Abstract: A method of manufacturing a stent includes determining a porosity characteristic and combining at least two predetermined alloy constituents based on the porosity characteristic. The method further determines a solidification profile based on the porosity characteristic and combined alloy constituents and solidifies the combined alloy constituents based on the solidification profile. In addition, the method includes forming a stent framework from the solidified alloy constituents, removing at least a portion of at least one of the alloy constituents, and forming pores within the stent framework based on the removal and consistent with the porosity characteristic.

Abstract: A system for treating a vascular condition includes a catheter and a stent disposed on the catheter. The stent includes tubing having a wall defining a central lumen and a plurality of holes. The system further includes a therapeutic agent disposed within the central lumen of the tubing. A method of manufacturing a therapeutic agent carrying stent includes inserting a therapeutic agent within a therapeutic agent delivery system into the central lumen of a hollow metal tube and forming a stent framework from the hollow tube.

Abstract: A system for treating abnormalities of the cardiovascular system includes a stent having a plurality of therapeutic agent-carrying regions and non therapeutic agent-carrying regions. The therapeutic agent-carrying regions are located within low strain regions of the stent and the non therapeutic agent-carrying regions are located within high strain regions of the stent. Another embodiment of the invention includes a method of manufacturing a therapeutic agent-carrying stent comprising forming a stent framework and applying a formulation containing one or more therapeutic agents to the stent framework while preventing the therapeutic agents from contacting the high strain regions of the stent framework.

Abstract: A balloon-expandable stent formed from a customized alloy formulation. The stent alloy has a either a high, variable or no work hardening rate, very high modulus of elasticity (Young's modulus), and a low yield point. A stent constructed of a material with this combination of properties undergoes significant plastic deformation upon deployment in vivo to its implantation diameter and exhibits minimum recoil for better sizing. The plastic deformation also raises the subsequent yield point of the stent material resulting in a stronger stent upon implantation that is more resistant to vascular loading.

Abstract: A valve replacement system that can be used for treating abnormalities of the right ventricular outflow tract includes a prosthetic valve device having a sealant contacting at least a portion of the outer surface of the valve device. The sealant may be breakable, and may be a hydrogel, an expandable hydrogel, or a solid. One embodiment of the invention includes a flowable sealant that is injected within the vascular system. Another embodiment of the invention includes a method for replacing a pulmonary valve that includes forming a seal around the exterior surface of a replacement valve and preventing blood flow around the replacement valve.

Abstract: A system and method for treating a vascular condition includes a conduit having an elongate tubular member with an outer surface and an inner surface, the inner surface defines a conduit lumen. The system further includes at least one symmetry indicator attached to the elongate tubular member and a replacement valve device. The replacement valve device includes a prosthetic valve connected to an expandable support structure. The replacement valve device is positioned within the conduit lumen adjacent the inner surface.

Abstract: A balloon-expandable stent formed from a customized alloy formulation. The stent alloy has a either a high, variable or no work hardening rate, very high modulus of elasticity (Young's modulus), and a low yield point. A stent constructed of a material with this combination of properties undergoes significant plastic deformation upon deployment in vivo to its implantation diameter and exhibits minimum recoil for better sizing. The plastic deformation also raises the subsequent yield point of the stent material resulting in a stronger stent upon implantation that is more resistant to vascular loading.

Abstract: This invention relates to an implantable medical device to treat a patient. The implantable device can be an orthopedic device such as a spinal implant including, but not restricted to, a disc or nucleus pulposus prosthesis, a spinal rod assembly, or a bone fixation plate. The orthopedic device can be formed to include a metal matrix composite that provides enhanced wear and diagnostic imaging techniques. In other forms, the present invention provides an implantable medical device that includes a porous metal matrix composite that can deliver a therapeutic composition to a patient. In still other forms, the present invention provides an implantable electrical device or lead formed to include a metal matrix composite that provides lower polarization and interfacial impedance and allows enhanced sensing of the physiological signals.

Abstract: Wet-tantalum capacitors used in a medical device are charged to and maintained at a maintenance voltage between full energy charges so that deformation in the wet-tantalum capacitor is substantially inhibited.

Abstract: Described are artificial disc implants for insertion between first and second adjacent vertebrae in a patient. The implants have a first member and a second member in articulating relationship. At least one member of the implant includes an amorphous metal element. Also described are related methods of making and using artificial disc implants.

Abstract: This invention relates to a metal composite orthopedic device. The device can comprise a metallic substrate cladded or joined to one or more metallic layer(s). The substrate and metallic layer(s) can be selected of different metals and metal alloys to provide desired wear performance, imaging characteristics and optionally to serve as a reservoir for therapeutic agents.

Abstract: High oxidation state metal-containing compounds are formed on or applied to the surfaces of medical devices. These compounds can cause cytostatic, cytotoxic, and anti-proliferative effects to the cells on or near the implanted medical devices and thus reduce or eliminate undesirable cell growth or accumulation on the medical devices.

Abstract: Manufacturing methods are provided to build modulated medical devices and segments of the devices for applications in the field of intraluminal intervention, reconstruction, or therapy. The methods, comprise steps of metal injection molding and processes of modulation, improve the manufacturability of the devices and/or expand the design alternatives for the devices. The modulated medical devices and their segments, made from the present method inventions, enhance the versatility in intraluminal treatments.

Abstract: This invention relates to an implantable medical device to treat a patient. The implantable device can be an orthopedic device such as a spinal implant including, but not restricted to, a disc or nucleus pulposus prosthesis, a spinal rod assembly, or a bone fixation plate. The orthopedic device can be formed to include a metal matrix composite that provides enhanced wear and diagnostic imaging techniques. In other forms, the present invention provides an implantable medical device that includes a porous metal matrix composite that can deliver a therapeutic composition to a patient. In still other forms, the present invention provides an implantable electrical device or lead formed to include a metal matrix composite that provides lower polarization and interfacial impedance and allows enhanced sensing of the physiological signals.