Disclosed herein are magnetically trackable stylets and methods thereof. A magnetically trackable stylet can include a stylet body including a core wire, a magnetic assembly, and an outer construction over the core wire and the magnetic assembly. The magnetic assembly can include one or more magnetic field-producing elements disposed alongside the core wire in a magnetically trackable distal portion of the stylet body. The outer construction, which can be an overmolded layer, a reflowed layer, a potting layer, or a shrink-wrapped layer, can be around the core wire and the magnetic assembly. The stylet body can be configured to be disposed in a lumen of a medical device such as a catheter for magnetically tracking a tip of the medical device in vivo without breakage of the stylet body due to bending-related fatigue. A method of such a magnetically trackable stylet can include a method of using the stylet.

Disclosed are guidewire and catheter systems that can be used to facilitate desirable catheter axial response (e.g., pushability) over a guidewire for advancement through patient vasculature. Features of the guidewire and catheter systems enable the catheter to advance over the guidewire within the tortuous paths of a patient's vasculature in response to push forces that do not exceed 50 g.

An access guidewire has a distal portion including a distal portion length and a distal portion diameter. The guidewire also includes an intermediate portion, proximal to the distal portion, having an intermediate portion length and an intermediate portion diameter. A proximal portion is proximal of the intermediate portion and includes a proximal portion length and a proximal portion diameter. The intermediate portion diameter is greater than the the distal portion diameter and the proximal portion diameter.

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.

A guide wire including a core shaft including a distal end portion having a pseudoelastic property, a tip joined to a distal end of the distal end portion of the core shaft, and an auxiliary wire that is arranged parallel to the distal end portion of the core shaft. The auxiliary wire has a distal end joined to the tip and a rear end joined to the core shaft. The auxiliary wire has a high flexibility, a high breaking strength, and a short breaking elongation compared to the distal end portion of the core shaft.

A guide wire in which a housing of a sensor is easy to be curved and a slit is hard to fracture. The guide wire includes a core wire, a first helical body, a second helical body, a housing attached to the first helical body and the second helical body, and a pressure sensor located in an internal space of the housing. The housing has slits penetrating a peripheral wall and extending in helices. One of the slits has a central portion extending in the helix in an extending direction and an end portion bent with respect to the central portion along a bending direction.

A connection structure includes a multi-thread coil formed by winding first metal element wires formed of a first metal and second metal element wires formed of a second metal arranged between a first metal body including the first metal and a second metal body including the second metal. The first metal body is connected to the first metal element wires of the multi-thread coil, and the second metal body is connected to the second metal element wires of the multi-thread coil. The connection structure imparts improved flexibility to the connection between the first and second metal bodies, and an appropriate connection can be provided even when the first and second metal bodies are made of dissimilar metals.

The proposed device comprises a plurality of electroactive material actuator units arranged as a set. Control data for driving individual units is transferred over three shared power lines. The electroactive material actuator of each unit is driven depending on control data received from the power lines via a demodulator, a controller, and a driver.

A reentry catheter for crossing a vascular occlusion includes an elongate flexible tubular body, having a proximal end, a distal end and at least one lumen extending there through. A reentry zone on the tubular body includes at least two and preferably three sets of opposing pairs of axially spaced exit apertures in communication with the lumen. The apertures are rotationally offset from each other and aligned in a spiral pattern around the tubular body. A method of crossing a chronic total occlusion includes the steps of advancing the reentry catheter across the occlusion via a channel formed in the subintimal space, and advancing a guidewire via a selected exit port into the native lumen distally of the occlusion. The catheter may be removed, leaving the guidewire across the occlusion to guide further interventional devices.

A guide wire includes a core shaft and a coil body wound around at least a portion of the core shaft on a proximal end side. The coil body is joined with the core shaft by a predetermined joint means at a position of a proximal end of the core shaft, and a first position along an axial direction of the guide wire between the proximal end and a distal end of the core shaft. The coil body is joined with the core shaft by welding at an axial specific position being at least one position within a range from the proximal end of the core shaft to the first position along the axial direction of the guide wire.