Antimicrobial metal ion coatings. In particular, described herein are coatings including an anodic metal (e.g., silver and/or zinc and/or copper) that is co-deposited with a cathodic metal (e.g., palladium, platinum, gold, molybdenum, titanium, iridium, osmium, niobium or rhenium) on a substrate so that the anodic metal is galvanically released as antimicrobial ions when the apparatus is exposed to a bodily fluid. The anodic metal may be at least about 25 percent by volume of the coating, resulting in a network of anodic metal with less than 20% of the anodic metal in the coating fully encapsulated by cathodic metal.

An antimicrobial medical device that includes a substrate having a metal surface that is made from a metal or metal alloy that may include stainless steel, cobalt, and titanium. Disposed on the metal surface is a first antimicrobial oxide layer that includes an antimicrobial metal that may include silver, copper, and zinc, and combinations thereof. The atoms of antimicrobial metal in the first antimicrobial oxide layer are of a first concentration. The first antimicrobial oxide layer is positioned in a direction opposite that of the metal surface. The device further includes a second antimicrobial oxide layer that includes an antimicrobial metal that may be silver, copper, and zinc, and combinations thereof. The atoms of the antimicrobial metal present in the second antimicrobial oxide layer are of a second concentration. The first concentration and the second concentration are not equal. Methods for making the antimicrobial medical device are also disclosed.

Disclosed is a bone regeneration device which forms an electric field on a scaffold inserted into a bone damage site. The present bone regeneration device comprises: a battery; a first electric conductor to be connected to a first electrode of the battery and inserted into a bone located on one side of the scaffold; and a second electric conductor to be connected to a second electrode of the battery and inserted into a bone located on the other side of the scaffold, wherein the battery forms an electric field on the scaffold by applying voltage to the first electric conductor and the second electric conductor.

An embodiment of this disclosure provides a medical dressing. The medical dressing includes a first layer comprising a non-woven material capable of being liquid permeable. The medical dressing also includes a second layer comprising a topical composition and a solidifying agent. The second layer is positioned on a side of the first layer. The medical dressing also includes a third layer comprising a material capable of being liquid impermeable. The third layer is positioned on the second layer opposite the first layer.

Various examples are provided for magnetic particle imbedded nanofibrous membranes. In one example, among others, a nanofibrous membrane includes one or more electrospun nanofibers forming form a layer of nanofibers, and a plurality of magnetic nanoparticles embedded in the one or more electrospun nanofibers. In another example, a method includes generating one or more electrospun nanofibers including magnetic nanoparticles from one or more nozzles positioned over a substrate to form a magnetic nanofibrous layer, and affixing the magnetic nanofibrous layer to a support structure. In another example, a system includes a magnetic nanofibrous membrane affixed to a support structure, and a magnetic field generator configured to generate a magnetic field that passes through the magnetic nanofibrous membrane.

The invention relates to a biodegradable, magnesium-containing bone screw for implanting into a patient body for use in medical applications, such as, orthopedic and craniofacial surgery. The bone screw has a tapered head, a threaded shaft and pointed tip. The composition of the bone screws provide for improved biodegradability and biocompatibility, and the features of the structure of the bone screws facilitates guidance and placement during implantation as well as reduces the potential for mechanical failures. Moreover, the bone screws are effective to provide targeted release of magnesium ions resulting in enhanced new bone formation.

The present invention discloses a method for preparing an anti-bacterial surface on a medical material surface, including the steps of: (1) conducting chemical graft of amino silane after performing oxygen plasma pretreatment to the medical material surface and then reacting the medical material with the amino silane surface with an acyl compound; (2) placing the medical material with an initiator-modified surface into an anti-adhesion monomer aqueous solution for a graft polymerization reaction; (3) placing the medical material with an anti-adhesion polymer brush-modified surface into an azide compound-containing dimethylformamide solution; and (4) placing the medical material with an azide surface into an anti-bacterial agent click solution for a click reaction, obtaining an anti-adhesion polymer layer—and anti-bacterial agent layer-comodified anti-bacterial surface. The method prevents mutual interference of the anti-adhesion ability and bactericidal ability, and has good long-acting anti-bacterial performance.

This invention provides a method of promoting bone healing by locally administering a vanadium-based insulin mimetic agent to a patient in need thereof. The invention also provides a new use of insulin-mimetic vanadium compounds for manufacture of medicaments for accelerating bone-healing processes. In addition, the invention also encompasses a bone injury treatment kit suitable for localized administration of insulin-mimetic vanadium compounds or compositions thereof to a patient in need of such treatment.

The present disclosure relates to a process for obtaining and formulating functional silica particles and other materials with active ingredients/compounds for use in polymers, paints, mortars, ceramic, cement, textile, pharmaceutics, varnishes, paper, clays, cosmetics, sensors and effluents.

The present disclosure describes a functional particle for binding to a substrate comprising:

a granule comprising oxide or hydroxide of an element selected from the following list: silica, magnesium, zinc, iron, copper, silver, aluminum, gold, titanium, or mixtures thereof having a size between 90 nm-500 nm;

a binder comprising silane-based compounds which binds the outer granule to the substrate;

a functional compound/active compound bound to the surface of the granule, to the binder, or to both;

wherein the functional compound is at least one of the following compounds: anti-mosquito/repellent/anti-insect, fungicide, antimicrobial/bactericide, antimycotic, anti-fire, UV protectors, larvicides, hydrophobics, vitaminics, moisturizers, cosmetics, drugs, mechanical properties, magnetic properties enhancement, or mixtures thereof.

The present invention is a method for producing allograft tissue by applying an antimicrobial solution to allograft tissue. The antimicrobial solution exhibits antimicrobial activity to make allograft resistant to microbial organisms, such as bacterium.