This disclosure describes microfabricated core wires configured for use in an intravascular device such as a guidewire or microcatheter. A microfabricated core wire includes a plurality of disks spaced apart from one another along a length of the distal section and a plurality of longitudinally extending ribbons interposed between the disks, each ribbon extending between and connecting a pair of adjacent disks. Various arrangements of disks and ribbons may be provided to control stiffness across a length of the core wire, particularly at or near the distal tip of the core wire.

The disclosure provides a medical guidewire. The medical guidewire includes an equal-diameter fiber and a variable-diameter sleeve surrounding the equal-diameter fiber. The variable-diameter sleeve includes a shaping section, a supporting section, and a pushing section that are connected in sequence. The shaping section, the supporting section and the pushing section have outer diameters increased sequentially. An asymmetric structure is provided on the variable-diameter sleeve itself or the surround of the variable-diameter sleeve along the equal-diameter fiber. The medical guidewire provided by the disclosure has improved bending performance and operability, so that it is easy to manipulate the medical guidewire to enter blood vessels with a large opening angle. thereby improving the effect of minimally invasive interventional treatment.

An optical fiber guidewire according to an embodiment of the present disclosure includes at least one optical fiber and a sleeve surrounding the optical fiber. The sleeve includes a functional section, a guiding section and a supporting section that are connected in sequence. An asymmetric structure is provided on the sleeve itself or the surround of the sleeve along the optical fiber. Therefore, the optical fiber guidewire provided in this disclosure has good bending performance and operability, and thus can be easily manipulated, readily enters a body cavity with a larger opening angle, and achieves self-guidance and flexible detection of the optical fiber guidewire in the body cavity, thereby improving the effect of minimally invasive interventional treatment.

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.

A guidewire having a proximal core wire formed from a first metal alloy is connected to a distal core wire formed from a second metal alloy. A tubular member is sized to receive an end of the proximal core wire and an end of the distal core wire in a butting configuration. The tubular member is attached to the proximal core wire and the distal core wire to form a joint connecting the two wires together.

The present invention relates to a safety puncturing system comprising a cannula and a guidewire.

A microtube guide has a microtube combined with a free-floating and removable core. The microtube is generally hollow with a tube shaft and a distal ring, the tube shaft and the distal ring formed from flexible plastic. The distal ring is conformable to the core and straightenable for insertion into a patient's body, and deploys when the core is withdrawn to form a loop. The core is received by the microtube and is configured to advance into the distal ring to cause a diameter of the distal ring to expand, retract, or straighten. The core comprises a tapered segment that tapers in outer diameter from the diameter of the main core wire to a smaller diameter. A distal end segment of microtubing is frictionally affixed to the tapered segment.

Intravascular delivery system for deployment of a therapeutic device (such as a stent, and/or other therapeutic devices including balloon catheter(s), laser catheter(s), intravascular ultrasound (IVUS), Optical coherence tomography (OCT), drug delivery catheter(s), coil delivery catheter(s), etc.) as required by a particular surgical procedure, in a controlled and robust manner is supported by a lockable balloon catheter equipped with a locking mechanism configured to lock in vivo to a delivery component, such as a guidewire. The lockable balloon catheter can be controllably transitioned between locked and unlocked modes of operation by inflation/deflation of the balloon of the lockable balloon catheter. The system provides an enhanced interlocking interface between the delivery component and an inner shaft by a unique configuration of the inner shaft. Connection of the inner shaft/guidewire and/or outer shaft/inflation lumen to the balloon is by an extended “neck” at the end(s) of the balloon which snuggly envelopes the portions of the inner and/or outer shaft(s) entering/exiting the balloon, thus avoiding the bonding and simplifying fabrication process. Being in the locked mode of operation, the lockable balloon catheter facilitates delivery of the therapeutic device along the delivery component to a target site while enhancing the stability of the delivery component, especially near the target site.

Disclosed is a guidewire having a core wire and an outer tube within which the distal section of the core is inserted. The outer diameter of the tube is greater than the outer diameter of the proximal section of the core wire. The guidewire also includes a proximal coil and a distal, radiopaque coil each disposed over the distal section of the core. A bushing coil is disposed over the proximal coil and distal coil. The proximal coil, distal coil, and bushing coil aid in filling the annular space between the core and the tube and thereby centering and aligning the core and tube.

A guide wire for minimally invasive operations with a distal wire end piece (3, II) connected to a wire main piece (2), wherein the guide wire (I, 10) has, at least in the distal wire end piece (3, II), an inner shaft (4, 14) and at least one protective layer enclosing the inner shaft (4, 14), the inner shaft (4, 14) comprises a first fibre composite material and, at least in the distal wire end piece (3, II), the inner shaft (4, 14) has a plurality of weakened points (8, 18), which are created by mechanical interventions, is characterised in that the weakened points (8, 18) are created by buckling load, bending load and/or breaking load. Correspondingly, for a method for producing a guide wire of this kind it is proposed that the weakened points (8, 18) are created by buckling load, bending load and/or breaking load.