A system for delivering an implantable medical device to an implant location includes a control handle portion, a catheter portion coupled to the control handle portion, and a distal portion configured to receive the implantable medical device. The catheter portion includes outer shaft including an inner braided layer extending axially along the outer shaft, an outer braided layer extending axially along the outer shaft, wherein the outer braided layer has a lower density of braids relative to the inner braided layer, and an axial spine positioned between the inner braided layer and the outer braided layer extending axially along the outer shaft.

The expandable sheaths disclosed herein include an expandable outer layer and a generally non-expandable inner layer. The outer layer is movable between a non-expanded configuration and an expanded configuration, where the outer layer/tubular layer is biased to the non-expanded configuration. Receipt of the inner layer within the central lumen of the outer layer causes the outer layer to transition from the non-expanded configuration to the expanded configuration.

Disclosed are methods and devices for restoring patency across a vascular or non-vascular occlusion. A first catheter having a first side port is configured to advance in a first direction through a vessel from a vascular access site on a first side of the occlusion. A second catheter having a second side port is configured to advance in a second direction through the vessel from a vascular access site on a second side of the occlusion. The catheters may have complementary surface configurations to facilitate alignment of the first and second side ports, so that a wire may be passed through the catheters, out of one of the side ports and into the other side port, to bypass the occlusion.

A split-tip catheter for placement within the vasculature of a patient and for use in hemodialysis or other suitable procedures, and methods of use. The split-tip catheter can include a catheter body defining a first lumen and a second lumen, and a split distal region extending from a distal end of the catheter body. The split distal region can include an arterial segment defined by an outer wall enclosing an arterial segment lumen, the arterial segment lumen in fluid communication with the catheter body first lumen, and a venous segment defined by an outer wall enclosing a venous segment lumen, the venous segment lumen in fluid communication with the catheter body second lumen, the venous segment outer wall extending from the catheter body distal end to a distal nose portion. The distal nose portion can taper from a first outer perimeter to a second smaller outer perimeter.

Aspects of the disclosure relate to medical catheters, including electrophysiological catheters, comprising a catheter maintaining at least one electrode including a plurality of electrode segments. The catheter can include a plurality of slots in which the electrodes can be secured so that the electrodes are at least partially positioned within a center lumen of the catheter. Methods of manufacturing medical catheters are also disclosed. In various methods of assembling a catheter, a hollow, tubular catheter made of a compliant material having a very small, micro or nano outside diameter is provided. Then, the slots are formed in the catheter and the electrode segments are positioned within the slots.

A medical device having a catheter and a fluid delivery conduit entirely disclosed within a portion of the catheter. The catheter may have a thermally transmissive region in fluid communication with the fluid delivery conduit and a rod disposed within at least a portion of the fluid delivery conduit. The medical device may control variable fluid flow with the ability to modify the effective cross-sectional area of the fluid delivery conduit available for fluid flow. Additional configurations provided herein may allow for the selective manipulation of a footprint or therapeutic pattern achievable with the medical device during a single procedure, negating the need for the removal and insertion of multiple devices to achieve the same variations in treatment geometry or characteristics.

Central catheters, central catheter assemblies, and methods thereof. A central catheter includes a catheter tube coupled with a number of the extension legs, a needle hub coupled with the catheter tube, where the needle hub is configured to receive a needle therethrough so that the needle is disposed within a primary catheter tube lumen. The central catheter includes a manifold hub for coupling the extension legs with the catheter tube. The manifold hub may be integral to the needle hub. The needle hub includes a septum within a needle hub lumen, where the septum is configured to define a fluid tight seal with a needle and to prevent fluid flow through the proximal portion of the needle-hub lumen when the needle is withdrawn from the needle-hub lumen. A method for introducing a central catheter into a blood vessel.

An endovascular catheter has an elongate catheter body having a distal portion, a proximal portion, multiple transition portions and a central lumen extending longitudinally through the catheter body. The catheter has a hybrid reinforcement, an angulated radiopaque marker and an angulated distal tip to improve the catheter’s ability to navigate vasculature and to improve clot aspiration.

A multi-lumen catheter includes a primary lumen having a proximal end and a tip and a secondary lumen parallel to the primary lumen. The primary lumen and the secondary lumen share a wall. A port is defined in the wall proximate the tip of the primary lumen and provides fluidic communication between the primary lumen and the secondary lumen.

A method of assisting a heart of a patient using a dual lumen cannula includes inserting the dual lumen cannula into the patient, positioning a first infusion tube of the dual lumen cannula in an artery near the heart to pump blood thereto, positioning a second drainage tube of the dual lumen cannula in a chamber of the heart to drain blood therefrom. The dual lumen cannula has a plurality of infusion apertures extending through a sidewall of the first infusion tube at a distal end of the first infusion tube; and a plurality of drainage apertures extending through a sidewall of the second drainage tube at a distal end of the second drainage tube. The distal end of the first infusion tube has a tapered portion extending distally beyond a distal-most infusion aperture of the plurality of infusion apertures and to a terminal surface at a tip of the first infusion tube.