The present disclosure is directed to intravascular devices, systems, and methods having a core wire with multiple flattened sections. In one aspect, a sensing guide wire is provided. The guide wire includes a first flexible elongate member; a sensing element positioned at a distal portion of the first flexible elongate member; and a second flexible elongate member coupled to the first flexible elongate member such that the second flexible elongate member extends distally from the first flexible elongate member; and wherein a distal portion of the first flexible elongate member includes at least two flattened sections, and wherein the first and second flexible elongate members are coupled along a portion of one of the at least two flattened sections. In other aspects, methods of forming a sensing guide wire are provided.

A guide wire configured for intravascular insertion includes a core wire having a flattened portion configured to allow the core wire to preferentially bend in at least one plane that passes through a longitudinal axis of the core wire. A distal most end of the flattened portion is spaced from a distal most end of the core wire. The guide wire may further include a sensor element configured to measure a physiological variable in a living body and a coil surrounding a portion of the core wire.

A guidewire comprises an elongate metal core, an inner layer, an optical core, and an outer layer. The metal core is configured to communicate torsional motion from a proximal end of the metal core to the distal end of the metal core. The inner layer extends about the metal core and has a first index of refraction. The optical core is disposed about the inner layer, wherein the optical core is configured to transmit light along the length of the guidewire. The optical core has a second index of refraction, which is greater than the first index of refraction. The outer layer is disposed about the optical core and has a third index of refraction. The third index of refraction is less than the second index of refraction.

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.

A section is disclosed for use with a portion assembly. The section can include a solid core section with a distal section having a first diameter, and a proximal section having a second diameter, wherein the second diameter can be greater than the first diameter. The section can include a coil wound around the distal section of the solid core section. The proximal section can have a flexural stiffness that is less than a flexural stiffness of the distal section. A length of the distal section of the section may be shorter than the length of the portion. A length of the proximal section of the section may be longer than the length of the portion.

Multiple approaches to incorporating multiple conductors on a guidewire by building the multiple conductor traces of variable sizes and material compositions on separate insulating layers are described. The approaches described in the invention facilitate ease of assembly of sensors to the guidewire or catheter element. This approach is particularly useful in scenarios where electrical or mechanical properties of the device need to be altered in specific sections to either enhance device performance and reliability (e.g. selective abrasion resistance), or facilitate ease of assembly (e.g. soldering or connection ease), or in some instances achieve desired electrical characteristics (e.g. impedance). The desired properties are incorporated into the same device requiring an innovative approach to forming signal wires in an otherwise tight space without impacting the primary mechanical performance of the devices.

The present disclosure is directed to intravascular devices, systems, and methods having a core wire with multiple flattened sections. In one aspect, a sensing guide wire is provided. The guide wire includes a first flexible elongate member; a sensing element positioned at a distal portion of the first flexible elongate member; and a second flexible elongate member coupled to the first flexible elongate member such that the second flexible elongate member extends distally from the first flexible elongate member; and wherein a distal portion of the first flexible elongate member includes at least two flattened sections, and wherein the first and second flexible elongate members are coupled along a portion of one of the at least two flattened sections. In other aspects, methods of forming a sensing guide wire are provided.

Guidewires having conductive elements are described where in one variation, the guidewire may be formed by disposing an insulative layer upon a surface of the guidewire core, and printing one or more conductive traces directly upon a surface of the insulative layer.

An elongate body extending from a proximal end to a distal end includes a core comprising an amorphous metal alloy and includes a sheath that comprises a crystalline metallic material. The sheath surrounds the core.

Disclosed is a novel vascular optical fiber guidewire. The vascular optical fiber guidewire includes a metal axial wire and an optical fiber surrounding the metal axial wire. The optical fiber includes a core wire and a cladding layer covering the core wire. For above vascular optical fiber guidewire, in a part of the optical guidewire that is required to transmit light, a bending radius of the optical fiber around the metal axial wire is greater than a critical bending radius, and in a region of the optical fiber guidewire that is required to scatter light, the bending radius of the optical fiber around the metal axial wire is less than the critical bending radius. The present disclosure is capable of entering a blood vessel by a percutaneous puncture technique, guiding the optical fiber guidewire through a medical imaging device in a blood vessel, and performing side-illumination on the head.