A device for reducing pulsatile pressure within a vessel to treat heart disease, such as pulmonary hypertension, includes a compliant body structured to expand and contract upon changes in pressure within the vessel, a reservoir structured for holding a fluid therein, and a conduit extending between and fluidly coupling the reservoir and the compliant body, wherein the device includes a graphene-polymer composite designed to resist diffusion of the fluid through the device.

Provided herein in some embodiments is an apparatus including a composite balloon with a tubular fiber layer and a polymeric balloon layer over the fiber layer. Also provided herein in some embodiments is a method including inserting a collapsed fiber tube into an expanded polymeric balloon, expanding the collapsed fiber tube to provide an expanded fiber tube, and securing an outer surface of the expanded fiber tube to an inner surface of the expanded polymeric balloon. The method can further include inserting a distal portion of an elongate catheter body through a center of the composite balloon and securing the composite balloon to the distal portion. Thereby, the method can include forming the catheter body with the composite balloon configured to apply a pressure to surrounding walls of an anatomical vessel in an inflated state of the composite balloon to modify one or more intravascular lesions in the anatomical vessel.

Inserts can be formed with elution characteristics to cause the inserts to elute an antimicrobial agent when subject to a fluid within a medical device. An insert can be formed with a desired geometry to allow the insert to be compression fit within a medical device to prevent the insert from moving or becoming dislodged once inserted into the medical device. The material may also be hygroscopic so that the insert swells when subject to a fluid thereby enhancing the compression fit of the device within the medical device. In some cases, the material can be reinforced using an internal structure. Inserts can be formed in many ways including by casting, thermoforming, or extrusion. In some cases, the inserts can be formed using a peel-away sleeve or material. The peel-away sleeves can be formed of a non-sticky material which facilitates removal of the inserts once the inserts have cured.

A radiopaque lined heat shrinkable tubing is disclosed. A non-limiting example of a radiopaque lined heat shrinkable tubing is a multilayer construction having an inner layer and an outer layer, wherein the inner layer includes a thermoplastic that is highly loaded with a radiopaque filler, and the outer layer includes a fluoropolymer heat shrink tube.

Deflectable catheters, hemostasis valves, and materials for the same are disclosed. The deflectable catheters and hemostasis valves can be made at least partially, if not entirely, from a fluoroelastomer and ePTFE combination. A deflectable region of the catheters can be articulated to form simple and/or complex curves.

Described herein are substrates, devices, methods for treating and preventing bacterial and fungal infections, such as infections associated with medical devices, and the like. Materials, substrates and devices of the present disclosure include materials, such as medical grade polymers, having a coating/layer of polyene antimycotic molecules coupled to a surface of the polymer substrate. In certain aspects, substrates and devices of the present disclosure also include a nitric oxide (NO) releasing material also embedded in/coated on the material. Methods of the present disclosure includes methods of making the compositions and/or devices of the present disclosure including materials functionalized with polyene antimycotic molecules and NO releasing materials. Embodiments also include methods of using the materials, substrates, and devices of the present disclosure to treat/prevent fungal and/or bacterial infections in a subject, particularly infections associated with the use of a medical device.

Methods and devices described for improved dynamic walled tubing and catheters.

Methods and devices described for improved dynamic walled tubing and catheters.

The present invention relates to a method of preparing reduced graphene oxide, incorporation of the reduced graphene oxide into polyisoprene latex to provide a polyisoprene latex graphene composite and elastomeric articles prepared using the polyisoprene latex-graphene composite. In particular, the reduction of graphene oxide is accomplished without the use of strong reducing agents and organic solvents and incorporation of the reduced graphene oxide into polyisoprene latex is accomplished using room temperature latex mixing method or hot maturation. The resultant composite exhibits good colloid stability and polyisoprene latex films produced from the composite exhibit good mechanical properties with improved ageing resistance.

A tube for a steerable introduction element like a catheter, an endoscope or a sheath includes composite material of a shape memory alloy material and a non-shape-memory polymer material. The tube is used for making the introduction element steerable in a relatively easy way by modifying the temperature of the tube as required for achieving a preferred bending of the introduction element.