Rapidly inserted central catheters (RICC) and methods thereof are disclosed. For example, a RICC can include a first section in a distal-end portion of a catheter tube, a second section in the distal-end portion of the catheter tube proximal of the first section of the catheter tube, and a junction joining the first and second sections of the catheter tube. The first section of the catheter tube can be formed of a first polymeric material having a first durometer. The second section of the catheter tube can be formed of a second polymeric material having a second durometer less than the first durometer. The first section of the catheter tube can have a proximal-end portion disposed in a receptacle of the junction and solvent bonded thereto. For example, a method can include a method of making or using a RICC.

A catheter includes a cylindrical distal member connected to a distal end part of a catheter body, and the distal member has a bending portion located distal to a most distal end part of the catheter body, the bending portion being a section that bends when an external force in a bending direction is applied to a distal end part of the distal member with the distal end part of the catheter body being fixed. The Young's modulus of the bending portion is smaller than the Young's modulus of the proximal end part of the distal member. A method for manufacturing the catheter includes performing a heat treatment for fusing the proximal end part of the distal member to the catheter body while adjusting a thermal load on an axially intermediate part of the distal member to be smaller than a thermal load on the proximal end part.

A deflectable, flexible device includes an elongate body, a convoluted tip portion at a distal end of the elongate body, and a lumen to receive one or more wires. The convoluted tip portion includes an electroformed pleated region which is formed by electrodepositing a metal on a mandrel having a pleated region. The convoluted tip portion may be hermetically sealed to permit repeated sterilization. The electroformed pleated region may include one or more fluid emission orifices. The convoluted tip portion extends or bends in response to fluid pressure manipulation, contact with tissue, manipulation with an internal spring or wire, or by a user pushing, pulling, or twisting the catheter directly or via an introducer sheath or the like. The convoluted tip portion may further include an RF ablation element or other energy-driven technique to create continuous linear lesions or a sensing element.

The present invention provides a system for enriching a flowing liquid with a dissolved gas inside a conduit. The system comprises two or more capillaries, each capillary delivering a stream of a gas-enriched liquid to the flowing liquid. The first ends of the capillaries are positioned to form an intersecting angle with respect to the effluent streams such that these streams of gas-enriched liquid collide with each other upon exit from the first ends of the capillaries, effecting localized convective mixing within the larger liquid conduit before these gas-enriched streams are able to come into close contact with the boundary surfaces of the conduit, whereby the gas-enriched liquid mixes with the flowing liquid to form a gas-enriched flowing liquid. In the preferred embodiment, no observable bubbles are formed in the gas-enriched flowing liquid. Methods of making and using such system are also provided.

Ablation systems and methods of the present disclosure are directed toward delivering pulsed radiofrequency (RF) energy to target tissue. The pulsations of the RF energy, combined with cooling at a surface of the target tissue, can advantageously promote local heat transfer in the target tissue to form lesions having dimensions larger than those that can be safely formed in tissue using non-pulsed RF energy under similar conditions.

Ablation systems and methods of the present disclosure control lesion depth and width such that, for example, wide and shallow lesions can be formed in target tissue in an anatomic structure of a patient during a medical procedure. Such wide and shallow lesions can be useful for treating, for example, thin tissue such as atrial tissue in atria of the heart of the patient.

This disclosure is directed to a catheter having a multi-electrode assembly with a high electrode density. The multi-electrode assembly may be a basket-shaped electrode assembly or a brush-shaped electrode assembly each having a plurality of spines. Each spine includes a flexible wire core of a shape memory material. The flexible wires may have variable cross-section s to control the movement and stiffness of the spines.

A method of producing a bendable tip for an instrument, is provided, which includes: mounting a tube for an instrument in a CNC controlled rotational and axially movable holder of a laser cutting machine, with a distal end of the tube extending form the holder; activating a laser cutter; cutting wedge shaped partial circumferential openings in the tube to define a plurality of radially extending ribs at the distal end of the tube, with the ribs being connected together by an axially extending spine, and the ribs having first and second axial sides; during cutting, forming in each of the ribs in at least one of the first or second axial sides, at least one of an axial projection or a recess, and forming in a facing one of the at least one of the first or second axial sides of an adjacent one of the ribs at least one of a corresponding complementary mating recess or a corresponding axial projection.

A cryoablation device is provided herein which, in an embodiment, includes a catheter shaft; a cryogen return line disposed within the catheter shaft; and a cryogen supply line disposed within the cryogen return line, such that the cryogen supply line, the cryogen return line, and the catheter shaft are all substantially coaxial. A needle tip probe is disposed at a distal end of the cryogen return line. The cryogen supply line extends in a distal direction beyond a distal end of the cryogen return line and into the needle tip probe, and the catheter shaft is axially movable relative to the needle tip probe and the cryogen return line, and the catheter shaft is configured such that the catheter shaft is distally extended over the needle tip probe in an extended position.

In some examples, a catheter includes an elongated body comprising proximal and distal portions. The distal portion of the elongated body comprises an inner liner that includes a proximal liner section and a distal liner section that include different materials, and an outer jacket positioned over the inner liner. The distal liner section has a first hardness and the proximal liner section has a second hardness, where the first hardness is less than the second hardness.