The polymer film serves for the embedding of a medical technology product to be implanted in a human organism. The polymer film includes a polymer of natural origin being biodegradable and absorbable by the human body. The polymer film has a polymer content. The polymer film further includes two antimicrobial active ingredients having a different mechanism of action and the polymer film has a total active-ingredient content. The ratio of the total active-ingredient content to the polymer content is at least 15%. The polymer content is greater than the total active-ingredient content. The polymer film is bendable and modulable and uninterrupted. The polymer forms a polymer matrix in which the antimicrobial active ingredients are embedded in a homogeneously distributed manner. The polymer film has, for each of the antimicrobial active ingredients, an individual active-ingredient content deviating from one another by at most 20%.

Silk coated and/or infused performance materials, apparel, and methods of preparing the same are disclosed herein. In some embodiments, silk performance apparel includes textiles, fabrics, consumer products, and other materials that are coated with aqueous solutions of pure silk fibroin-based protein fragments having low, medium, and/or high molecular weight in various ratios.

Silk coated and/or infused performance materials, apparel, and methods of preparing the same are disclosed herein. In some embodiments, silk performance apparel includes textiles, fabrics, consumer products, and other materials that are coated with aqueous solutions of pure silk fibroin-based protein fragments having low, medium, and/or high molecular weight in various ratios.

Silk coated and/or infused performance materials, apparel, and methods of preparing the same are disclosed herein. In some embodiments, silk performance apparel includes textiles, fabrics, consumer products, and other materials that are coated with aqueous solutions of pure silk fibroin-based protein fragments having low, medium, and/or high molecular weight in various ratios.

In one aspect, methods of preparing composite nanoparticle compositions are described herein. For example, in some embodiments, a method comprises providing a zein solution stream, an organic fluid stream including at least one additive and at least one buffer fluid stream. The zein solution stream, organic fluid stream and buffer fluid stream are delivered to a chamber for mixing at one or more rates sufficient to flash precipitate composite nanoparticles including the additive encapsulated by a shell comprising the zein.

In one aspect, methods of preparing composite nanoparticle compositions are described herein. For example, in some embodiments, a method comprises providing a zein solution stream, an organic fluid stream including at least one additive and at least one buffer fluid stream. The zein solution stream, organic fluid stream and buffer fluid stream are delivered to a chamber for mixing at one or more rates sufficient to flash precipitate composite nanoparticles including the additive encapsulated by a shell comprising the zein.

The present invention relates to a gelatin or pectin based antimicrobial surface coating material. In the present invention, boron compounds are mixed with gelatin or pectin and a surface coating material in the form of a film is obtained. The said coating material can be used in all packaging industry requiring hygiene particularly in food industry. The invention enables packages to be antifungal, anticandidal and antibacterial.

Tissue repair and restoration can be performed using an elastic material formed from tropoelastin. The elastic material can be formed by providing a solution of tropoelastin monomers, applying the solution to a surface, and heating the solution on the surface in absence of a cross-linking agent to enable the tropoelastin monomers to bind to each other to form an elastic material that does not dissociate into tropoelastin monomers when the elastic material is contacted with an aqueous solution.

Tissue repair and restoration can be performed using an elastic material formed from tropoelastin. The elastic material can be formed by providing a solution of tropoelastin monomers, applying the solution to a surface, and heating the solution on the surface in absence of a cross-linking agent to enable the tropoelastin monomers to bind to each other to form an elastic material that does not dissociate into tropoelastin monomers when the elastic material is contacted with an aqueous solution.

The disclosure relates to omniphobic coatings, related articles including such coatings, and related method for forming such coatings or articles, for example biobased and/or biodegradable omniphobic coatings with high barrier properties. The omniphobic coating includes an oleophobic and hydrophilic first layer, and a hydrophobic and optionally oleophilic second layer adjacent to the first layer. A corresponding omniphobic coated article can include the omniphobic coating on a substrate such as a porous cellulosic or paper substrate, for example to provide a water- and oil/fat/grease-resistant coating for a paper-based product. The first layer of the omniphobic coating is adjacent to the substrate and the second layer is adjacent to the first layer at a position further from the substrate than the first layer. The omniphobic coating can be applied to a substrate in a layer-by-layer process, and the coated article can be recycled by extraction to remove the coating and recover the substrate material, for example in a re-pulping process.