Abstract: A medical implant has a microscopically rough outer coating that serves to bond the implant to animal tissue. The coating is applied to the implant by physical vapor deposition. The coating preferable is applied via a generally oblique coating flux or a low energy coating flux. In some embodiments, the coating has pores. The pores can contain a drug, which can diffuse over a period of time. The coating may be partially nonporous to protect the implant from corrosion. The coating can have an outer porous layer that can bond with animal tissue easily.

Abstract: A medical device has a porous radiopaque coating that can withstand the high strains inherent in the use of such devices without delamination. A coating of Ta is applied to a medical device, such as a stent, by vapor deposition so that the thermomechanical properties of the stent are not adversely affected. The coating preferable has high emissivity.

Abstract: A method of manufacturing a medical device having interior and exterior surfaces, the method including the steps of: a) shielding the exterior surface; and, b) exposing the interior surface to a plasma, wherein the shielding of the exterior surface substantially prevents exposure of the exterior surface to the plasma.

Abstract: An in-situ plasma cleaning device (PCD) performs an atomic surface cleaning process to remove contaminants and/or to modify the cylindrical surfaces of both the target and substrate. The atomic cleaning process utilizes a plasma generated locally within the in-situ plasma cleaning device with suitable properties to clean both the target and substrate cylindrical surfaces either concurrently or separately. Moreover, the in-situ plasma cleaning device is designed to traverse the length of the target and the substrate cylindrical surfaces during the cleaning process.

Abstract: An inhomogeneous surface is formed on a substrate, such as an orthopedic implant or other surface upon which cell growth is desired, by depositing a discontinuous coating of atoms on the substrate and etching the substrate. The difference in etch rates between the coating and the substrate will produce structures in the nanometer scale. Deposition and etch conditions can be chosen to create structures of a specific size to preferentially bind to specific biological materials.

Abstract: A medical device has a porous metallic coating that can withstand the high strains inherent in the use of such devices without delamination. A coating of the metal is applied to a medical device, such as a stent, by vapor deposition so that the thermomechanical properties of the stent are not adversely affected. The coating preferable has high emissivity. The coating is applied via a generally oblique coating flux or a low energy coating flux.

Abstract: A system and method for coating implantable medical devices so that they do not interfere with MR imaging are described. Using any of the coating processes well known to those skilled in the art, e.g., physical vapor deposition such as evaporation, sputtering, or cathode arc, or chemical vapor deposition, spraying, plasma polymerization, plasma enhanced chemical vapor deposition and the like, multiple sources, including at least one source of an electrically insulating material and at least one source of an electrically conducting material, are oriented and shielded so as to coat separate sections of the implantable medical device. The object being coated is then rotated so that overlapping spiral coatings of the materials from the different coating sources are produced on the object.

Abstract: A plurality of coated layers is disposed on an implanted device. The materials and electrical parameters of the coated layers are chosen and the geometry of the coated layers is arranged so that incident electromagnetic radiation induces currents in the coated layers that have a predetermined phase and amplitude relationship with the current induced in the implanted device.

Abstract: An implantable electrode has a biomedically compatible, microscopically rough, metal coating that creates a high double-layer capacitance. The coating is applied to the implant by physical vapor deposition. The coating preferably is applied via a generally oblique coating flux or a low energy coating flux. In some embodiments, the coating has pores. The pores can contain a drug, which can diffuse over a period of time. The coating may be partially nonporous to protect the implant from corrosion.

Abstract: A medical implant has a microscopically rough outer coating that serves to bond the implant to animal tissue. The coating is applied to the implant by physical vapor deposition. The coating preferable is applied via a generally oblique coating flux or a low energy coating flux. In some embodiments, the coating has pores. The pores can contain a drug, which can diffuse over a period of time. The coating may be partially nonporous to protect the implant from corrosion. The coating can have an outer porous layer that can bond with animal tissue easily.

Abstract: A medical device has a porous radiopaque coating that can withstand the high strains inherent in the use of such devices without delamination. A coating of Ta is applied to a medical device, such as a stent, by vapor deposition so that the thermomechanical properties of the stent are not adversely affected. The coating preferable has high emissivity. The coating is applied via a generally oblique coating flux or a low energy coating flux.

Abstract: A medical device has a porous radiopaque coating that can withstand the high strains inherent in the use of such devices without delamination. A coating of Ta is applied to a medical device, such as a stent, by vapor deposition so that the thermomechanical properties of the stent are not adversely affected. The coating preferable has high emissivity.

Abstract: A medical device has a radiopaque coating that can withstand the high strains inherent in the use of such devices without delamination. A coating of Ta is applied to a medical device, such as a stent, by vapor deposition so that the thermomechanical properties of the stent are not adversely affected.

Abstract: An array of unbalanced magnetrons arranged around a centrally-located space for sputter coating of material from target electrodes in the magnetrons onto a substrate disposed in the space. The electrodes are powered in pairs by an alternating voltage and current source. The unbalanced magnetrons, which may be planar, cylindrical, or conical, are arranged in mirror configuration such that like poles are opposed across the substrate space or are adjacent on the same side of the substrate space. The magnetrons are all identical in magnetic polarity, such that there is no magnetic coupling between either opposed or adjacent magnetrons. A positive plasma potential produced by the AC driver prevents electrons from escaping to ground along the unclosed field lines, increasing plasma density in the background working gas and thereby improving the quality of coating being deposited on the substrate.

Abstract: An array of unbalanced magnetrons arranged around a centrally-located space for sputter coating of material from target electrodes in the magnetrons onto a substrate disposed in the space. The electrodes are powered in pairs by an alternating voltage and current source. The unbalances magnetrons, which may be planar, cylindrical, or conical, are arranged in mirror configuration such that like poles are opposed across the substrate space or are adjacent on the same side of the substrate space. The magnetrons are all identical in magnetic polarity. A positive plasma potential produced by the AC driver prevents electrons from escaping to ground along the unclosed field lines, increasing plasma density in the background working gas and thereby improving the quality of coating being deposited on the substrate.

Abstract: A sputtering cathode comprising a concave surface for receiving and supporting a sputtering target having a substantially conformal concave shape. The cathode is cooled via passage of a suitable coolant through passageways within the cathode. The target is constrained to the cathode along the target periphery. The target expands thermally during sputtering, but being constrained laterally the target is forced into intimate contact with the cooled concave cathode surface. The target is thus cooled over its entire surface, resulting in predictable, uniform erosion rates and target wear, whereas prior art planar cathodes are known to suffer from undesirable buckling of the target away from the cathode due to thermal expansion of the target in use. Cathodes and targets in accordance with the invention are non-planar and preferably are either spherically or cylindrically concave.

Abstract: A cylindrical magnetron having a cylindrical cathode surrounding a cylindrical target. The cathode is without features extending inwards thereof at either end such that the target may be axially removed from or installed into the cathode from either end. The target is positioned and axially retained within the cathode by resilient means operative between the outer surface of the target and the inner surface of the cathode. The invention is especially useful in magnetron assemblies having a plurality of abutting, coaxially disposed magnetrons, wherein all the targets may be removed and replaced from the cathode assembly without requiring disassembly and reassembly of the cathodes.

Abstract: An array of unbalanced magnetrons arranged around a centrally-located space for sputter coating of material from target electrodes in the magnetrons onto a substrate disposed in the space. The electrodes are powered in pairs by an alternating voltage and current source. The unbalances magnetrons, which may be planar, cylindrical, or conical, are arranged in mirror configuration such that like poles are opposed across the substrate space or are adjacent on the same side of the substrate space. The magnetrons are all identical in magnetic polarity. A positive plasma potential produced by the AC driver prevents electrons from escaping to ground along the unclosed field lines, increasing plasma density in the background working gas and thereby improving the quality of coating being deposited on the substrate.

Abstract: Apparatus for creating subatmospheric high plasma densities in the vicinity of a substrate in a work space for use in magnetron sputter deposition aided by ion bombardment of the substrate. Unbalanced flux lines emanating from cylindrical or frusto-conical targets cannot be captured across the work space, because the energizing magnets are cylindrical, and instead converge toward the axis of the apparatus to provide a high flux density, and therefore a high plasma density, in the vicinity of a substrate disposed in this region. The plasma profile and the coating material profile within the work space are both cylindrically symmetrical, resulting in a consistent and predictable coating on substrates.

Abstract: A hollow cathode magnetron for sputtering target material from the inner surface of a target onto an off-spaced substrate. The magnetron is in the shape of a truncated cone, also known as a conical frustum. The target cone is backed by a conical cathode maintained at a predetermined voltage for attracting gas ions into the inner surface of the target cone to sputter material therefrom. The sputtering plasma is made uniform over the entire surface of the target by assuring that the magnitude of the component of the magnetic field tangent to the target surface is constant. The plasma is further confined to the vicinity of the target by using electrostatic elements. Sputter coatings on planar substrates can achieve areal thickness nonuniformities of less than +/−0.2%.