A catheter includes a handle with torqueing and steering mechanisms. The torqueing mechanism includes a rotatable nosecone and a bearing coupled to the nosecone to be rotatable therewith. The bearing is concentrically disposed over a shaft of the catheter. The steering mechanism includes a rack coupled to the bearing to be slideable therewith and a pull wire having a proximal end attached to the bearing and a distal end attached to a distal portion of the shaft. Rotation of the nosecone causes an entire length of the shaft to rotate and axial movement of the rack tensions the pull wire to bend the distal portion of the shaft. A valve relief component is slidingly disposed over the shaft and is configured to dock onto the handle when not in use.

A support catheter includes: a distal shaft shaped as a tube into which a therapeutic catheter is insertable, the distal shaft including an inner layer and a reinforcing layer, the reinforcing layer being shaped as a tubular mesh including metal wires wound in first and second opposite directions; and a proximal shaft connected to the distal shaft. The reinforcing layer includes welds at intersections of the metal wires wound in the first and second directions. The welds are located in a limited region in a circumferential direction of the distal shaft. A covering member is located outside the welds.

A method of delivering a therapeutic substance for treatment to a region of the body through vascular isolation and manipulation of fluid flux into and from the region of the body including the steps of: restricting vascular inflow to the region of the body; washing out oncotically active plasma proteins from the region of the body by increasing the outward oncotic pressure gradient from the region of the body; inducing ischemia in the region of the body; controlling the pressure and fluid flow of the main blood vessels to and from the region of the body; providing the therapeutic substance to the region of the body when the fluid flow to the region of the body is controlled.

System and method for bi-directional fluid injection includes a retrograde introducer, a retrograde cannula having an inlet opening, intermediate opening and outlet opening, an antegrade introducer and an antegrade cannula. The retrograde introducer is configured to engage with the retrograde cannula and to insert the retrograde cannula into a fluid channel. The antegrade introducer is configured to engage with the antegrade cannula and to insert the antegrade cannula into the fluid channel from within the retrograde cannula through the intermediate opening. After insertion of both cannulas, both introducers are removed. In operation, fluid flows into the retrograde cannula inlet and a portion thereof is diverted to the antegrade cannula which flows the portion in a first direction in the channel, the remainder of the fluid flows out the retrograde cannula outlet in an opposite direction in the channel. The system is removed from the channel using the introducers in reverse order.

A balloon catheter and method for manufacturing are disclosed in which the fracturing of the vicinity of a proximal opening portion formed by an inner shaft can be prevented. A distal side of an inner shaft included by a balloon catheter is disposed in a lumen of an outer distal shaft, and a proximal side of the inner shaft is disposed on an outer surface of an outer proximal shaft, and the inner shaft forms a proximal opening portion which opens on an outer surface side of the outer proximal shaft. The inner shaft has a first region and a second region disposed on a proximal side of the first region. The first region is fixed to the outer surface of the outer proximal shaft. The second region is not fixed to the outer surface of the outer proximal shaft.

A medical device includes a guidewire extending between a proximal portion defining a proximal end and a distal portion defining a distal end. The distal portion includes a radially expandable part, and the guidewire is movable between a retracted configuration in which the part is radially retracted and an expanded configuration in which the part is radially expanded. The part is radiopaque.

Lumen-apposing shunt devices for transporting body fluid from a first compartment (e.g., peritoneal cavity) to a second compartment (e.g., bladder) comprise a longitudinal tube communicating between the two compartments and retention systems that separate apart and maintain each end of the tube within the respective compartment. The retention systems include double self-expandable wheels and double inflatable balloons enveloping the tube transversely, with one wheel or balloon in the first compartment and the other wheel or balloon in the second compartment. The self-expanded wheels or inflated balloons support and retain the shunt device between the compartments as fluid (e.g., ascites) from the first compartment flows into the second compartment in response to pressure gradients between the compartments. The shunt device contains a one-way valve mechanism to provide unidirectional flow of fluid from the first to the second compartment and to prevent reflux from the second to the first compartment.

Apparatus, including a probe having a distal end insertable into a nasal sinus of a human patient, and a location sensor positioned within the distal end. A sinuplasty balloon is positioned on the distal end at a selected opening of the nasal sinus. A processor receives first signals from the location sensor while the distal end is inserted into the nasal sinus and prior to positioning of the balloon at the selected opening, and generates a first map of the sinus. The processor inflates the balloon when it is at the selected opening, so as to enlarge the selected opening, and subsequently deflates the balloon. The processor then receives second signals from the location sensor and generates therefrom a second map of the sinus. The processor registers the first map with the second map and generates from the registered maps a numerical increase in size of the selected opening.

Retrieval of material from vessel lumens can be improved by electrically enhancing attachment of the material to the thrombectomy system. The system can include a catheter having a distal portion configured to be positioned adjacent to a thrombus in a blood vessel, an electrode disposed at the distal portion of the catheter, and an interventional element configured to be delivered through a lumen of the catheter. The electrode and the interventional element are each configured to be electrically coupled to an extracorporeal power supply.

An introducer assembly (10) includes a catheter (12) having a proximal end (14), a distal end (16) extending to a distal tip of the introducer assembly, and an outer catheter wall. The catheter (12) includes a medical device holding portion (34) proximate the distal end, a guide wire lumen (100) extending between the proximal and distal ends, and a side opening (50) extending through the outer wall to the guide wire lumen. The side opening (50) and the guide wire lumen (100) are simultaneously open and the guide wire lumen and side opening are able to receive a guide wire therethrough. The catheter (12) is flexible at least in the location of the side opening, such that a guide wire (28) fed from the distal end (16) can pass through to the proximal end (14) when the catheter is substantially straight and can pass from the distal end through the side opening (50) when the catheter is curved at the location of the side opening. The catheter (12) also includes a plurality of one stiffening mandrel lumens (104, 106) extending from the proximal end (14) and a plurality of stiffening mandrels sized to fit within the stiffening mandrel lumens and in some forms able to slide therewithin and in other forms enclosed within the stiffening mandrel lumens. The mandrels have different lengths disposed along the length of the catheter and can be of substantially uniform diameter.