An everting balloon system is disclosed that can be used for the placement of an IUD within the uterine cavity of a female patient. The everting balloon system with IUD can be used to access a uterine cavity at specific locations in the fundus. A one-handed IUD delivery system for placement with an everting catheter is disclosed. An IUD loading system for placement within an everting catheter is disclosed. The everting catheter with an IUD can simplify the process of IUD placement within the uterine cavity.

An everting balloon system is disclosed that can be used for the placement of an IUD within the uterine cavity of a female patient. The everting balloon system with IUD can be used to access a uterine cavity at specific locations in the fundus. A one-handed IUD delivery system for placement with an everting catheter is disclosed. An IUD loading system for placement within an everting catheter is disclosed. The everting catheter with an IUD can simplify the process of IUD placement within the uterine cavity.

A dialysis catheter is provided. A first lumen extends through a first tubular member from a proximal portion to a distal portion, and a first orifice at the distal portion provides an opening through the first tubular member to the first lumen. The first tubular member further includes an inflation lumen extending longitudinally at least partially through a length of the first tubular member. A balloon is operably connected to an outer surface of the first tubular member proximal to the first opening, is in fluid communication with the inflation lumen. A second tubular member has a proximal portion connected to the outer surface of the first tubular member. A distal portion of the second tubular member is connected to the balloon wall. A second lumen extends through the second tubular member, and a second orifice provides an opening through the second tubular member at the distal portion.

A catheter that includes a reinforcing body including a wire wound or woven so that a gap is provided between each winding or weave of the wire; an inner layer, the reinforcing body being embedded in at least a part of the inner layer; and an outer layer that covers an outer periphery of the inner layer in a circumferential direction, and the reinforcing body is formed integrally including a first diameter portion with a first outer diameter, a second diameter portion with a second outer diameter larger than the first outer diameter, and a tapered portion increasing in diameter toward a distal end side or a proximal end side between the first diameter portion and the second diameter portion, and at least the second diameter portion of the reinforcing body is embedded in the outer layer.

A balloon catheter includes a flexible outer cylinder shaft, a holding member connected to a proximal end portion of the outer cylinder shaft, a sealing member that maintains liquid tightness incorporated in the holding member, a flexible inner cylinder shaft, a tube having a Rockwell hardness of R 115 or more, a flexural modulus of 3.0 to 4.5 GPa, and a thickness of 0.06 to 0.12 mm, a push-in member connected to a proximal end portion of the inner cylinder shaft, a pull-out prevention member connected to the push-in member, and a balloon composed of an elastic material and connected to each of the distal end portion of the outer cylinder shaft and the proximal end portion of the inner cylinder shaft, wherein the tube is inserted over the inner cylinder shaft over an area thereof except for a connecting portion between the balloon and the inner cylinder shaft.

An everting catheter with an expandable inner lumen for the passage of instruments or other devices is described. The catheter can have an inflatable everting balloon. When inflated, the everting balloon can define a channel or passageway, via an inner balloon lumen, into a target site. Instruments can be delivered to the target site through the channel defined by the inflated everting balloon.

A catheter includes an elongated body and an expandable member configured to expand radially outward away from the elongated body from a collapsed configuration to an expanded configuration. The catheter further includes a retainer configured to overlap an end of the expandable member to hold the expandable member in the collapsed configuration. The expandable member may be configured to engage with a vessel wall when the expandable member is in the expanded configuration. The vessel may curve and the expandable member may be configured to deflect a portion of the elongated body distal to the expandable member when the expandable member is engaged with the vessel wall to better conform the shape of the elongated body to the curved portion of the vessel.

An everting balloon system is disclosed that can be used for biopsy within a body of a patient or animal. The everting balloon system can be used to access a bodily cavity or vessel for tissue specimen collection at specific bodily locations. The everting catheter system described simplifies the process of tissue biopsy.

An improved medical device reduces the loss of longitudinal length during expansion of a stent-graft from a compressed state to an expanded state. For example, the stent-graft is placed over a cover that provides resistance to expansion of the balloon during inflation, which reduces longitudinal compressing forces exerted on the stent-graft.

A balloon catheter includes an outer shaft, an inner shaft, and an inflatable balloon. The inner shaft is inserted inside the outer shaft. A part of the inner shaft extends from a leading end of the outer shaft. The balloon includes a base end side joint portion joined to the outer shaft and a leading end side joint portion joined to the inner shaft. The inner shaft has an extension portion configured to in an axial line direction. The extension portion is provided further to a base end side than the leading end side joint portion.