Abstract: Polymeric hybrid precursors, mixtures of polymeric hybrid precursors and polymers, and polymer composite matrices prepared from the mixture of the polymeric hybrid precursors and the polymer. The mixture of the polymeric hybrid precursors and the polymer can undergo a process to form the polymer composite matrix having a cross-linked network of a silasesquioxane based polymer formed from the polymeric hybrid precursors that interpenetrates the polymer. The polymeric hybrid precursors include chemical linkage moieties that are capable of forming non-covalent bonds with portions of the polymer. The polymer composite matrices are useful as biomaterials in medical devices.

Abstract: Reinforced copolymers formed from a functionalized copolymer that undergoes a reactive extrusion process with an inorganic component to form the reinforced copolymer. The functionalized copolymer in the form of a block and/or graft copolymer includes hard segments and soft segments, where the soft segments are covalently bonded with a coupling agent either before or after copolymerization with the hard segments. The reinforced copolymer of the present disclosure can be suitable for use as a biomaterial and/or in medical devices.

Abstract: The present disclosure relates to compounds from which nanofibers can be produced, the resulting nanofibers produced from the compounds, and nanofiber reinforced polymers prepared using the nanofibers and a polymer. The compounds used in forming the nanofibers include chemical linkage moieties that are capable of forming non-covalent bonds with portions of the polymer so as to form the nanofiber reinforced polymers. The nanofiber reinforced polymers are useful as biomaterials in medical devices.

Abstract: Particulate materials useful as fillers, reinforcing agents, radioopacifiers, or impact modifiers. The particulate material has an average particle size range of about 10,000 nm or less and comprises an organic-inorganic hybrid material that has a ceramic material network having organic polymer segments distributed throughout the ceramic network. The ceramic network may be prepared by a sol-gel technique. The particulate material may be compounded in thermoplastic polymer compositions useful in a variety of applications such as preparation of medical device components.

Abstract: According to one aspect of the present invention, internal medical devices are provided which include one or more extruded regions, each of which may be formed from one or more extruded portions, which extruded portions may, in turn, contain one or more polyelectrolyte species. The one or more extruded regions may be, for example, at least partially freestanding or at least partially disposed over a substrate. The one or more extruded regions may be formed, for example, using various processes.

Abstract: A shaped medical device article prepared from a polymer melt composition comprising a polymer ester, a transesterification catalyst, and a tri- or tetraalkoxy silane, by forming and solidifying said composition, and after solidification, subjecting the composition to reaction conditions to effect hydrolysis at least some alkoxysilyl groups remaining in the composition to form silanol groups and to effect condensation of said silanol groups to form a ceramic network.

Abstract: A medical device having at least one composite region thereon formed of composite material comprising a polymer and a fluorinated sol-gel derived ceramic. The composite material is useful as a coating material for imparting a low coefficient of friction to a substrate.

Abstract: Implantable or insertable medical devices that have one or more composite regions. These composite regions include polymer and sol-gel derived ceramic. The polymer and sol-gel ceramic may form bi-continuous phases or separate polymeric and sol-gel derived ceramic phases.

Abstract: A medical device at least a portion of which has a degradable coating, the coating degrading in an aqueous environment, and to methods of making and using the same. The coating may be a layer-by-layer coating, the first layer comprising a material having a positive charge and the second layer comprising a material having a negative charge.

Abstract: A medical device formed at least in part from a microfibrillar polymer-polymer composite, the microfibrillar polymer-polymer composite comprising a polymer matrix and oriented polymer microfibrils, and method of making the same.

Abstract: The invention generally relates to internal (e.g., implantable, insertable, etc.) drug delivery devices which contain the following: (a) one or more sources of one or more therapeutic agents; (b) one or more first electrodes, (c) one or more second electrodes and (d) one or more power sources for applying voltages across the first and second electrodes. The power sources may be adapted, for example, to promote electrically assisted therapeutic agent delivery within a subject, including electroporation and/or iontophoresis. In one aspect of the invention, the first and second electrodes are adapted to have tissue of a subject positioned between them upon deployment of the medical device within the subject, such that an electric field may be generated, which is directed into the tissue. Furthermore, the therapeutic agent sources are adapted to introduce the therapeutic agents into the electric field.