Disclosed herein are embodiments of a conductive polymer doped with silica nanoparticles. In several embodiments, a coated electrode comprising a coating of the conductive polymer on a conductive surface of the electrode is provided. In some embodiments, the silica nanoparticles of the conductive polymer are mesoporous and are loaded with a pharmaceutical agent. Methods of using the conductive polymer doped with silica nanoparticles are also provided, including methods of recording or stimulating a bioelectric signal and methods of administering a pharmaceutical agent to a subject.

A coating for an electrosurgical electrode to reduce the potential for sticking of tissue. The coating is an elastomer containing a plurality of diamond particles having an average diameter of between diameter of 0.5 and 500 nanometers and that comprise between 0.1 and 25 percent by weight of the coating. The coating may be formed by reducing a silicone dispersion with xylene, adding the plurality of diamond particles, and agglomerating the plurality of diamond particles through sonification and then applied to the device. The coasting may also be formed by reducing a silicone dispersion with xylene, adding the plurality of diamond particles, and agglomerating the plurality of diamond particles through sonification, and then applied to the device by plasma enhanced vapor deposition.

A coating for an electrosurgical electrode to reduce the potential for sticking of tissue. The coating is an elastomer containing a plurality of diamond particles having an average diameter of between diameter of 0.5 and 500 nanometers and that comprise between 0.1 and 25 percent by weight of the coating. The coating may be formed by reducing a silicone dispersion with xylene, adding the plurality of diamond particles, and agglomerating the plurality of diamond particles through sonification and then applied to the device. The coasting may also be formed by reducing a silicone dispersion with xylene, adding the plurality of diamond particles, and agglomerating the plurality of diamond particles through sonification, and then applied to the device by plasma enhanced vapor deposition.

A medical component is provided which includes a first portion formed of a first elastomeric material having at least one taggant embedded or incorporated therein, and a second portion formed of a second elastomeric material. The at least one taggant has a first diffusivity relative to the first elastomeric material and a second diffusivity relative to the second elastomeric material. The second diffusivity is less than the first diffusivity.

The present invention is directed to a composite material with a high dielectric constant. In certain embodiments, the composite material of the invention is biocompatible and is used in an implantable medical device, such as an implantable antenna, probe, sensor or electrode. In certain embodiments, the present invention comprises a biocompatible conductive or semi-conductive filler comprising filler particles dispersed within a biocompatible electrically insulating material. The filler particles may comprise an electrically insulating coating.

The present invention is directed to a composite material with a high dielectric constant. In certain embodiments, the composite material of the invention is biocompatible and is used in an implantable medical device, such as an implantable antenna, probe, sensor or electrode. In certain embodiments, the present invention comprises a biocompatible conductive or semi-conductive filler comprising filler particles dispersed within a biocompatible electrically insulating material. The filler particles may comprise an electrically insulating coating.

The present application relates to shear thinning hydrogel compositions which are useful for reducing and/or preventing tissue adhesion in a subject (e.g., a post-operative subject). Methods of using the compositions and kits comprising the compositions oar also provided.

The present application relates to shear thinning hydrogel compositions which are useful for reducing and/or preventing tissue adhesion in a subject (e.g., a post-operative subject). Methods of using the compositions and kits comprising the compositions oar also provided.

The present invention relates to thin polymeric films containing nanoparticles with tunable absorption in the visible and near infrared (NIR) region. When these films are irradiated with NIR sources, they show a pronounced photo-thermal effect. Said effect allows a localized temperature increase, which can be controlled both spatially and temporally. Once the irradiation source has been turned off, the temperature returns within a few seconds to the initial value and then raises again as soon as the film is irradiated again. These films can be used as reusable medical devices, with a controllable and reproducible heating profile, in particular thermal or heating patches.

The present patent application is directed to compositions and shaped structures implantable into mammalian bodies, the compositions and shaped structures having localized bioactive surfaces.