A tubular shaped elongated catheter device assembly with a distal and a proximal end, comprising an intraluminal distal segment and an extraluminal proximal segment, comprising one or more chemical and/or biological agents, for interaction with bodily fluids of luminal organs, wherein the intraluminal segment comprises at least one expandable cross-sectional area which in its expanded state is smaller than the cross-sectional area of the luminal target site and wherein at least the expandable portion of the intraluminal segment is capable of interacting with at least one component of the bodily fluid via an interactive contact surface.

The disclosed device, systems and methods relate to a novel catheter, system and methods. Exemplary embodiments comprise a plurality of lumens and balloons for insertion into the aorta and vena cava.

Medical devices including balloons and balloons are provided that include an elongate body and an inflatable balloon defining a longitudinal axis, the inflatable balloon being attached to and partially surrounding at least a section of the elongate body. The medical device further includes a plurality of protrusions extending from the inflatable balloon. When the inflatable balloon is in an unstrained state, each of the plurality of protrusions extends in a first transverse direction relative to the longitudinal axis. In certain implementations, the inflatable balloon may also be configured to collapse such that, when in a collapsed state, an untextured portion of the inflatable balloon extends to a radius and the plurality of protrusions does not extend beyond the radius.

Systems (1100) for treating a blood flow passage are discloses herein. In one example, a treatment device includes an expandable element (1104) configured to be positioned within the passage and a reinforcing element (1102). The expandable element may have an expanded configuration in which the expandable element defines a lumen (1108) therethrough. The reinforcing element may be positioned within the lumen of the expandable element. The reinforcing element may be coupled to the expandable element such that expansion of the expandable element causes the reinforcing element to radially expand, thereby creating a perfusion lumen through the device.

An ostial stent delivery device may include a first elongate shaft including a first lumen and extending along a central longitudinal axis, wherein the first elongate shaft includes a first inflatable balloon fixedly attached proximate a distal end of the first elongate shaft; and a second elongate shaft including a second lumen, the first elongate shaft being at least partially disposed within the second lumen. The second elongate shaft includes a second inflatable balloon fixedly attached proximate a distal end of the second elongate shaft. The second inflatable balloon is disposed at least partially proximal of the first inflatable balloon. The first inflatable balloon has a substantially cylindrical shape along a majority of its length in the deployed configuration. The second inflatable balloon has a substantially biconical shape having a central axis oriented parallel to the central longitudinal axis in the deployed configuration.

A method is disclosed, including joining a balloon to a resilient inner body of a balloon assist device, the balloon comprising an axial length shorter than an axial length of the inner body; expanding a slit in the resilient inner body of the balloon assist device; inserting a catheter through the slit; and releasing the slit to contract the balloon assist device around the catheter.

Filtration systems with integrated filter element(s) forming portions of the wall of the filtration catheter are disclosed. The filtration catheters disclosed herein are designed to be used alone or in conjunction with another filter device to provide embolic protection of both carotid arteries. Occlusive element such as balloon is placed on the exterior of the filtration catheter to redirect blood flow in the vessels during the filtration process as well as to help anchor the filtration catheter inside the vessel. The integrated filter element(s) does not require collapsing thus significantly reduces the complexity of the filtration system retrieval process and the chances of releasing emboli back into the blood stream. The compact design of the filtration systems makes them particularly suitable for embolic protection during endovascular procedures on or close to the heart.

A multi-stage balloon catheter has a deflated state, a first inflation state at a first pressure and a second inflation state at a higher fluid pressure. In the first inflation state, the multi-stage balloon has a plurality of bulb segments separated by waist hoops that allow the multi-stage balloon to conform to match the curvature of a passageway. When pressure is increased in the multi-stage balloon from the first inflation state to the second inflation state, the waist locations expand either by breaking or stretching the waist restraints or by overcoming expansion resistance incorporated into the balloon material at the waist locations. The multi-stage balloon catheter may be used to implant a stent in a manner to conform and match a curved passageway rather than tending to straighten the passageway.

There is provided a microcatheter having a proximal solution lumen and a distal tip portion with a guidewire lumen. The microcatheter and methods of use thereof allows for introduction of solution into a vessel while manipulating the guidewire and/or the microcatheter itself. The solution may be a contrast solution, for viewing of the vessel, a therapeutic or diagnostic solution, or any other type of solution.

Disclosed herein is a method of producing high purity pentagalloyl glucose (PGG), analogues or derivatives thereof, at least 99.9% pure, by washing with dimethyl ether. PGG may be provided in a kit, including a hydrolyzer for dissolving the PGG and a saline solution. Also disclosed herein is a device for delivery of a therapeutic solution to a blood vessel. The device may be a catheter having an upstream balloon and a downstream balloon. The upstream balloon may be expanded to anchor the catheter and occlude antegrade blood flow. The downstream balloon may be expanded to occlude retrograde blood flow, creating a sealed volume within the blood vessel. The downstream balloon may have pores configured to deliver a therapeutic inflation solution into the sealed volume or a portion thereof. The downstream balloon may be expanded by the expansion of a balloon disposed inside the downstream balloon.