's body that have a longitudinal axis (e.g., the torso, head, and arm) can be treated with TTFields by affixing first and second sets of electrodes at respective positions that are longitudinally prior to and subsequent to a target region. An AC voltage with a frequency of 100-500 kHz is applied between these sets of electrodes. This imposes an AC electric field with field lines that run through the target region longitudinally. The field strength is at least 1 V/cm in at least a portion of the target region. In some embodiments, this approach is combined with the application of AC electric fields through the target region in a lateral direction (e.g., front to back and/or side to side) in order to apply AC electric fields with different orientations to the target region.

Catheter apparatuses, systems, and methods for achieving renal neuromodulation by intravascular access are disclosed herein. One aspect of the present technology, for example, is directed to a treatment device having a multi-electrode array configured to be delivered to a renal blood vessel. The array is selectively transformable between a delivery or low-profile state (e.g., a generally straight shape) and a deployed state (e.g., a radially expanded, generally spiral/helical shape). The multi-electrode array is sized and shaped so that the electrodes or energy delivery elements contact an interior wall of the renal blood vessel when the array is in the deployed (e.g., spiral/helical) state. The electrodes or energy delivery elements are configured for direct and/or indirect application of thermal and/or electrical energy to heat or otherwise electrically modulate neural fibers that contribute to renal function.

A cryoablation catheter includes an inner lumen and an inflatable balloon surrounding the inner lumen. An inflow pipe is disposed within the inflatable balloon and is configured to introduce a refrigerant into the balloon. A thermocouple wire is disposed within the inflatable balloon and positioned adjacent the inflow pipe. The thermocouple wire is configured to measure an internal temperature of the balloon. The cryoablation catheter further includes an isolation guide disposed within the inflatable balloon. The isolation guide includes a central bore configured to receive the inner lumen, an inflow bore configured to receive the inflow pope, and a thermocouple bore configured to receive the thermocouple wire. The thermocouple bore is spaced from the inflow bore along the isolation guide.

A medical device for cutting bone and soft tissue includes a shaft having a rotating component with a distal working end. A cutting member is carried on the working end of the rotating component and a motor rotates the rotating component. The cutting member has a ceramic body with cutting edges, and the ceramic body is formed of a ceramic composite including alumina and zirconia, wherein the alumina has a grain size ranging between 0.5-1.5 microns and the zirconia has a grain size ranging between 0.1-1.0 micron. The alumina grain shape and zirconia grain shape are non-elongated.

An electrosurgical handpiece is provided that includes a squeezable handle. The squeezable handle has a back grip and a finger grip that can be squeezed to actuate electrosurgical handpiece. The back grip and the finger grip are connected by a lower malleable region that has an elasticity greater than the remainder of the squeezable handle.