The invention relates to a coating for an implant component, a method for producing an implant component having said coating, and a use of said coating on an implant component. The coating is intended for an implant component, in particular a spinal implant component, and is a TiNb coating which has, in addition to an atom % proportion of Ti and an atom % proportion of Nb, an atom % proportion of 5-30 atom % of Ag.

A bioactive scaffold is provided. The bioactive scaffold includes an interconnected web of struts composed of a glass-ceramic material, the web of struts being printed as a three-dimensional structure from a filament composition having a bimodal distribution of glass-ceramic microparticles, wherein the bioactive scaffold has a porosity defined by spaces between struts of greater than or equal to about 40% to less than or equal to about 80% and an average pore size of greater than or equal to about 200 μm to less than or equal to about 400 μm. Methods of making the bioactive scaffold and treating bone defects using the bioactive scaffolds are also provided.

Anti-biofilm osseointegrating and/or tissue-integrating implantable biomaterial devices that optionally can elute therapeutic ions such as magnesium, silver, copper and/or zinc. In certain embodiments, the devices are engineered to produce structures suitable as implants having a relatively high surface population of zeolite. Methods of producing the devices are also disclosed.

Systems, methods, and apparatuses for increasing liquid absorption are described. Some embodiments may include a dressing having an absorbent layer containing super-absorbent material as well as ionic-exchange media (IEM). In some embodiments, the absorbent layer may include absorbent fibers. The absorbent fibers may each include a super-absorbent core surrounded by a water-permeable layer onto which ionic-exchange media (IEM) may be grafted. As liquid comes into contact with the IEM, its ionic nature may be reduced, therefore protecting the absorbent qualities of the super-absorbent material.

The invention concerns the use of an antimicrobial composition comprising metallic silver and metallic ruthenium as well as at least one vitamin or at least one vitamin derivative for the topical treatment or prevention of skin, skin adnexa or mucosa diseases which are caused by infection with at least one microorganism. The invention also concerns a bandaging material or patch comprising an antimicrobial composition which comprises metallic silver and metallic ruthenium as well as at least one vitamin or at least one vitamin derivative. The antimicrobial composition (“AgXX”) has a broad-spectrum effect against bacteria (a: E. coli) and fungi (b: Pathogen yeast and c: Penicillium).

a) Escherichia coli (additionally silver (“Ag”) as control),
b) Candida parapsilosis,
c) Penicillium notatum.

Disclosed is absorbable bone wax and a preparation method thereof. The preparation method comprises the steps of: 1) mixing polyoxypropylene polyoxyethylene block copolymer (PEG-PPG-PEG) and polyoxypropylene polyoxyethylene random copolymer (PEG-PPG), and stirring evenly under heating to obtain a liquid mixture; 2) under mechanical stirring and heating condition, adding hemostatic starch microspheres to the liquid mixture obtained in step 1) to obtain a uniformly-mixed liquid; and 3) adding a bone repair material to the uniformly-mixed liquid obtained in step 2), and mixing uniformly to obtain a mixed solution, then pouring the mixed solution into a mold or sub-packaged bottle, and leaving at room temperature for solidifying and shaping to give the absorbable bone wax. The absorbable bone wax of the present invention can achieve the effect of rapid hemostasis, changing the relatively single hemostasis method with traditional bone wax which only depends on physical sealing.

An orthopaedic implant comprising a titanium substrate having silver deposited thereon, wherein the silver is operable to be eluted at a rate of at least 0.25 μg/cm2 24 h-1, for at least 14 consecutive days, in use. The invention also extends to a method of producing an orthopaedic implant and use of the same.

Novel compositions and systems for closure of wounds with antimicrobial effectiveness are disclosed. The compositions provide devices of improved flexibility and elasticity and are readily applied to wound sites or over wound closure devices. The present invention is also directed to a novel platinum catalyst for use in such compositions. The catalyst provides for rapid curing on topical surfaces such as skin and bonds to such surfaces in about 2-5 minutes.

Wound dressings comprising absorbable polyelectrolyte material and ionic crystals and methods of making the same are provided. The weight percent of ionic crystals in the polyelectrolyte materials can be adjusted for desired uses of the wound dressings.

This disclosure relates to a wound care device which contains capillary force one-way pumps that are capable of transporting fluid, such as wound exudate, away from a wound site to the opposite side of the wound care device, which functions as a segregated fluid reservoir. This fluid transport mechanism generally aids in reducing wound maceration by removing excess wound fluid and the protease enzymes and infectious bacteria contained within the wound fluid. The wound care device performs this function, often times for multiple days, without the loss of the physical integrity of the wound care device. In addition to providing a uni-directional fluid transport mechanism, the wound care device contains a perforated adhesive layer.