Abstract: Coatings for medical devices, methods of making the coatings, and methods of using them are described.

Abstract: Coatings for medical devices, methods of making the coatings, and methods of using them are described.

Abstract: Disclosed herein is the correlation of chemical properties of oils with the physical properties of a resulting cured oil composition. Also disclosed are biocompatible materials and coatings for medical devices prepared using enriched oils and methods for enhancing or modifying the physical and chemical characteristics of cured oils by enriching such oils with fatty acid alkyl esters. Methods of tailoring the properties of biocompatible materials and coatings to deliver one or more therapeutic agents are also provided.

Abstract: A nanoemulsion and corresponding methods of making and using systems of single or blended high HLB value surfactant(s) for the emulsification of single or blended oils and vitamin E components in an aqueous phase are provided. The resulting nanoemulsions and methods of administering the nanoemulsions, including a corresponding kit, provide delivery of the nanoemulsions to a patient.

Abstract: Fatty acid-derived biomaterials, methods of making the biomaterials, and methods of loading them with silver compounds are described. The silver-containing biomaterials can be utilized alone or in combination with a medical device for the release and local delivery of one or more anti-infective agents. Methods of forming and tailoring the properties of said biomaterials and methods of using said biomaterials for treating injury in a mammal are also provided.

Abstract: Exemplary embodiments of the present invention provide adhesion barriers having anti-adhesion and tissue fixating properties. The adhesion barriers are formed of fatty acid based films. The fatty acid-based films may be formed from fatty acid-derived biomaterials. The films may be coated with, or may include, tissue fixating materials to create the adhesion barrier. The adhesion barriers are well tolerated by the body, have anti-inflammation properties, fixate, well to tissue, and have a residence time sufficient to prevent post-surgical adhesions.

Abstract: A biocompatible biological component is provided comprising a membrane-mimetic surface film covering a substrate. Suitable substrates include hydrated substrates, e.g. hydrogels which may contain drugs for delivery to a patient through the membrane-mimetic film, or may be made up of cells, such as islet cells, for transplantation. The surface may present exposed bioactive molecules or moieties for binding to target molecules in vivo, for modulating host response when implanted into a patient (e.g. the surface may be antithrombogenic or antiinflammatory) and the surface may have pores of selected sizes to facilitate transport of substances therethrough. An optional hydrophilic cushion or spacer between the substrate and the membrane-mimetic surface allows transmembrane proteins to extend from the surface through the hydrophilic cushion, mimicking the structure of naturally-occurring cells.

Abstract: Fatty acid-based, pre-cure-derived biomaterials, methods of making the biomaterials, and methods of using them as drug delivery carriers are described. The fatty acid-derived biomaterials can be utilized alone or in combination with a medical device for the release and local delivery of one or more therapeutic agents. Methods of forming and tailoring the properties of said biomaterials and methods of using said biomaterials for treating injury in a mammal are also provided.

Abstract: Fatty acid-derived biomaterials, methods of making the biomaterials, and methods of using them as drug delivery carriers are described. The fatty acid-derived biomaterials can be utilized alone or in combination with a medical device for the release and local delivery of one or more therapeutic agents. Methods of forming and tailoring the properties of said biomaterials and methods of using said biomaterials for treating injury in a mammal are also provided.

Abstract: A surgical mesh is formed of a biocompatible mesh structure with a coating that provides anti-inflammatory, non-inflammatory, and anti-adhesion functionality for a implantation in a patient. The coating is generally formed of a fish oil, can include vitamin E, and may be at least partially cured. In addition, the coating can include a therapeutic agent component, such as a drug or other therapeutic agent.

Abstract: A biocompatible biological component is provided comprising a membrane-mimetic surface film covering a substrate. Suitable substrates include hydrated substrates, e.g. hydrogels which may contain drugs for delivery to a patient through the membrane-mimetic film, or may be made up of cells, such as islet cells, for transplantation. The surface may present exposed bioactive molecules or moieties for binding to target molecules in vivo, for modulating host response when implanted into a patient (e.g. the surface may be antithrombogenic or antiinflammatory) and the surface may have pores of selected sizes to facilitate transport of substances therethrough. An optional hydrophilic cushion or spacer between the substrate and the membrane-mimetic surface allows transmembrane proteins to extend from the surface through the hydrophilic cushion, mimicking the structure of naturally-occurring cells.