Abstract: Compositions, instruments, systems, and methods are providing for creating families of materials having diverse therapeutic indications and possessing enhanced biocompatibility. One genus platform for the families includes a biocompatible synthetic electrophilic component mixed with a nucleophilic component. The electrophilic component can include a functionalized electrophilic poly (anhydride ester) material. The nucleophilic material can include a natural, autologous protein. The components, when mixed in a liquid state, react by cross-linking, forming a solid matrix composition, or hydrogel.

Abstract: A delivery device applies a biocompatible and biodegradable barrier material to a tissue region, e.g., to seal a vascular puncture site. The material comprises two liquid components, which are pre-packaged in individual dispensers. Upon mixing, the liquid components cross-link to create a barrier matrix. A holder attaches to the delivery device. The holder mutually supports the first and second dispensers while the protein solution and polymer solution are conveyed from the dispensers into a fluid delivery channel. The protein and polymer solutions mix as a result of flow through the channel.

Abstract: Compositions, instruments, systems, and methods are providing for creating families of materials having diverse therapeutic indications and possessing enhanced biocompatibility. The genus platform for the families includes a biocompatible synthetic electrophilic component mixed with a nucleophilic component. The electrophilic component can include a functionalized electrophilic poly (anhydride ester) material. The nucleophilic material can include a natural, autologous protein. The components, when mixed in a liquid state, react by cross-linking, forming a solid matrix composition, or hydrogel.

Abstract: A delivery device applies a biocompatible and biodegradable barrier material to a tissue region, e.g., to seal a vascular puncture site. The material comprises two liquid components, which are pre-packaged in individual dispensers. Upon mixing, the liquid components cross-link to create a barrier matrix. A holder attaches to the delivery device. The holder mutually supports the first and second dispensers while the protein solution and polymer solution are conveyed from the dispensers into a fluid delivery channel. The protein and polymer solutions mix as a result of flow through the channel.

Abstract: A biocompatible material genus serves as the foundation for multiple material composition species, each adapted to a specific therapeutic indication.

Abstract: Medical devices having topographic coatings are provided. The topographic coatings have regions of high and low elevation and may be composed of polymers, metals, ceramics, proteins and other biocompatible materials. Such topographic coatings facilitate the deposition, elution, and protection of therapeutic agents on the medical device, manipulation of the medical device, and other purposes. In particularly preferred embodiments, the medical device comprises a stent for vascular implantation.

Abstract: Systems and methods convey a closure material into a catheter to seal a puncture site in a blood vessel. The closure material comprises a mixture of first and second components which, upon mixing, undergo a reaction to form a solid closure material composition. The systems and methods assure ease of delivery and effective mixing of the components to create an in situ barrier at the puncture site.

Abstract: A biocompatible material genus serves as the foundation for multiple material composition species, each adapted to a specific therapeutic indication.

Abstract: Systems, methods, and compositions achieve rapid closure of vascular puncture sites. The systems and methods form a vascular closure composition by mixing together a first component, a second component, and a buffer material. The first component includes an electrophilic polymer material having a functionality of at least three. The second component includes a nucleophilic material that, when mixed with the first component within a reaction pH range of between 7 to 9, cross-links with the first component to form a non-liquid, three-dimensional barrier. The buffer material has a pH within the reaction pH range. The systems and methods apply the composition to seal a vascular puncture site.

Abstract: Systems, methods, and compositions achieve rapid closure of vascular puncture sites. The systems and methods form a vascular closure composition by mixing together a first component, a second component, and a buffer material. The first component includes an electrophilic polymer material having a functionality of at least three. The second component includes a nucleophilic material that, when mixed with the first component within a reaction pH range of between 7 to 9, cross-links with the first component to form a non-liquid, three-dimensional barrier. The buffer material has a pH within the reaction pH range. The systems and methods apply the composition to seal a vascular puncture site.

Abstract: Systems and methods convey a closure material into a catheter, e.g., to seal a puncture site in a blood vessel. The closure material comprises a mixture of first and second components, which, upon mixing, undergo a reaction to form solid closure material composition. The first component may be a lyophilized polyethylene glycol (PEG) material contained within a vial. The second component may be a buffered albumin solution plus water contained within a syringe. An applicator provides easy and effective mixing of the components and delivery of the mixture to the puncture site.

Abstract: Systems and methods employ functional instruments to close incisions and wounds using a suture knot in combination with a biocompatible material composition. The systems and methods are well suited for use, for example, at a vascular puncture site following a vascular access procedure.

Abstract: A fluidic media introduction apparatus for closing an opening in a vessel wall includes an elongated member with a fluidic media introduction port and a guide wire lumen. The guide wire lumen extends from a proximal portion to a distal portion of the elongated member. A fluidic media mixing chamber is positioned in the elongated member and coupled to a fluidic media introduction port. A fluidic media delivery lumen is coupled to the mixing chamber. A fluidic media advancement port is positioned at the distal portion of the elongated member. An inflatable member is coupled to the distal portion of the elongated member.

Abstract: A biocompatible and biodegradable barrier material is applied to a tissue region, e.g., to seal a vascular puncture site. The barrier material comprises a compound, which is chemically cross-linked without use of an enzyme to form a non-liquid mechanical matrix. The compound preferably includes a protein comprising recombinant or natural serum albumin, which is mixed with a polymer that comprises poly(ethylene) glycol (PEG), and, most preferably, a multi-armed PEG polymer.

Abstract: A biocompatible and biodegradable hydrogel compound, which is free of a hemostatic agent, is applied to arrest the flow of blood or fluid from body tissue. The compound preferably includes a protein comprising recombinant or natural serum albumin, which is mixed with a polymer that comprises poly(ethylene) glycol (PEG), and, most preferably, a multi-armed PEG polymer.

Abstract: A biocompatible and biodegradable barrier material is applied to a tissue region, e.g., to seal a vascular puncture site. The barrier material comprises a compound, which is chemically cross-linked without use of an enzyme to form a non-liquid mechanical matrix. The compound preferably includes a protein comprising recombinant or natural serum albumin, which is mixed with a polymer that comprises poly(ethylene) glycol (PEG), and, most preferably, a multi-armed PEG polymer.

Abstract: A biocompatible and biodegradable hydrogel compound, which is free of a hemostatic agent, is applied to arrest the flow of blood or fluid from body tissue. The compound preferably includes a protein comprising recombinant or natural serum albumin, which is mixed with a polymer that comprises poly(ethylene) glycol (PEG), and, most preferably, a multi-armed PEG polymer.

Abstract: Systems, methods, and compositions achieve rapid closure of vascular puncture sites. The systems and methods form a vascular closure composition by mixing together a first component, a second component, and a buffer material. The first component includes an electrophilic polymer material having a functionality of at least three. The second component includes a nucleophilic material that, when mixed with the first component within a reaction pH range of between 7 to 9, cross-links with the first component to form a non-liquid, three-dimensional barrier. The buffer material has a pH within the reaction pH range. The systems and methods apply the composition to seal a vascular puncture site.

Abstract: Systems and methods convey a closure material into a catheter to seal a puncture site in a blood vessel. The closure material comprises a mixture of first and second components which, upon mixing, undergo a reaction to form a solid closure material composition. The systems and methods assure ease of delivery and effective mixing of the components to create an in situ barrier at the puncture site.

Abstract: A delivery device applies a biocompatible and biodegradable barrier material to a tissue region, e.g., to seal a vascular puncture site. The material comprises two liquid components, which are pre-packaged in individual dispensers. Upon mixing, the liquid components cross-link to create a barrier matrix. A holder attaches to the delivery device. The holder mutually supports the first and second dispensers while the protein solution and polymer solution are conveyed from the dispensers into a fluid delivery channel. The protein and polymer solutions mix as a result of flow through the channel.