A system for use with an endoscopic device. The system can include a shaft having a proximal end, a distal end, and at least one output port, wherein a portion of the shaft is surrounded by a single polyurethane expandable material, wherein the polyurethane expandable material is expandable from a diameter of at least approximately 5.0 mm to a diameter of approximately 25 mm. The system can also include a manifold connected to the proximal end of the shaft, the manifold including one or more fluid coupling ports for receiving an injected fluid, wherein at least one of the one or more fluid coupling ports is in fluid communication with the at least one output port and wherein when received, the system is configured to convey the injected fluid from the manifold to the shaft resulting, at least in part, in expanding the polyurethane expandable material.

A method for performing a medical procedure requiring effective, reliable and foolproof delivery of controlled amounts of a medical grade gas to a patient includes providing a compressed gas cylinder having a weight with medical grade gas sealed therein of at least twelve grams and not greater than fifty grams. The method also includes connecting the compressed gas cylinder to an integrated compressed gas unit including a regulator valve assembly positioned between an outlet port and an inlet port, wherein the regulator valve assembly includes a press button actuator and regulator adjustment dial. A flow control system is secured to the compressed gas unit and the medical grade gas is delivered in precisely controlled amounts by actuating the compressed gas unit and operating the flow control system to deliver the medical grade gas to vasculature of the patient.

A catheter (1) has a distal side and a proximal side and includes a tip part (10) and a main body part (20) disposed proximal to the tip part (10), the main body part (20) includes a first layer (21) and a second layer (22), the first layer (21) contains 60% by mass or more of an ethylene-tetrafluoroethylene copolymer, the second layer (22) is disposed inside of the first layer (21) in a radial direction of the catheter (1) and contains 60% by mass or more of a polyamide resin, and a cantilever bending load of the tip part (10) is smaller than a cantilever bending load of the main body part (20).

Methods of modifying the luminal profile of a body vessel are described. An example method comprises advancing a cannula out of the distal end of a catheter disposed within the lumen of a body vessel of an animal and toward a target site on the wall of the body vessel; passing contrast dye through the cannula toward the target site; simultaneously continuing the advancing and passing until the distal end of the cannula punctures the inner layer of the wall of the body vessel at the target site; and passing a bulking agent through the cannula and into a space between connective tissue layers surrounding the vessel wall at the target site. Medical devices, medical device assemblies, and kits are also described.

A catheter is provided which includes an outer catheter and an extendable inner catheter. A sealing feature is positioned between the inner catheter and the outer catheter to seal the annular gap between the two while allowing axial translation. The seal may be a compliant protrusion surrounding the inner catheter and may have a chevron-shape for facilitating axial translation. The seal may be a one-way valve configured to allow antegrade flushing but prevent retrograde flow. The seal may be squeegee-like flange on the distal tip of the outer catheter. The seal may be an expandable bulge, which may be mechanically expandable or inflatable or which may be a photosensitive or electrosensitive hydrogel. The seal may include a spring that is radially compressed upon translation or rotation of the inner catheter to transiently break the seal. Also provided is a seal for sealing between the catheter and the vasculature.

An implantable device comprising a nanochanneled membrane is described. The device uses nanofluidics to control the delivery of diagnostic and/or therapeutic agents intratumorally. The devices can be used for chemotherapy, radiosensitization, immunomodulation, and imaging contrast.

A method for using CO.sub.2 as a contrast material in medical imaging procedures is disclosed. The method includes providing a source of pressurized CO.sub.2. The step of providing includes connecting the source of pressurized CO2 to a compressed gas unit for controlling delivery of the CO.sub.2. The method also includes regulating pressure of the CO.sub.2 delivered by the compressed gas unit, transmitting the pressurized CO.sub.2 from the compressed gas unit to a control valve assembly for delivery to a patient in controlled dosages, and sequentially processing the CO.sub.2 with the control valve assembly and delivering the CO.sub.2 to the patient as a contrast media.

A multi-purpose balloon intra-cavity catheter includes a catheter having a proximal end portion, a central portion and a non-branching distal end portion, a plurality of lumens associated with the catheter extending from the proximal end portion, and a plurality of inflatable balloons positioned in the central portion and/or the non-branching distal end portion. Each of the plurality of inflatable balloons is communicatively associated with a corresponding one of the plurality of lumens, the plurality of inflatable balloons being selectively inflated or deflated to position and stabilize the catheter in a cavity for delivery of a medical treatment. The catheter can include an extraction opening associated with a lumen to remove fluids and materials from the cavity, and a connector associated with a corresponding lumen adapted to selectively receive one or more of a fluid medium or a radioactive isotope provided to a corresponding lumen for delivery of the medical treatment.

A device includes a capsule sized to pass through a lumen of a gastrointestinal tract; an enteric coating surround at least a portion of the capsule and configured to protect the capsule form stomach acid while allowing degradation of the capsule in the small intestine of the gastrointestinal tract; a plurality of functionalized particles disposed within the capsule, a plurality of tissue penetrating members configured to puncture a wall of the lumen of the intestinal tract; and an actuator having a first configuration and a second configuration. The actuator is configured to retain the plurality of functionalized particles within the capsule in the first configuration. The actuator is further configured to advance the plurality of functionalized particles from the capsule into a wall of the lumen of the gastrointestinal tract via the plurality of tissue penetrating members by the actuator transitioning from the first configuration to the second configuration.

The present disclosure relates to medical devices that that include the following: a flexible elongate tube having a proximal end and a distal end configured to be directed toward an opening of a body lumen; a first lumen extending from the distal end of the tube proximally along the tube and having a fluid connection for a fluid source at its proximal end; a second lumen extending from the distal end of the tube proximally along the tube, the second lumen configured to accept a guidewire extending along the second lumen; and a wire filament extending along the elongate tube, a distal end of the filament connected to the distal end of the elongate tube, a proximal portion of the wire extending at least partially along the elongate tube, and a distal portion of the wire extending external to the elongate tube.