Abstract: A method for activating silicone rubber surfaces comprising steps of: i) swelling at least the surface of the silicone rubber matrix with a silicone rubber swelling solvent; ii) treating the silicone rubber matrix during or after the swelling with a solution comprising at least a reactive silane, the reactive silane comprising: a) at least one Si—C bond and; b) at least one hydrolytically labile bond linked to at least one of the Si atoms present in the reactive silane and; c) at least one functional group F1 connected via a Si—C bond to the same or an other Si atom present in the reactive silane, the functional group comprising electrophilic and/or nucleophilic moieties, and/or at least one functional group F2 connected via a Si—C bond to the same or an other Si atom present in the reactive silane comprising moieties which become electrophilic or nucleophilic moieties by a mechanism selected from the group consisting of ring opening of a cyclic structure, hydrolysis, displacement or by a migration reaction;

Abstract: In embodiments, medical devices, such stents, can deliver a therapeutic agent to body tissue of a patient. The medical device includes a porous therapeutic layer that is substantially free of a polymer matrix which can withstand expansion or contraction of the medical device, with minimal delamination.

Abstract: A balloon carries a drug in drug-carrying regions, wherein the drug-carrying regions protect the drug during delivery through a patient's vasculature. Once at a target site, the balloon expands, causing the drug-carrying regions to expose the drug to the target site. One drug eluting balloon device includes a longitudinal sheath that defines an interior space having a balloon disposed therein. When the balloon expands, at least one push element at least partially inverts at least one pocket formed on an outer surface of the sheath. This inversion causes a drug contained within the at least one pocket to be released to the target site. In another embodiment, a plurality of bands is provided, each band made of material having a different resistance to elongation. Upon expansion, the bands invert to expose a drug provided on a surface of the bands.

Abstract: The invention discloses a method of coating a medical device. The method includes applying a coating composition on the medical device to form a layer on the medical device. The coating composition includes one or more of one or more biological agents and heparin dissolved in a mixture of a first solvent and a second solvent. The first solvent and the second solvent have different evaporation temperatures. Subsequently, at least a part of one of the first solvent and the second solvent present in the coating composition is evaporated to create a plurality of pores in the layer. Thereafter, one or more drugs are deposited in the plurality of pores. When the medical device is positioned and expanded at a target site, the one or more drugs are released from the plurality of pores.

Abstract: A coated medical device and a method of providing a coating on an implantable medical device result in a medical device having a bio-absorbable coating. The coating includes a bio-absorbable carrier component. In addition to the bio-absorbable carrier component, a therapeutic agent component can also be provided. The coated medical device is implantable in a patient to effect controlled delivery of the coating, including the therapeutic agent, to the patient.

Abstract: This invention uses mesoporous silica nanoparticles and other nanostructured materials to formulate polyacrylate-based bone cement for achieving an enhanced and controlled elution of active ingredients such as antibiotics. This invention overcomes the limitation of low antibiotic release from commercial polyacrylate-based bone cements using for example, PMMA. In certain aspects, the formulation enables a sustained release of antibiotics from the bone cement over a period of 80 days and achieves 70% of total drug release, whereas the commercial antibiotic bone cement (e.g., SmartSet GHV) only releases about 5% of the antibiotics on the first day and subsequently an almost negligible amount. In addition, the mechanical properties of our formulated bone cements are well retained. The inventive bone cement exhibits good antibacterial properties and has very low cytotoxicity to mouse fibroblast cells.

Abstract: The present invention provides polymeric substrates comprising a biocompatible coating and methods of preparation thereof. In particular, the coating may be a ceramic material, especially a calcium phosphate material, which may be functionally graded. The invention provides the ability to apply high quality coatings to polymeric substrates without damaging the substrate (e.g., melting the polymeric material). The functionally graded coating can provide crystalline calcium phosphate near the coating interface with the substrate and provide amorphous calcium phosphate at the outer surface of the coating.

Abstract: An intraocular lens with a hydrophilic polymer coating composition and method of preparing same are provided. Specifically, a composition suitable for reducing tackiness in intraocular lenses is provided wherein an acrylic intraocular lens is treated by vapor deposition with an alkoxy silyl terminated polyethylene glycol polymer composition.

Abstract: A stent is coated by ejecting droplets of a coating substance from a reservoir containing a coating substance. A reservoir housing can have a plurality of reservoir compartments. A transducer is used to eject the coating substance from the reservoir. Energy from the transducer is focused at a meniscus or an interface between the coating substance and another coating substance in the reservoir.

Abstract: Medical devices, and in particular implantable medical devices such as stents and stent delivery systems including catheters, may be coated to minimize or substantially eliminate a biological organism's reaction to the introduction of the medical device to the organism or to treat a particular condition. A dip coating process is utilized to minimize waste and to customize coating thickness and drug loading directly at the clinical site just prior to therapeutic use on a patient. An aqueous latex polymeric emulsion is utilized to coat any medical device to a desired thickness by allowing for successive dipping and drying cycles at the clinical site. In addition, aqueous latex polymeric emulsions pose less of a chance of the bridging phenomenon associated with organic solvent based polymers.

Abstract: A substrate (for example an implantable medical device) is provided with a lubricious surface by grafting onto the surface monomers containing acrylamide groups and then hydrolysing said groups under alkaline conditions, the grafting step being carried out in an aqueous environment.

Abstract: Embodiments of the invention include devices and coatings for devices including coated hydrophobic active agent particles. In an embodiment, the invention includes a drug delivery device including a substrate; and coated therapeutic agent particles disposed on the substrate, the coated therapeutic agent particles comprising a particulate hydrophobic therapeutic agent; and a cationic agent in contact with the particulate hydrophobic therapeutic agent. Other embodiments are also included herein.

Abstract: The present invention relates to a device comprising a substrate based essentially on nitinol and, arranged thereon at least partially, a covering or a coating based on at least one polyphosphazene derivative having the general formula (I), a process for its production, and the use of the device as an artificial implant, vascular or nonvascular stent, catheter, thrombolectomy or embolectomy catheter, fragmentation spindle or catheter, filter, vascular connector, hernia patch, oral, dental or throat implant or urether.

Abstract: The invention provides a biocompatible component having a surface intended for contact with living tissue, wherein the surface comprises particles of metal oxide, said particles having an average particle size of less than 100 nm. A method for the production of such biocompatible component is also provided. It was found that the bioactivity of the biocompatible component was increased compare to a reference in that it induced earlier apatite nucleation in vitro. It is believed that by the biocompatible component may induce early hydroxyapatite nucleation in vivo and thus promote osseointegration of an implant.

Abstract: A method and device for local delivery of water-soluble or water-insoluble therapeutic agents to the surface of a normal or diseased body lumen is disclosed. An expandable structure of a medical disposable device, such as a balloon of a balloon catheter, is coated with an amphiphilic polymer coating comprising a therapeutic agent and an amphiphilic polymer or co-polymer. The medical disposable device is inserted into a body lumen, and expanded to contact the amphiphilic polymer coating against the body lumen. The total solubility of the polymer or co-polymer in vivo prevents any embolic hazard associated with the amphiphilic polymer coating.

Abstract: Methods and compositions are provided that load and encapsulate an agent, such as a protein, in a porous self-healing polymer. A delivery system includes a porous self-healing polymer, an ionic affinity trap within the pores of the self-healing polymer, and an agent associated with the ionic affinity trap. Methods of encapsulating an agent in a polymer include providing a porous self-healing polymer comprising an ionic affinity trap within the pores. The polymer is incubated with an agent having an affinity for the ionic affinity trap. At least a portion of the pores in the polymer are then healed. Active encapsulation of macromolecules at low concentrations may be achieved due to affinity of the agent for the ionic affinity trap within the pores.

Abstract: The invention provides a medical implant device or component thereof comprising a metal substrate, an intermediate coating, and an outer coating of aluminum oxide, as well as a method of making such a medical implant device or component thereof.

Abstract: A method is provided for applying a cover layer (9) to a net structure (4) to be used for medical purposes, in particular a thrombosis filter. The net structure (4) is applied to a planar substrate (1) that covers openings (5) of the net structure on one side, wherein the openings (5) across the uncovered side are filled with a sacrificial material (7), in particular copper. The net structure (4) is lifted from the substrate (1). A cover layer (9) is deposited on the surface previously covered by the substrate, and the sacrificial material (7) is removed.

Abstract: Polymers may include a plurality of tetradecahydroanthracene moieties. Such polymers may be used to make food or beverage containers or medical devices. Food or beverage containers or medical devices may be coated with polymers including a plurality of tetradecahydroanthracene moieties.

Abstract: The present invention relates to the preparation of a hemostatic dressing in the form of a powder that is particularly applicable for stemming severe bleeding and for incorporation of the powder into dressings that can stabilize the site of tissue injury, and simultaneously act as an antimicrobial agent.

Abstract: Various embodiments of methods and devices for coating stents are described herein.

Abstract: A coating system for coating an Insertable Medical Device (IMD) with one or more drugs is disclosed. The coating system includes a spray nozzle unit for coating the IMD with one or more drugs. The IMD includes a guiding member, a coating member and a supporting member. The IMD is passed through a protection tube such that the guiding member is located within the protection tube and an end of the supporting member is connected to a holder to expose the coating member of the IMD to the spray nozzle unit. The protection tube is received by a mandrel fixture which includes a circular disc for holding and rotating the protection tube and the IMD within the protection tube. When the protection tube along with the IMD is rotated, the spray nozzle unit coats the coating member of the IMD with the one or more drugs.

Abstract: In various embodiments, a coated device comprises: a substrate; a film coating at least part of the substrate, which film comprises a multilayer unit comprising a first layer and a second layer associated with one another via a hydrogen bond, wherein the first layer comprises a first natural polymeric material and a hydrogen bond donor and wherein the second layer comprises a second natural polymeric material and a hydrogen bond acceptor; and an agent for delivery associated with the coated device. In various embodiments, a coated device comprises: a substrate; a film coating at least part of the substrate, which film comprises a multilayer unit comprising a tetralayer with alternating layers of opposite charge; and an agent for delivery associated with the coated device.

Abstract: The present invention provides a medical device, preferably a contact lens, which a core material and an antimicrobial metal-containing LbL coating that is not covalently attached to the medical device and can impart to the medical device an increased hydrophilicity. The antimicrobial metal-containing coating on a contact lens of the invention has a high antimicrobial efficacy against microorganisms including Gram-positive and Gram-negative bacterial and a low toxicity, while maintaining the desired bulk properties such as oxygen permeability and ion permeability of lens material. Such lenses are useful as extended-wear contact lenses. In addition, the invention provides a method for making a medical device, preferably a contact lens, having an antimicrobial metal-containing LbL coating thereon.

Abstract: The invention relates to a surgical repair article, comprising a structural member of high performance polyethylene (HPPE) filament(s). The invention also relates to a method of making such a surgical repair article, and to a kit of parts comprising the article. The surgical repair article comprises a structural member of high performance polyethylene (HPPE) filament(s), and a biodegradable coating applied to the surface of the structural member, wherein the coating comprises a sot/gel produced inorganic oxide and a biologically active compound incorporated therein. The article combines high tensile strength, biocompatibility and favourable bioactive compound delivery characteristics.

Abstract: Medical articles with porous polymeric structures and methods of forming thereof are disclosed. The porous structure can have pores sizes that are nanoporous or greater than nanoporous. The porous structure can be a coating or layer of a medical device such as a stent, stent graft, catheter, or lead for pacemakers or implantable cardioverter defibrillators. Additionally, the body of the medical device can be a porous polymeric structure. The porous structure can be made from bioabsorbable polymers. The porous structures can be formed by contacting a polymer with a supercritical fluid.

Abstract: The present invention provides materials and methods that can serve as a prosthetic and/or, for tissue engineer applications, as a supporting matrix in the stabilization of the myocardium.

Abstract: A novel method for producing an otoplastic device is described. In said method, a model of the auditory canal of an individual is made, then a thin film is placed over the model, and said thin film is used for making an accurate copy of the model in a deep drawing process.

Abstract: Methods for modulating the release rate of a drug coated stent are disclosed.

Abstract: A medical device, such as a medical wire, which includes a coating applied to the surface of the medical wire. The coating includes a base layer bonded to the surface of the medical wire and an at least partially transparent low-friction top coat applied to the base layer. The base layer includes heat activated pigments that change color when heated above a color shifting temperature. In one embodiment, the color of the pigment in one area contrasts with the color of the pigment in an adjacent area without otherwise affecting the low-friction surface of the coating. The areas of different color created in locations along the length of the low-friction coated medical wire form markings which, as an example, enable a surgeon to determine the length of the medical wire inserted into a body by observing the markings on the portion of the marked medical wire located exterior to the body.

Abstract: The present invention relates to compositions which are suitable for selective filling or selective coating of folds of a folded balloon, and especially relates to compositions of a contrast agent and an active agent in a solvent for filling of folds of a folded catheter balloon as well as to methods for selective filling or selective coating of folds of a folded catheter balloon and to filled or coated folded catheter balloons which can be obtained according to one of these methods.

Abstract: This invention relates to a method to produce reproducible and homogeneous coatings and to fine-tune the coating morphology. More particularly, the invention relates to a method and apparatus for controlling the particle formation and deposition process to form a biocompatible coating on a medical implant or a tissue.

Abstract: A substrate for biochips is manufactured so that the substrate has a substrate surface having a reaction region capable of reacting with biological substances and a non-reaction region not reacting with the biological substances, sunken bottomed wells formed in the substrate surface, and a layer of a material capable of reacting with the biological substances having a surface exposed only at the bottoms of the bottomed wells, the exposed surface forming the reaction region.

Abstract: A coating having a smooth orange peel morphology is formed on an adluminal surface of a stent, concurrently with the formation of a coating having a rough rice grain morphology on an abluminal surface of the stent. During the formation of the two coatings, a mandrel is placed adjacent to the adluminal surface of the stent but does not generally contact the adluminal surface.

Abstract: An encapsulated bacteriophage formulation and a method for preparing encapsulated bacteriophage formulation is provided. The method for producing the encapsulated bacteriophage composition involves injection of a molten coating substance comprising stearic acid and palmitic acid present at a ratio of 50:50, into a granulator chamber containing immobilized bacteriophages. The immobilized bacteriophage are agitated by rotation of a base of the chamber and swept by a flow of air at a temperature of between 10° C. and 50° C.

Abstract: A medical device includes a base material and chlorhexidine or a pharmaceutically acceptable salt thereof disposed in the base material sufficient to reduce microbial growth. The base material includes a polymer having a silicone monomer and a urethane monomer. To make the medical device having an antimicrobial agent, a silicone-urethane-carbonate polymer is dissolved in Dimethylformamide/Tetrahydrofuran (DMF/THF) to generate a coating solution, a chlorhexidine or a pharmaceutically acceptable salt thereof is mixed into the coating solution, a base material is coated with the coating solution, and the coating solution is dried to remove the solvent. The chlorhexidine is present in concentration sufficient to reduce microbial growth.

Abstract: A nozzle for use in a coating apparatus for the application of a coating substance to a stent is provided. Method for coating a stent can include discharging a coating composition out from a needle of a nozzle assembly, and atomizing the coating composition as the coating composition is discharged. The needle can be positioned in a chamber of the nozzle assembly, and gas can be introduced into the chamber for atomizing the coating composition.

Abstract: An apparatus for coating medical devices at the point of care with a polymer and/or therapeutic agent comprising an environmentally controlled device coating chamber in which the device may be delivered by the manufacturer as the device packaging, or the device may be placed into the chamber at the point of care. The environmentally controlled chamber can provide a sterile enclosure in which the polymer and/or a therapeutic agent can be applied to an uncoated or previously coated device and converted to another form (such as a liquid to a film or gel) if desired, under controlled and reproducible conditions. The environmentally controlled chamber can accommodate and provide for coating the device by immersion, spray and other methods of covering the device surface with a liquid or powder. The chamber can provide for energy sources, both internally, such as heat produced by film heaters, and externally, such as UV light or microwave passing through the enclosure.

Abstract: The present invention provides a porous member formed not by the paste method and a method of producing the porous member. The porous member of the present invention includes a core layer and a porous surface layer, wherein the core layer and the surface layer are composed of the same polymer raw material, the surface layer is formed integrally on a surface of the core layer, and the porous member does not comprise an adhesive layer between the core layer and the surface layer. Such a porous member can be produced by making the surface of a polymer substrate porous. Specifically, the porous member can be produced by immersing the polymer substrate in a solvent capable of dissolving the polymer substrate and freeze-drying the immersed polymer substrate.

Abstract: The present invention relates to a composite matrix that includes a reinforcing textile portion having two surfaces coated over at least 90% of the respective surface areas thereof, by means of at least a first layer including at least one resorbable macro-molecule and having a collagen content of between 50 and 100 wt % relative to the total weight of the first layer; the invention also relates to a prosthesis including such a matrix and to a method for preparing said matrix.

Abstract: A method of securely mounting a stent on a balloon of a catheter. The method generally includes crimping a stent on a balloon of a catheter at least one time, and positioning the balloon with the stent thereon within a polished bore of a mold formed at least in part of a metallic material. The balloon is pressurized and heated within the mold, or within a sheath, in two stages as the stent is restrained from radially expanding. The method may include crimping the stent onto the balloon one or two times during processing. The method increases retention of the stent on the balloon catheter following sterilization.

Abstract: A drug delivery device for delivering therapeutic agents and a method of making such a device is disclosed. The device includes an inflatable balloon. A microporous coating covers a portion of the outer surface of the wall of the balloon. The thickness of the coating and the size of the micropores can permit desirable delivery of a substance from the micropores of the coating and into the tissue of a patient's lumen.

Abstract: Systems and methods for coating medical devices are provided that allow for relatively precise control over the deposition area and coating uniformity with improved efficiency. A microdrop source is used to provide a flow of coating microdrops. A charging electrode disposed near the outlet of the coating source gives each microdrop an electrostatic charge. As the microdrop travels toward the medical device to be coated, a control electrode alters the trajectory of the microdrop. The invention can include a scanner to scan or image the medical device as the coating is applied and a control system to adjust parameters of the deposition process based on information provided by the scanner.

Abstract: The present invention provides novel medical instruments and methods for fabricating them by using nano-technology processes.

Abstract: A tissue thickness compensator may generally comprise a first layer comprising a first biocompatible material sealingly enclosed in a water impermeable material and a second layer comprising a second biocompatible material comprising at least one encapsulation, wherein the first biocompatible material expands when contacted with a fluid. The tissue thickness compensator may comprise a haemostatic agent, an anti-inflammatory agent, an antibiotic agent, anti-microbial agent, an anti-adhesion agent, an anti-coagulant agent, a medicament, and/or pharmaceutically active agent. The encapsulation may comprise a biodegradable material to degrade in vivo and/or in situ. The tissue thickness compensator may comprise a hydrogel. The reaction product may comprise a fluid-swellable composition. Articles of manufacture comprising the tissue thickness compensator and methods of making and using the tissue thickness compensator are also described.

Abstract: Multifilament sutures are prepared by permeating the suture with an antimicrobial solution and applying an antimicrobial coating to the suture.

Abstract: A method for manufacturing a drug carrying stent includes applying at least a first therapeutic agent to at least an outer portion of a stent framework and applying a first magnesium coating on at least a first portion of the applied first therapeutic agent.

Abstract: A process for reducing solvent contents in drug-containing polymeric compositions may be utilized to reduce the solvent content in implantable medical device wherein the compositions are in reservoirs. Specifically, the solvent contents in the drug-containing polymeric compositions are first reduced by one or more conventional drying methods, to a range from about 0.5 weight percent to about 10 weight percent of the total weight of the polymeric composition. Subsequently, the drug-containing polymeric compositions are further treated by a low temperature drying method for further reduction of the solvent content.

Abstract: An embodiment of the present invention relates to a medical product coated with a polymer layer, which comprises an inhibitor of the TRPC-3 ion channel underneath, in, and/or on the biostable or biodegradable polymer layer.

Abstract: A coating system and method are described. In some embodiments, a system may include a composition. The composition may include one or more bridged polycyclic compounds. At least one of the bridged polycyclic compounds may include at least two cyclic groups, and at least two of the cyclic groups may include quaternary ammonium moieties. In some embodiments, a method may include applying a coating to a surface of a medical device. The coating may be antimicrobial. A coating may include antimicrobial bridged polycyclic compounds. In some embodiments, bridged polycyclic compounds may include quaternary ammonium compounds. In some embodiments, bridged polycyclic compounds may include guanidinium moieties. Bridged polycyclic compounds based coating systems may impart self-cleaning properties to a surface.