A guidewire for a medical device is disclosed. The guidewire includes an elongate body, a proximal connector assembly, a corewire, and a sensor assembly. The body has an annular wall that defines an interior lumen. The proximal connector assembly is coupled to the body and is configured for connection to a medical positioning system. The corewire extends through the lumen. The sensor assembly located on a distal end of the corewire is electrically connected to the proximal connector assembly. The sensor assembly is configured to generate an electrical signal indicative of a position of the sensor assembly in a reference coordinate system defined by the medical positioning system. The body includes a helical cutout extending over a predetermined length of the body. The helical cutout is configured to increase the flexibility of the body over the predetermined length of the body.

A medical guidewire includes an electrically conductive core, a polymer tubing that encloses at least a portion of the electrically conductive core, and a trackable electromagnetic element formed in a distal end of the medical guidewire. The trackable electromagnetic element includes a coil. A first end of the coil is electrically coupled to an electrically conductive structure such as a metallic braid in the polymer tubing, and a second end of the coil is electrically coupled to the electrically conductive core.

A guide wire which is flexible in a distal portion and which can prevent occurrence of damage such as breakage and separation of a coil in the distal portion has an elongated core member and a tubular body located so as to cover a periphery of a distal portion of the core member. The tubular body is formed using a belt-shaped member wound in a spiral shape, and has an engagement portion which causes side portions adjacent in a longitudinal axis direction of the core member to engage with each other in the belt-shaped member.

The disclosure generally relates to a guidewire with controllable stiffness and to a method of use thereof. A distal section of the guidewire includes a core wire, a shape memory coil, and a distal element electrically connecting the core wire to the shape memory coil. The shape memory coil has an expanded configuration with smaller stiffness and a compressed configuration having larger stiffness. Upon passage of an electric current through the shape memory coil, the shape memory coil may switch between the expanded and compressed configurations, thus changing the stiffness of the distal section of the guidewire.

A medical guidewire system including an inner member having an outer diameter and an outer member having an inner diameter, the inner diameter being larger than the outer diameter. The inner and outer members are relatively slidable to adjust a stiffness of the guidewire system. The lumen of the outer member forms a gap for fluid flow therethrough. A connector to the inner member and a fluid infusion channel communicating with the gap for injection of fluid through the gap to exit a distal portion of the outer member.

Medical devices and methods for making and using a medical device are disclosed. An example medical device may include a guidewire for accessing and treating a region of the neural vasculature. The guidewire may include an elongate shaft having a distal end region. The elongate shaft may include an inner tubular member and an outer tubular member. The inner tubular member may have a plurality of openings formed therein. The outer tubular member may have a plurality of slots formed therein. An occlusive balloon may be coupled to the distal end region of the elongate shaft and disposed about at least some of the plurality of openings. The inner tubular member may define a lumen in fluid communication with the occlusive balloon through the plurality of openings. The tip member may be coupled to the distal end region of the elongate shaft.

The present disclosure relates to guidewire devices having shapeable tips and effective torquability. A guidewire device includes a core having a proximal section and a tapered distal section. A tube structure is coupled to the core such that the tapered distal section extends into the tube structure. The tube structure includes a plurality of bypass cuts formed tangentially within the tube structure to increase the flexibility of the tube structure and to reduce the tendency of resilient forces from the tube structure to disrupt a shaped distal tip of the guidewire device.

The present disclosure relates to guidewire devices with an outer tube and a core. The distal section of the core extends into and is surrounded by the outer tube. One or more centering mechanisms are also disposed within the outer tube and are arranged to fill a portion of the annular space between the core and the inner surface of the tube. The one or more centering mechanisms thereby assist in keeping the distal section of the core axially aligned within the tube, which enables effective control of the device and minimizes undesirable whip movements of the guidewire.

A guidewire includes: a shaft having a proximal end, a distal end, and a body extending from the proximal end to the distal end; a blunt tip; and a sleeve; wherein the body of the shaft comprises at least a segment that is surrounded by the sleeve, the segment coupled to the blunt tip; and wherein the segment of the body of the shaft comprises a flat portion having one or more openings extending through a thickness of the flat portion.

Disclosed are intravascular devices comprising a core having a proximal and distal section and a tube wherein the distal section of the core passes into and is encompassed by the tube. The core includes a stepped shoulder located at the junction of the proximal and distal sections of the core. The proximal end of the tube is coupled to the stepped shoulder beneficially increasing torque transmission along the tube to the distal end of the intravascular device while maintaining effective flexibility of the device.