Hydrophilic coatings including a polymer matrix having voids wherein microparticles having a lubricious liquid are located within the voids.

Methods of making medical devices are described. A method of making a medical device for delivering a bioactive includes preparing a suitable solution comprising the bioactive; placing a vessel containing the solution over a substrate comprising a biocompatible foam and defining open cells; initiating flow of the solution from the vessel and toward the substrate such that the solution exits the vessel and contacts the substrate; and maintaining flow of the solution for an amount of time sufficient to achieve a desired volume of the solution within the substrate. Medical devices made by the methods are also described.

A material, especially a glassy material of pyrophosphate type, corresponding to the general formula (I): {[(M.sup.2+).sub.1−x(R.sup.+).sub.2x].sub.2[(P.sub.2O.sub.7.sup.4−).sub.1−y(PO.sub.4.sup.3−).sub.4y/3]} n(H.sub.2O) in which x and y are positive rational numbers each between 0 and 0.8, and n is such that the weight percentage of water in the material is greater than 0 and less than or equal to 95. M.sup.2+ represents a bivalent ion of a metal chosen from calcium, magnesium, strontium, copper, zinc, cobalt, manganese and nickel, or any mixture of such bivalent ions. R.sup.+ represents a monovalent ion of a metal selected from potassium, lithium, sodium, and silver, or any mixture of such monovalent ions. This material in particular can be used in manufacturing of bone replacements or prosthesis coatings.

Provided are hybrid biomaterials comprising one or more layers of cross-linked poly(propylene fumarate) and/or cross-linked copolymer comprising a plurality of cross-linked propylene fumarate moieties. The layers may further comprise a plurality of microparticles, a plurality of micropores, or both a plurality of microparticles and a plurality of micropores encapsulated within the cross-linked poly(propylene fumarate) and/or cross-linked copolymer comprising a plurality of cross-linked propylene fumarate moieties. One of the layers is disposed on a compliant matrix dense tissue substrate (e.g., a pericardium tissue substrate). The hybrid biomaterials can be used, for example, in method of repairing tissue defects.

A method for coating a medical implant applies at least one coating to at least one surface of the implant by plasma polymerization. The implant has pores sized in the nanometer range. The method stabilizes the pores. The plasma polymerization is conducted in the presence of a coating gas and oxygen. A coating parameter can be selected so that a rough surface of the implant is coated. An implant includes a membrane having pores sized in the nanometer range. A surface of the implant is at least partially coated with a plasma polymer. The interior of the pores is uncoated.

Disclosed is a medical instrument coating, being coated on the surface of a nickel-titanium alloy component of a medical instrument. The medical instrument coating comprises an elementary copper phase, an amorphous titanium-containing substance and a transition layer comprising a copper-nickel intermetallic phase. Also mentioned is a preparation method for the medical instrument coating. A medical instrument comprising a copper-titanium coating has good blood compatibility, and simultaneously can inhibit the endothelialization of the medical instrument surface, thereby improving the recovery rate of the medical instrument and prolonging the recovery time window; the copper-titanium coating belongs to the group of metal composite coatings, has a certain toughness and ductility, and avoids the large-amplitude deformation process of the medical instrument damaging the coating; and the mechanical property and the coating quality of the medical instrument comprising a fine nickel-titanium alloy component are guaranteed by the method for preparing the coating.

A medical textile product includes a textile substrate having opposed first and second surfaces with the textile substrate including a textile construction of one or more yarns. The second surface includes a coating of a substantially water-insoluble, non-porous elastomeric sealant. The one or more yarns at the first surface are pre-treated with a removable composition, such that the water-insoluble elastomeric sealant encapsulates a portion of fibers of the one or more yarns at the second surface of the textile substrate. The textile substrate is substantially impermeable to fluid. The first surface is substantially free of the substantially water-insoluble elastomeric sealant. The textile substrate may be a non-tubular substrate, such as a planar sheet, a shaped sheet, and a tape, or a tubular substrate, such as a cylindrical conduit, a tubular conduit, a Y-shaped, a T-shaped conduit, a multi-channel conduit, and a bulbous shaped conduit.

Methods and devices are provided for promoting wound healing. In general, surgical staplers and stapler components are provided having a coating thereon that is configured to selectively control an interaction between at least one matrix metalloproteinase (MMP) inhibitor and an outer surface of the stapler or stapler component.

Antimicrobial formulations and coatings for medical devices and processes therefor are disclosed. The formulations include at least one water permeable polymer with at least one antimicrobial agent in a liquid medium and are prepared by wet milling the components and can form antimicrobial coatings having uniformly dispersed particles having an average size of no greater than 50 microns.

A method of making a solution including poly(ethylene terephthalate). The method includes dissolving poly(ethylene terephthalate) in a solvent mixture to form a solution, the solvent mixture including two solvent components. A Hansen Solubility Parameter Distance between the solvent mixture and HSP coordinates having a dispersion HSP of 18.02 MPa.sup.0.5, a polar HSP of 5.56 MPa.sup.0.5, and a hydrogen bonding HSP of 14.27 MPa.sup.0.5 is less than about 2 MPa.sup.0.5.