Methods, devices, systems of resuscitating a patient including accessing an arterial vessel positioning a catheter into the arterial vessel advancing the catheter through the arterial vessel to position it below a vessel supplying blood to a heart and a brain expanding an expandable portion of the catheter to prevent blood from flowing past the expanded portion and infusing a substance retrograde into the artery within the arterial section between the heart and the expanded portion of the catheter.

A double-balloon catheter device for gastrointestinal anastomosis. The double-balloon catheter device for gastrointestinal anastomosis includes a liquid injection assembly, a double-balloon assembly, and a supporting device (15) connecting the liquid injection assembly and the double-balloon assembly. The liquid injection assembly includes a first balloon liquid injection connection port (2), a guide wire connection port (3), and a second balloon liquid injection connection port (4). The double-balloon assembly includes a double-balloon catheter device (5), and includes a first balloon (6) and a second balloon (7) that can expand-and that are respectively disposed on the two ends of the double-balloon catheter device (5). The double-balloon catheter device (5) is provided with a first balloon liquid injection channel (51), a guide wire channel (52), and a second balloon liquid injection channel (53).

a dilatable balloon catheter, comprising: a guide wire inserted and disposed in the inside of the catheter, an operation portion is fixedly connected to one end of the catheter, a balloon is disposed at the outer side of the catheter remote from the operation portion, the lumen of the catheter and the inner cavity of the balloon are connected by a communication structure provided on the catheter, the guide wire includes a first guide wire and a second guide wire which are separated from each other, the rear end of the first guide wire is connected to insertion-extraction structure in the rear end of the operation portion, the second guide wire is fixed to the inside of the catheter by a fixing process. The guide wire of the dilatable balloon catheter and the liquid injection lumen can share the same lumen, greatly reducing the diameter of the catheter in the present invention, so that the dilatable balloon catheter can be inserted into a narrow duct or lumen that needs to be expanded in human body through an device channel of an endoscope, and realize visualization operation.

A guide extension catheter with improved stability includes an elongated pushing portion connected to an extension portion with a balloon disposed near its distal end. An inflation lumen extends along a length of the pushing portion and the extension portion to feed fluid into an interior of the balloon. Introduction of fluid into the balloon expands it radially outward from the extension to apply pressure against an inner wall of the vessel to anchor the distal end of the extension within the vessel.

In some examples, a catheter includes an elongated member including at least one balloon connected to the elongated member, the at least one balloon being configured to inflate to an expanded state. In the expanded state, the at least one balloon forms at least a portion of a cavity with a wall of a vessel of the patient. The catheter including at least one electrode carried by the elongated member and having at least one surface exposed to the cavity formed by the at least one balloon. The electrode is configured to connect to an energy source that is configured to deliver, via the electrode, an electrical signal to a fluid contained in the cavity and in contact with the electrode to cause the fluid to undergo cavitation to generate a pressure pulse wave within the fluid.

The present disclosure discloses a guide extension catheter device. The catheter device includes an elongated body having at least one of a distal portion, a proximal portion, and a middle portion. The middle portion extends between the distal portion and the proximal portion. In an aspect, the distal portion comprises a first part and a second part. The first part is disposed at a distal end of the distal portion and the second part is disposed at a proximal end of the distal portion. The first part of the distal portion is cylindrical in shape and the second part is tapered such that a diameter of a second part proximal end is greater than a diameter of a second part distal end. The catheter device also integrates a built-in balloon at the first part of the distal end.

Balloon catheter devoid of guidewire or guidewire lumen and having a proximal shaft with only a single continuous lumen. A coil assembly is mounted at its proximal end to the distal end of the proximal shaft defining an interface therebetween. Disposed about a distal section of the proximal shaft and a proximal section of the coil assembly is a sleeve. A balloon, having a vent hole, forms a proximal leg seal about an outer surface of a distal end of the sleeve and an opposite distal leg seal. The sleeve covers the interface and extends axially in a distal direction terminating underneath the proximal leg seal of the balloon. A distal section of the coil assembly at least partially coincides with the distal leg seal of the balloon. A wire member secured at a plurality of connection points along the coil assembly extends axially within the balloon.

The disclosure includes a balloon guiding sheath that includes an elongated sheath having a proximal end, a distal end opposite the proximal end, an inner tube extending between the proximal end and the distal end, an outer tube surrounding the inner tube and extending between the proximal end and the distal end, an access port located adjacent in the proximal end, a distal port located adjacent the distal end, and a working lumen extending through the elongated sheath between the access port and the distal port. The balloon guiding sheath also includes an inflatable balloon located on an outer surface of the elongated sheath adjacent the distal end, the inflatable balloon being fluidly coupled to an inflation lumen extending between the inflatable balloon and an inflation port located adjacent the proximal end.

Disclosed is a multifunctional convertible catheter and methods of use, said multifunctional convertible catheter capable of performance of both diagnostic angiography while containing a guide wire throughout its lumen and angioplasty, and also being convertible between over-the-wire or rapid exchange configurations by manipulation of said multifunctional catheter and said guide wire by an operator. Whether used in an over-the-wire or rapid exchange configuration, a multifunctional convertible catheter disclosed herein allows the operator to perform angioplasty at any site in the body without use of an exchange length guide wire, without the need to exchange said convertible angioplasty balloon catheter for a diagnostic catheter pre- or post-angioplasty, without the need of an injectable vascular sheath, all while reducing catheter inventory requirements for the health care system.

A balloon embolization apparatus, system and method include a detachable balloon device mounted to the distal end of a catheter or microcatheter. The balloon device includes an elongated cannula having first and second axial lumens defined in the cannula, one lumen which allows for travel over a wire, an inflatable balloon disposed on the cannula, and a valve sleeve disposed between the balloon and the cannula. An inflation port on the cannula allows fluid to be introduced to the balloon via a channel in the catheter. The valve sleeve includes a vent offset from the inflation port in the cannula. The valve sleeve allows the introduced fluid to inflate the balloon, but prevents the fluid from escaping, thereby forming a check valve. Once inflated, the catheter is detached from the balloon apparatus. When the catheter is withdrawn, the balloon remains in place to allow for embolization.