A ureteral catheter includes a drainage lumen having a proximal portion configured to be positioned in at least a portion of a patient's urethra and/or bladder and a distal portion configured to be positioned in a patient's kidney, renal pelvis, and/or in the ureter adjacent to the renal pelvis. The distal portion includes a retention portion for maintaining positioning of the distal portion of the drainage lumen. The retention portion includes a plurality of sections, each section having one or more openings on a sidewall of the retention portion for permitting fluid flow into the drainage lumen. A total area of openings of a first section of the plurality of sections is less than a total area of openings of an adjacent second section of the plurality of sections. The second section is closer to a distal end of the drainage lumen than the first section.

The invention relates to an intercardiac pump device comprising a pump (11) whose distal end (13) is connected to a cannula (15) which is provided with a suction head (16) for sucking blood. Said strainer is provided with a non-sucking extension (20) for stabilizing the position of said pump device in the heart and mechanically prolonging the cannula (15) without deteriorating hydraulic conditions. Said extension is also used in the form of a spacer in order to avoid that the suction head (16) adheres to a cardiac wall.

A system of devices for treating an artery includes an arterial access sheath adapted to introduce an interventional catheter into an artery and an elongated dilator positionable within the internal lumen of the sheath body. The system also includes a catheter formed of an elongated catheter body sized and shaped to be introduced via a carotid artery access site into a common carotid artery through the internal lumen of the arterial access sheath. The catheter has an overall length and a distal most section length such that the distal most section can be positioned in an intracranial artery and at least a portion of the proximal most section is positioned in the common carotid artery during use.

An apparatus and method of manufacture includes a helical wire coil and a core wire. The core wire has a first wire portion and a second wire portion. The first wire portion of the core wire extends through the helical wire coil. The second wire portion of the core wire is intertwined with the first helical wire coil to fixedly secure the core wire relative to the first helical wire coil. The core wire is formed from a first material that is non-extensible. The core wire is fixedly secured relative to a distal portion of the helical wire coil such that the core wire inhibits longitudinal elongation of the helical wire coil along a longitudinal coil axis.

A heart pump assembly, also referred to as catheter assembly, having a desired anatomical shape is provided. The catheter assembly can include a catheter and a cannula having a bend between a proximal portion and a distal portion. A resting shape of the catheter and the cannula can be selected to allow the distal cannula portion to be positioned at a desired angle relative to an anatomical plane (e.g., a plane of an aortic arch). In some embodiments, a packaging tray can be designed to set the catheter assembly in a desired resting shape. For example, the proximal cannula portion can be positioned at a first angle relative to the catheter, and the proximal cannula portion can be positioned at a second angle out of the plane of the packaging tray via one or more inserts.

A catheter includes a tubular body comprised of inner and outer layers, and an embedded reinforcement body. The tubular body includes a substantially linear main body portion and a shaped portion that is bent so the shaped portion lies in substantially the same plane. The shaped portion includes a first bent portion defining a first angle distal of the main body portion, a second bent portion defining a second angle distal of the first bent portion and bent to the same side as the first bent portion, a third bent portion defining a third angle distal of the second bent portion and bent to a side opposite the second bent portion, and a most distal portion distal of the third bent portion. A physical property changing point exists between a proximal portion of the first bent portion and a distal portion of the second bent portion.

The described invention provides endovascular devices that share the following general features: a working segment, a support segment, a working lumen, a support lumen, a side hole, and an angled extension. A described endovascular device includes an outer support catheter and an inner catheter with a side hole optionally containing an angled extension disposed at least partially within the lumen defined by the outer support catheter. The inner catheter can be connected to sets of grips on the outer catheter and the inner catheter, which are used by the operator to rotate one catheter relative to the other so as to position the side hole or the angled extension of the inner catheter in the targeted vessel. A radiopaque marker or intravascular ultrasound can be used to identify the position of the distal side hole in vivo. In some devices, the distal segment beyond the side hole (the support segment) for each of the described devices is effective to provide stability to each endovascular device, to provide strength to the endovascular device, to provide support for the endovascular device, to facilitate placement of the endovascular device, to anchor the endovascular device within a blood vessel, to reduce kickback of the endovascular device, or a combination thereof. The endovascular devices described can include additional support elements, for example, a balloon, a stent, a wire, or a combination thereof. The described selectively inflatable balloon is of two dimensions, a diameter and a length, sized to fit within the diameter of a vessel, for positioning the endovascular device. It may be disposed in a circumferential array of selectively inflatable balloons, as a single distal inflatable balloon or both. The circumferential array of selectively inflatable balloons is effective to position the endovascular device within a target blood vessel. The single distal balloon is effective to anchor the endovascular device within a target blood vessel. Each inflatable balloon can be selectively filled with a fluid, e.g., sterile water and saline.

Embodiments of medical devices and methods are disclosed. The medical devices typically comprise a flexible elongate member defining a lumen, and a support spine affixed to the distal end and extending proximally therefrom within the elongate member lumen. In some embodiments, the support spine is pre-shaped such that the support spine biases the distal region of the elongate member to adopt a straight configuration, or the support spine biases at least a portion of the distal region of the elongate member to adopt a curved shape to form a curved portion. Some embodiments include apertures at or near the distal end for enabling fluid communication between the lumen and the outside environment. In some embodiments, the support wire extends proximally from the distal end within a distal portion of the lumen such that a proximal portion of the lumen is substantially unobstructed.

A needle assembly 10 compromising an infusion needle 11 that includes a needle cannula 13 made of a superelastic material such as Nitinol. The needle cannula is cold-worked or heat annealed to produce a preformed bend 16 that can be straightened within passageway 21 of a coaxial outer cannula 12 for introduction into the body of a patient. Upon deployment from the outer cannula, the needle cannula substantially returns to the preformed configuration for the introduction or extraction of materials at areas lateral to the entry path of the needle assembly. The needle assembly can compromise a plurality of needle cannulae than can be variably arranged or configured for attaining a desired infusion pattern.

An imaging medical device includes a shaft main body portion having an image acquiring lumen and a guide wire lumen. The shaft main body portion includes a first shaft proximal portion in which the image acquiring lumen is disposed, and a second shaft proximal portion in which the guide wire lumen is disposed, with the two being bifurcated. First and second hub portions are interlocked with the first and second shaft proximal portions respectively, and a transducer unit is fixed to a drive shaft. Reference line X represents the axis line of the shaft main body portion, θ1 represents the inclination of the central axis of the first hub portion relative to the reference line, θ2 represents the inclination of the central axis of the second hub portion relative to the reference line, and the relationship of |θ1|>|θ2| is satisfied.