An apparatus and methods for tissue restoration are provided. The apparatus may include a catheter shaft extending from a proximal end to a distal tip, the catheter shaft defining lumens including an inflation lumen and a light fiber lumen, a coated balloon positioned on a translucent distal segment of the catheter shaft proximal to the distal tip in fluid communication with the inflation lumen, the coated distal balloon comprising a translucent material and a coated material on an outer surface of the coated balloon, and a light fiber positioned in the catheter shaft in the light fiber lumen and extending through the translucent distal segment.

An apparatus and methods for tissue restoration are provided. The apparatus may include a catheter shaft extending from a proximal end to a distal tip, the catheter shaft defining lumens including an inflation lumen and a light fiber lumen, a coated balloon positioned on a translucent distal segment of the catheter shaft proximal to the distal tip in fluid communication with the inflation lumen, the coated distal balloon comprising a translucent material and a coated material on an outer surface of the coated balloon, and a light fiber positioned in the catheter shaft in the light fiber lumen and extending through the translucent distal segment.

A catheter may include an elongated tube enclosing at least one catheter lumen, and a centering device coupled to a distal end of the elongated tube, wherein the centering device includes a plurality of legs. Each leg of the plurality of legs may include a first end fixed to an outer surface of the elongated tube. Each leg of the plurality of legs may include an outward bias such that a central portion of each leg of the plurality of legs is spaced radially outward from the elongated tube when the centering device is in an expanded state.

Valves and valve systems are provided that are useful for integration with inflatable indwelling medical devices to prevent over-inflation of retention balloon.

Disclosed is an inter- and intra-catheter flow device for the management of vascular bleeding disorders that provide a liquid flow-pass between proximal and distal balloons for bridging the circulation between the upper and lower segments of a hemorrhaging artery or blood vessel, while blocking the blood flow to the hemorrhaging middle segment(s) of the artery or blood vessel between the two or more balloons. When only one balloon is inflated, these devices can create a pressure gradient between proximal or distal and middle segments of the artery or blood vessel. These devices are useful for controlling proximal artery blood pressure, preventing distal ischemia-reperfusion injury, identifying the bleeding location, controlling the bleeding, repairing and remodeling vascular structures, extending resuscitative endovascular balloon occlusion of the aorta (REBOA) use duration, and performing fluid resuscitation.

An infusion catheter includes a housing, a proximal shaft assembly, a first distal shaft assembly and a second distal shaft assembly. The housing has one or more inflation ports and one or more infusion ports. The proximal shaft assembly supports a first balloon. The first distal shaft assembly extends distally from the proximal shaft assembly and supports a first distal balloon. The second distal shaft assembly extends distally from the proximal shaft assembly and supports a second distal balloon. The first and second distal shaft assemblies define infusion openings in fluid communication with the one or more infusion ports. The infusion catheter may be inserted into a uterine cavity to occlude tubal ostia and an internal cervical OS of the uterine cavity for sealing the uterine cavity. A therapeutic agent may be delivered through the infusion catheter and into the sealed uterine cavity to treat the uterine cavity.

The invention relates to a method for reducing the outer diameter of the balloon (1) of a balloon catheter in the non-expanded state, wherein at least one restriction element (3) is applied to at least a portion of the balloon (1) of the balloon catheter. In this way, the outer diameter of the balloon (1) is thus reduced and, moreover, its flexibility increased.

An hourglass shaped three-chambered and tunneled balloon catheter suitable for use in the placement of an aortic valve during the transcatheter aortic valve implantation (TAVI) process.

A balloon catheter is provided with a main tube and an air tube therein. The main tube is provided with a central lumen to allow the balloon catheter to travel across and be guided along a guidewire during insertion into a vasculature of a patient. The air tube is configured to transfer fluid, such as air, to a balloon for inflating and deflating the balloon. The air tube can be embedded within the inner and outer surfaces of the main tube. Holes are cut into the main tube and a portion of the air tube to expose the air tube to the environment outside of the main tube. The holes allow for fluid communication between the air tube and the balloon. The holes are cut or sheared at a direction that is lateral to the longitudinal direction of the catheter tube.

A balloon catheter is provided with a main tube and an air tube therein. The main tube is provided with a central lumen to allow the balloon catheter to travel across and be guided along a guidewire during insertion into a vasculature of a patient. The air tube is configured to transfer fluid, such as air, to a balloon for inflating and deflating the balloon. The air tube can be embedded within the inner and outer surfaces of the main tube. Holes are cut into the main tube and a portion of the air tube to expose the air tube to the environment outside of the main tube. The holes allow for fluid communication between the air tube and the balloon. The holes are cut or sheared at a direction that is lateral to the longitudinal direction of the catheter tube.