Abstract: A method of non-delaminably bonding a non-porous thermoplastic elastomer to a substrate by heating a bilayer of the elastomer and the substrate for a predetermined time and a product obtained by the method. Methods for producing non-delaminable conduits and non-delaminable kink-resistant conduits constructed of biocompatible elastomers and substrates, and products produced by these methods are taught. Methods, products, and articles of manufacture relating to non-delaminable monofilament supported kink-resistive conduits that may be used as inflow conduits in left ventricular assist devices for treatment of heart failure are also provided.

Abstract: A novel enhanced liner for prostheses provides for better for either off of the shelf or in customized form, to line a prosthetic used by amputees. Striking a balance between controlling the tear strength and imparting resiliency results in a user friendly product that can be easily donned, and doffed and worn without the drawbacks of the prior art. A unique coating allows the user to remove it like a tubular sock-member, and support comfort and convenience.

Abstract: A novel enhanced process for laser trimming of grafts includes to heat polish the ends. Both heat polish and vapor polish are known processes in plastic processing. When PTFE is used as a graft or covering material, a problem occurs, time and temperature required will distort the ptfe material in the covering of stent graft, A simple solution is the “wetting” of the ends with and aqueous solution of FEP or PFA. A temperature lower than the melt point of PTFE would be used leaving the graft or covering in tact and unharmed. An aqueous solution of PTFE could also work provided conduction or ironing occurred.

Abstract: A method of non-delaminably bonding a non-porous thermoplastic elastomer to a substrate by heating a bilayer of the elastomer and the substrate for a predetermined time and a product obtained by the method. Methods for producing non-delaminable conduits and non-delaminable kink-resistant conduits constructed of biocompatible elastomers and substrates, and products produced by these methods are taught. Methods, products, and articles of manufacture relating to non-delaminable monofilament supported kink-resistive conduits that may be used as inflow conduits in left ventricular assist devices for treatment of heart failure are also provided.

Abstract: A method of non-delaminably bonding a non-porous thermoplastic elastomer to a substrate by heating a bilayer of the elastomer and the substrate for a predetermined time and a product obtained by the method. Methods for producing non-delaminable conduits and non-delaminable kink-resistant conduits constructed of biocompatible elastomers and substrates, and products produced by these methods are taught. Methods, products, and articles of manufacture relating to non-delaminable monofilament supported kink-resistive conduits that may be used as inflow conduits in left ventricular assist devices for treatment of heart failure are also provided.

Abstract: An improved inflow conduit for an implantable ventricular assist device comprising covering the flexible porous tubular graft body of the conduit with an attached non-porous polymer to produce a non-porous conduit. The flexible conduit has an upstream end and a downstream end, a ventricular attachment structure to which the upstream end of the body connects; and a coupling fitting on the downstream end of the body. Also taught is a combination of the improved inflow conduit with an implantable ventricular assist device. A method for the treatment of congestive heart failure, comprising implanting the implantable ventricular assist device in a patient in need of such treatment, as well as an article of manufacture, comprising packaging material and the implantable ventricular assist device contained within the packaging material are also provided.

Abstract: Stented tubular grafts of expanded, sintered polytetrafluoroethylene (PTFE). The stented PTFE grafts of the present invention include an integrally stented embodiment, an externally stented embodiment, and an internally stented embodiment. In each embodiment, the stent may be either self-expanding or pressure-expandable. Also, in each embodiment, the stent may be coated or covered with a plastic material capable of being affixed (e.g., heat fused) to PTFE. Manufacturing methods are also disclosed by the individual components of the stented grafts are preassembled on a mandrel and are subsequently heated to facilitate attachment of the PTFE layer(s) to one another and/or to the stent. Optionally, the stented graft may be post-flexed and post-expanded following it's removal from the mandrel to ensure that the stented graft will be freely radially expandable and/or radially contractible over it's full intended range of diameters.

Abstract: Stented tubular grafts of expanded, sintered polytetrafluoroethylene (PTFE). The stented PTFE grafts of the present invention include an integrally stented embodiment, an externally stented embodiment, and an internally stented embodiment. In each embodiment, the stent may be either self-expanding or pressure-expandable. Also, in each embodiment, the stent may be coated or covered with a plastic material capable of being affixed (e.g., heat fused) to PTFE. Manufacturing methods are also disclosed by the individual components of the stented grafts are preassembled on a mandrel and are subsequently heated to facilitate attachment of the PTFE layer(s) to one another and/or to the stent Optionally, the stented graft may be post-flexed and post-expanded following it's removal from the mandrel to ensure that the stented graft will be freely radially expandable and/or radially contractible over it's full intended range of diameters.

Abstract: A dilation catheter device comprising a shroud tube having a total preselected diameter effective for use in a preselected body lumen, the shroud tube having a strain relief tube extending therethrough which is adapted to reversibly form a flared, funnel-shape and a collapsed shape for contacting the surface of a dilation balloon, whereby the configuration of the balloon can be altered by altering the position of contact of the distal end of the strain relief tube with the surface of the balloon. Methods for use of the device and articles of manufacture containing the device are also taught.

Abstract: A method of non-delaminably bonding a non-porous thermoplastic elastomer to a substrate by heating a bilayer of the elastomer and the substrate for a predetermined time and a product obtained by the method. Methods for producing non-delaminable conduits and non-delaminable kink-resistant conduits constructed of biocompatible elastomers and substrates, and products produced by these methods are taught. Methods, products, and articles of manufacture relating to non-delaminable monofilament supported kink-resistive conduits that may be used as inflow conduits in left ventricular assist devices for treatment of heart failure are also provided.

Abstract: A dilation catheter device comprising a shroud tube having a total preselected diameter effective for use in a preselected body lumen, the shroud tube having a strain relief tube extending therethrough which is adapted to reversibly form a flared, funnel-shape and a collapsed shape for contacting the surface of a dilation balloon, whereby the configuration of the balloon can be altered by altering the position of contact of the distal end of the strain relief tube with the surface of the balloon. Methods for use of the device and articles of manufacture containing the device are also taught.

Abstract: An improved inflow conduit for an implantable ventricular assist device comprising covering the flexible porous tubular graft body of the conduit with an attached non-porous polymer to produce a non-porous conduit. The flexible conduit has an upstream end and a downstream end, a ventricular attachment structure to which the upstream end of the body connects; and a coupling fitting on the downstream end of the body. Also taught is a combination of the improved inflow conduit with an implantable ventricular assist device. A method for the treatment of congestive heart failure, comprising implanting the implantable ventricular assist device in a patient in need of such treatment, as well as an article of manufacture, comprising packaging material and the implantable ventricular assist device contained within the packaging material are also provided.

Abstract: Drug eluting stented tubular grafts wherein the stent is coated with a coat comprising a composite of at least one biocompatible, pharmaceutically acceptable, bioerodible polymer and at least one therapeutic substance. The polymer may be a polyester. The therapeutic agent may include selective gene delivery vectors, sirolimus, actinomycin-D and paclitaxel. The stented grafts include an integrally stented embodiment and an internally stented embodiment. In each embodiment, the stent may be either self-expanding or pressure-expandable. Further, the stent may comprise a plurality of elements, wherein each said element comprises an undulating linear shape formed into a generally cylindrical configuration, and wherein each said element is connected to an adjacent neighbor element by at least one linear connector. A method for the treatment of cardiovascular disease by implantation of the stented graft, and an article of manufacture, comprising packaging material and the stented graft are also taught.

Abstract: Stented tubular grafts of expanded, sintered polytetrafluoroethylene (PTFE). The stented PTFE grafts of the present invention include an integrally stented embodiment, an externally stented embodiment, and an internally stented embodiment. In each embodiment, the stent may be either self-expanding or pressure-expandable. Also, in each embodiment, the stent may be coated or covered with a plastic material capable of being affixed (e.g., heat fused) to PTFE. Manufacturing methods are also disclosed by the individual components of the stented grafts are preassembled on a mandrel and are subsequently heated to facilitate attachment of the PTFE layer(s) to one another and/or to the stent. Optionally, the stented graft may be post-flexed and post-expanded following it's removal from the mandrel to ensure that the stented graft will be freely radially expandable and/or radially contractible over it's full intended range of diameters.

Abstract: A smooth-walled non-crimped inflow conduit for an implantable ventricular assist system. The conduit has an internally smooth lumen surface for enhanced washing of the conduit under irregular blood flow conditions. The conduit includes a tubular graft body that may be formed of a knitted fabric sealed with bovine collagen or gelatin, or formed of closed structured PTFE. The conduit may include external ribbing or support to prevent inward collapse under negative pressure conditions and also protect against damage from inadvertent physical contact in the operating room. The external support may be bonded to the exterior or formed integrally with the tubular graft body. An outer reinforcement cage may be provided to help prevent gross distortion or damage to the tubular graft body. The ends of the tubular graft body are left unsupported and wrapped around opposed lips of conduit coupling structure to minimize blood contacting surfaces at junctions with other conduits or with the heart.

Abstract: Stented tubular grafts of expanded, sintered polytetrafluoroethylene (PTFE). The stented PTFE grafts of the present invention include an integrally stented embodiment, an externally stented embodiment, and an internally stented embodiment. In each embodiment, the stent may be either self-expanding or pressure-expandable. Also, in each embodiment, the stent may be coated or covered with a plastic material capable of being affixed (e.g., heat fused) to PTFE. Manufacturing methods are also disclosed by the individual components of the stented grafts are preassembled on a mandrel and are subsequently heated to facilitate attachment of the PTFE layer(s) to one another and/or to the stent. Optionally, the stented graft may be post-flexed and post-expanded following it's removal from the mandrel to ensure that the stented graft will be freely radially expandable and/or radially contractible over it's full intended range of diameters.