Abstract: A prosthesis, and method for forming same, are provided which includes expanded polytetrafluoroethylene (ePTFE) tubes having angularly offset node and fibril configurations. Also, the node and fibril configurations are angularly offset from the longitudinal axes of the respective tubes, providing resistance against failure in the longitudinal direction.

Abstract: A differentially expanded vascular graft for implantation within a body includes a PTFE tube formed of a homogeneous material. The PTFE tube has a longitudinal first portion which has been longitudinally expanded, and a longitudinal second portion which has been longitudinally expanded. The first and second portions have respective microstructures which are different from one another. A method and apparatus for making the differentially expanded vascular graft of the present invention facilitates the formation of the various expanded portions of the PTFE tube.

Abstract: The vascular graft includes a PTFE tube having non-expanded portions formed from sintering a PTFE green tube extrudate. The non-expanded portions are distributed longitudinally along the PTFE tube. The PTFE tube also has expanded portions formed subsequent to the sintering of the PTFE green tube extrudate. The expanded and non-expanded portions are integral with one another, and alternate with one another along the length of the PTFE tube. The expanded and non-expanded portions each have a respective stiffness, where the stiffness of the non-expanded portion is greater than that of the expanded portion.

Abstract: The smart textile vascular graft is used with an electrical control unit. The vascular graft includes a tube structure formed of a textile material. At least one active fiber is incorporated in the textile material. The active fiber provides electrical coupling thereof to the electrical control unit to provide for transmission of a control signal between the active fiber and control unit. The active fiber has at least one physical characteristic which is variable and corresponds to the control signal to provide communication between the active fiber and electrical control unit relating to the physical characteristic.

Abstract: The vascular graft is for implantation within a body and has a PTFE tube structure including a length and inner and outer wall surfaces. The tube structure has a non-expanded portion formed from sintering a PTFE green tube extrudate and an expanded portion formed subsequent to the sintering. The expanded and non-expanded portions are of the same extrudate. The expanded portion has a region which adjoins the non-expanded portion wherein a degree of expansion of the region is limited by the non-expanded portion. The limiting of the expansion by the non-expanded portion is attenuated at a location of the region which is remote from the non-expanded portion. A method for making the vascular graft facilitates the formation of the non-expanded and expanded portions of the PTFE tube structure.

Abstract: The present invention is a tunneling device for vascular tunneling procedures. The invention includes a tunneling device and a tunneling tip. The tunneling device includes a tissue-separating source of energy at the tunneling tip. The preferred source of energy is ultrasonic movement at the distal tip of the tunneler. Preferably the ultrasonic driver is disposed in a removably attached tip but it may be in the tunneler handle. Also included is a method of tunneling which includes separating tissue layers as the tunneler is advanced. The preferred method uses an ultrasonically vibrating tip.

Abstract: An apparatus is provided for securing a graft to a tunneler during implantation of the graft subcutaneously for vascular access. The apparatus includes an elongated member adapted to be tunneled subcutaneously from an entry point at a first location on the skin surface of a patient to an exit point at a second location on the skin surface of the patient. The elongated member includes a proximal end and a distal end. The apparatus further includes a graft engagement portion at the proximal end of the elongated member. The graft engagement portion includes at least one proximally facing surface adapted to slideably receive, in a direction toward the distal end, the inner surface of a graft. The graft engagement portion further includes at least one radially projecting element adapted to resist movement of the graft, after the graft has been received over the proximally facing surface, in a direction toward the proximal end.

Abstract: The present invention provides an implantable graft, including a primary tubular body having a first outer wall surface and a first inner wall surface defining a primary blood contacting lumen, and a secondary tubular body having a second outer wall surface and a second inner wall surface. The secondary tubular body is located about the primary tubular body to form a space therebetween. The primary and secondary tubular bodies are joined by at least one rib.

Abstract: An implantable microporous ePTFE tubular vascular graft exhibits long term patency, superior radial tensile strength and suture hole elongation resistance. The graft includes a first ePTFE tube and a second ePTFE tube circumferentially disposed over the first tube. The first ePTFE tube exhibits a porosity sufficient to promote cell endothelization, tissue ingrowth and healing. The second ePTFE tube exhibits enhanced radial strength in excess of the radial tensile strength of the first tube.

Abstract: A method of making an ePTFE tubular structure includes the steps of

Abstract: An implantable microporous ePTFE tubular vascular graft exhibits long term patency, superior radial tensile strength and suture hole elongation resistance. The graft includes a first ePTFE tube and a second ePTFE tube circumferentially disposed over the first tube. The first ePTFE tube exhibits a porosity sufficient to promote cell endothelization, tissue ingrowth and healing. The second ePTFE tube exhibits enhanced radial strength in excess of the radial tensile strength of the first tube.

Abstract: An improved ePTFE material and method of preparing the improved ePTFE material provides a tubular structure with enhanced axial elongation, radial expansion, and physical recovery characteristics.

Abstract: An improved ePTFE material and method of preparing the improved ePTFE material provides a tubular structure with enhanced axial elongation, radial expansion, and physical recovery characteristics.

Abstract: An implantable microporous ePTFE tubular vascular graft exhibits long term patency, superior radial tensile strength and suture hole elongation resistance. The graft includes a first ePTFE tube and a second ePTFE tube circumferentially disposed over the first tube. The first ePTFE tube exhibits a porosity sufficient to promote cell endothelization, tissue ingrowth and healing. The second ePTFE tube exhibits enhanced radial strength in excess of the radial tensile strength of the first tube.

Abstract: An implantable microporous ePTFE tubular vascular graft exhibits long term patency, superior radial tensile strength and suture hole elongation resistance. The graft includes a first ePTFE tube and a second ePTFE tube circumferentially disposed over the first tube. The first ePTFE tube exhibits a porosity sufficient to promote cell endothelization, tissue ingrowth and healing. The second ePTFE tube exhibits enhanced radial strength in excess of the radial tensile strength of the first tube.

Abstract: An implantable microporous ePTFE tubular vascular graft exhibits long term patency, superior radial tensile strength and suture hole elongation resistance. The graft includes a first ePTFE tube and a second ePTFE tube circumferentially disposed over the first tube. The first ePTFE tube exhibits a porosity sufficient to promote cell endothelization tissue ingrowth and healing. The second ePTFE tube exhibits enhanced radial strength in excess of the radial tensile strength of the first tube.

Abstract: An implantable microporous ePTFE tubular vascular graft exhibits long term patency, superior radial tensile strength and suture hole elongation resistance. The graft includes a first ePTFE tube and a second ePTFE tube circumferentially disposed over the first tube. The first ePTFE tube exhibits a porosity sufficient to promote cell endothelization tissue ingrowth and healing. The second ePTFE tube exhibits enhanced radial strength in excess of the radial tensile strength of the first tube. The stent provides patency to the endoprosthesis.

Abstract: An implantable microporous ePTFE tubular vascular graft exhibits long term patency, superior radial tensile strength and suture hole elongation resistance. The graft includes a first ePTFE tube and a second ePTFE tube circumferentially disposed over the first tube. The first ePTFE tube exhibits a porosity sufficient to promote cell endothelization tissue ingrowth and healing. The second ePTFE tube exhibits enhanced radial strength in excess of the radial tensile strength of the first tube.