The present invention is directed to compositions containing polymer matrix, fiber and/or additives which are suitable for load bearing applications for medical devices. The matrix can be formed from a group of polymers which resorb inside the body after implantation. These compositions contain reinforcing fibers that are incorporated into a resorbable polymer matrix to improve properties such as mechanical. The reinforcing fibers can be resorbable, non-resorbable, natural, or metallic. Additives can be incorporated into the matrix material or the fibers or both to provide a secondary effect. These additives can be bioceramics to provide an osteoconductive effect; antimicrobial particles such as silver; coloring agents, and radiopaque additives to make the implants visible under fluoroscopy. The additives may also contribute to improve mechanical properties. The Composite composition with Matrix, Fibers and/or additives can provide enhanced functionality of mechanical, Osteoconductive and tailored degradation characteristics that can result in superior properties conventionally not achievable for Bioresorbable composites.

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 invention relates to an odontological biomaterial called “ANCLA Post”. The post is used as a reconstruction means in anterior and posterior teeth, the cylindrical, conical design of the extension and anchor-shaped design of the apical end allowing forces to be adequately distributed to prevent the fracturing of the tooth and to keep same repairable and usable for a long time. The post is characterized in that it is made of fiberglass, resin or polymer, and is white and radiopaque.

The present invention provides composition comprising a metal oxide semiconductor nanomaterial coated or dispersed with a hemostatic polymer.

Methods of preparing nitric oxide-releasing silica particles are provided, including the steps of functionalizing a silica particle with a linker moiety; and reacting a functional group on a nitric oxide storage/release compound with the linker moiety to attach the nitric oxide storage/release compound to the silica particle via the linker moiety. The disclosure also provides certain nitric oxide-releasing silica particles and precursors thereof, as well as compositions containing such particles.

A semi-synthetic hybrid material having a pH from 7 to 7.4 includes an inorganic fraction and a cross-linked organic fraction. The method for producing this material, and osteosynthesis devices or implants made of semi-synthetic hybrid material are also described.

In accordance with the invention, compositions, devices, and related methods have been developed for medical-related and other applications. In some embodiments, the devices and compositions described herein comprise a triggerable shape memory polymer network. In certain embodiments, the polymer network comprises a covalently crosslinked polymeric material and a non-crosslinked polymeric material associated with the crosslinked polymeric material. In some cases, the polymer network has a first configuration (e.g., as polymerized), and a second configuration (e.g., upon heating and deformation), such that the polymer network can be triggered to recover the first configuration upon heating the polymeric material above a softening temperature of the polymeric material. In certain embodiments, the polymer network comprises a plurality of particles capable of increasing the temperature of the polymer network (e.g., above the softening temperature) in the presence of an external stimulus such as induction, radio frequency, or magnetic resonance, such that the polymer network changes configuration. The polymeric material may be molded into any suitable shape.

A medical implant comprising a plurality of biocomposite layers, each layer comprising a polymer and a plurality of uni-directionally aligned continuous reinforcement fibers. The medical implant is suitable for load-bearing orthopedic implant applications and comprises one or more biocomposite materials where sustained mechanical strength and stiffness are critical for proper implant function.

A medical implant comprising a plurality of biocomposite layers, each layer comprising a polymer and a plurality of uni-directionally aligned continuous reinforcement fibers. The medical implant is suitable for load-bearing orthopedic implant applications and comprises one or more biocomposite materials where sustained mechanical strength and stiffness are critical for proper implant function.

The present invention provides composition comprising a metal oxide semiconductor nanomaterial coated or dispersed with a hemostatic polymer.