A method of depositing a relatively thin film of bioinert material onto a surgical implant substrate, such as a dental implant. Chemical vapor deposition (CVD) may be used to deposit a layer of tantalum and/or other biocompatible materials onto a solid substrate comprised of an implantable titanium alloy, forming a biofilm-resistant textured surface on the substrate while preserving the material properties and characteristics of the substrate, such as fatigue strength.

Provided herein are methods for the controlled, independent modification of the surface of magnesium-based materials and compositions generated thereby. The methods allow for the alteration of multiple surface characteristics including generation of precise nanostructures, morphology, crystallography, chemical hybridizations and chemical composition for controlled bioresorption and/or increased biocompatibility, for example, osseointegration, hydroxyapatite formation, osseoconduction, cell adhesion, cell proliferation, enhanced local mechanical properties (elasticity, modulus, surface texture, porosity), hydrophobicity, hydrophilicity, steric hindrance, modulating-immuno response, anti-inflammatory properties and/or anti-bacterial properties.

Provided herein are systems and methods for the controlled surface modification of a material substrate, including, for example, generation of nanostructures, crystallographic or morphologic alterations and the removal of defects, changes in chemical composition and bond structure and the creation of thermodynamic metastable states. The provided systems and methods utilize one or more directed energetic particle beams with independently controlled parameters (e.g. incident angle, fluence, flux, energy, species, etc.) to precisely and efficiently generate enhanced surface properties beyond those of conventional plasma kinetic roughening.

Provided herein are systems and methods for the controlled surface modification of a material substrate, including, for example, generation of nanostructures, crystallographic or morphologic alterations and the removal of defects, changes in chemical composition and bond structure and the creation of thermodynamic metastable states. The provided systems and methods utilize one or more directed energetic particle beams with independently controlled parameters (e.g. incident angle, fluence, flux, energy, species, etc.) to precisely and efficiently generate enhanced surface properties beyond those of conventional plasma kinetic roughening.

An implant device has an exterior portion forming an exterior surface of the implant. The exterior portion is made of a porous material defining passages through the exterior portion. An inner portion has an outer surface with a treated area that is accessible from the exterior surface through the passages. The treated area has a treatment for direct attachment to bone or soft tissue.

An implant device has an exterior portion forming an exterior surface of the implant. The exterior portion is made of a porous material defining passages through the exterior portion. An inner portion has an outer surface with a treated area that is accessible from the exterior surface through the passages. The treated area has a treatment for direct attachment to bone or soft tissue.

The present invention provides a dental implant device comprising a dental implant body and an implant fixture. Said implant fixture is characterized in that it comprises a portion to be fixed to said implant body and a portion to be fixed to a tooth adjacent to the transplantation site of said implant body in a subject, and is configured so that mechanical stimulation from the tooth adjacent to said transplantation site is transmissible to said implant body, and said implant device is characterized in that it is placed into the oral cavity of said subject so that said implant body is inserted at said transplantation site while said implant fixture is fixed to said implant body and the tooth adjacent to said transplantation site.

The present invention provides a dental implant device comprising a dental implant body and an implant fixture. Said implant fixture is characterized in that it comprises a portion to be fixed to said implant body and a portion to be fixed to a tooth adjacent to the transplantation site of said implant body in a subject, and is configured so that mechanical stimulation from the tooth adjacent to said transplantation site is transmissible to said implant body, and said implant device is characterized in that it is placed into the oral cavity of said subject so that said implant body is inserted at said transplantation site while said implant fixture is fixed to said implant body and the tooth adjacent to said transplantation site.

A biocompatible polymer hybrid nanocomposite coating on a surface of a substrate, such as titanium and its alloys. The coating can be achieved by an electrostatic spray coating, preferably using ultra-high molecular weight polyethylene (UHMWPE) as a matrix for the coating. For example, up to 2.95 wt. % carbon nanotubes can be used as reinforcement, as can up to 4.95 wt. % hydroxyapatite. A dispersion of CNTs and HA in the coating is substantially uniform. The tribological performance of such coatings include high hardness, improved scratch resistance, excellent wear resistance, and corrosion resistance compared to pure UHMWPE coatings.

An inorganic-organic composite medical material includes a two-phase co-continuous structure of an inorganic substance having open pores and an organic polymer filling the open pores, wherein the open pores have an average pore diameter of 1 nm or more and 100 nm or less, and the inorganic substance has a specific surface area of 100 m.sup.2/g or less.