A tubular construct that includes a braided tube embedded therein is disclosed herein. The braided tube may be embedded between layers of the tubular construct or may alternatively be positioned flush with the inside of the tubular construct. The tubular construct is resistant to kinking and has enhanced radial strength. The braided tube reinforces the wall of the tubular construct by improving burst pressure resistance, tube strength, and torque transmission. When radial pressure is applied to the braided tube that is embedded in the construct, the braided tube cannot expand lengthwise. Thus, the compression strength of the construct is increased in the radial direction. This feature takes advantage of the same principle used in the children's toy colloquially known as a Chinese finger trap. The increased radial strength of the tubular construct prevents the construct from collapsing and thereby enhances its structural integrity.

Provided is an artificial bladder including: a main body which includes an inlet port, an outlet port, and a predetermined reservoir portion configured to store urine between the inlet port and the outlet port and is formed of a biocompatible polymer that is expandable so that a volume of the reservoir portion changes according to the amount of urine; a sensor which is attached to an outer wall of the main body, has a surface having a wrinkled structure, and is provided so that, when the volume of the reservoir portion increases, the wrinkled structure stretches out and resistance of the sensor changes; and an actuator which is provided at the outlet port and is configured to discharge the urine according a result detected by the sensor.

An endoprosthesis (1) comprising a body part (2), a first cover sheet (4), and a thrombogenic fiber (5), wherein the (5) fibers are attached to the endoprosthesis (1) by means of a fixation layer (7) and partially arranged between the first cover sheet (4) and the fixation layer (7).

The invention relates to an endoprosthesis (1), in particular a vascular stent or a heart stent, comprising at least one body (3) part. At least one area (5,6) of an outer surface, preferably the whole outer surface, of the at least one body part (3) is provided with thrombogenic fibers (2). The invention further relates to methods of manufacturing endoprostheses (1).

A fluidic bridging tube (1), for bridging membranes in the human or animal body allowing the passage of fluid, has a proximal flange (2), an inter lumen connector (3) with a lumen (5) and a distal flange (4). The tube comprises a metal skeleton or scaffold structure (51) and a surrounding polymer which is softer than the scaffold structure. The scaffold structure (51) has a tubular mesh providing structural strength to the inter lumen connector. The tubular mesh has members (61) defining substantial rectangular mesh apertures, and distal crowns (64). At its proximal end the scaffold structure comprises spines (68) extending from a proximal tubular mesh rim (63). The spines provide structural strength to the proximal flange (2). In the preferred embodiment the tube is a tympanostomy tube. A method of manufacturing the tube comprises providing the scaffold structure and over-moulding the outer material to form the shape of the proximal flange, the inter lumen connector with a lumen, and the distal flange.

An annuloplasty band having a differentiation in area moment of inertia, where the area moment of inertia in the out of plane direction is much less than the area moment of inertia in the plane of the annulus. This makes the band stiff enough to hold the annulus in the correct shape while being flexible enough out of plane to minimize the risk of suture dehiscence or breakage. One example is a C-shaped band with a core formed of nitinol and having a constant cross-section with a wider radial dimension than an axial dimension. The cross-section may be rectangular. The band is asymmetric across a minor axis with one end extending around the anterior side farther than the other. The free ends rise up from adjacent lateral sides, and a continuous posterior mid-section also rises upward.

Methods of producing hybrid fibrous scaffolds are provided. The methods include dissolving a polymer, such as polydioxanone, in a solution, such as 1,1,1,3,3,3-hexafluoro-2-propanol (HFP), to form a polymer-containing solution. The method comprises electrically charging the polymer-containing solution. The method comprises writing the polymer-containing solution on a counter electrode or a ground in a grid pattern to form semi-stable fibers comprised of the polymer, the semi-stable fibers vary between bent and straight and forming the hybrid fibrous scaffold. The writing may be performed by a 3D printer. The resulting scaffolds and methods of using the same are also disclosed herein.

Prosthetic scaffold for regenerative organization of organ tissue for organ function supplementation or replacement and a method for making the prosthetic scaffold by physical vapor deposition of same.

A method of manufacturing a covered stent is disclosed. The method includes winding a first PTFE tape around a cylinder body of a jig, winding a second PTFE tape around a stent including the jig fitted therein, heating the stent in an oven, fitting the stent into upper and lower elastic members, fitting the elastic members into a mold, pressing the upper elastic member to bond the PTFE tapes to each other and to thus form a first film at a cylindrical body of the stent, taking the elastic members out of the mold, taking the stent out of the elastic members, removing the jig from the stent, forming a silicone coating layer at an expansion portion of the stent, and sewing the spaces in the expansion portion, the second PTFE tape, and the silicone coating layer to form a second film at the expansion portion.

The invention relates to a prosthetic heart valve (100) for an endoprosthesis (1) used in the treatment of a stenotic cardiac valve and/or a cardiac valve insufficiency. The prosthetic heart valve (100) comprises of a plurality of leaflets (102), which consist of a natural and/or synthetic material and have a first opened position for opening the heart chamber and a second closed position for closing the heart chamber, the leaflets (102) being able to switch between their first and second position in response to the blood flow through the heart. In addition, the prosthetic heart valve (100) comprises a leaflet support portion (103), consisting of biological and/or synthetic material for mounting of the prosthetic heart valve (100) to a stent (10), and a bendable transition area (104) which forms a junction between the leaflets (102) and the leaflet support portion (103), the transition area (104) progressing essentially in a U-shaped manner similar to a cusp shape of a natural aortic or pulmonary heart valve for reducing tissue stresses during opening and closing motion of the leaflets (102). The invention further relates to an endoprosthesis (1) comprising a prosthetic heart valve (100) and a stent (10).