Coatings are disclosed that include a solvent and a silk fibroin and/or a silk fibroin-like macromolecule. These coatings are provided via self-assembly on a target surface, or co-assembly with one or more functionally active additive compounds such as organic or inorganic therapeutics. Coating growth is facilitated by the addition of effective concentrations of kosmotropic agents, such as potassium phosphate, and provide coatings that are smooth on the nanometer length scale and free of inhomogeneities. Because the method grows the coating from the surface in a non-covalent bottom-up approach, it is suitable for coating surfaces that have high curvature or complex geometry, such as porous materials or those with nano or micron-scale diameter features. These coatings can be grown on both organic and inorganic surfaces without the need for specific covalent chemistry of the surface or activation of the surface by irradiation or chemical treatment.

Silk processed, coated, repaired, and/or infused leather or leather articles, and methods of preparing the same are disclosed herein.

A method for modifying the properties of balsa wood comprises infiltrating a protein ionic liquid comprising polymerized dopamine into delignified balsa wood. A method of making an optically active protective coating comprises mixing protein ionic liquid comprising polymerized dopamine with ethyl acetate-based or water-based nail polish. A method of making a thermoplastic having biological activity comprises melting a thermoplastic; and blending a protein ionic liquid with the thermoplastic; and cooling the thermoplastic protein ionic liquid blend to a solid state. The thermoplastic is a hot glue stick. The protein ionic liquid comprises antibodies, enzymes, or fluorescent proteins. A method of making a chymotrypsin protein ionic liquid/thermoplastic material comprises mixing cationized chymotrypsin and anions of poly(ethylene glycol) 4-nonylphenyl 3-sulfopropyl ether to form a chymotrypsin and anion complex; lyophilizing and melting the cationized chymotrypsin and anion complex to form a water-free ionic liquid; blending the chymotrypsin ionic liquid with molten hot glue/thermoplastic.

A method for modifying the properties of balsa wood comprises infiltrating a protein ionic liquid comprising polymerized dopamine into delignified balsa wood. A method of making an optically active protective coating comprises mixing protein ionic liquid comprising polymerized dopamine with ethyl acetate-based or water-based nail polish. A method of making a thermoplastic having biological activity comprises melting a thermoplastic; and blending a protein ionic liquid with the thermoplastic; and cooling the thermoplastic protein ionic liquid blend to a solid state. The thermoplastic is a hot glue stick. The protein ionic liquid comprises antibodies, enzymes, or fluorescent proteins. A method of making a chymotrypsin protein ionic liquid/thermoplastic material comprises mixing cationized chymotrypsin and anions of poly(ethylene glycol) 4-nonylphenyl 3-sulfopropyl ether to form a chymotrypsin and anion complex; lyophilizing and melting the cationized chymotrypsin and anion complex to form a water-free ionic liquid; blending the chymotrypsin ionic liquid with molten hot glue/thermoplastic.

A coating for conversion of formaldehyde to carbon dioxide includes an alcohol/aldehyde oxidase and a formate oxidase immobilized on a solid particulate support; and a latex binder.

A coating for conversion of formaldehyde to carbon dioxide includes an alcohol/aldehyde oxidase and a formate oxidase immobilized on a solid particulate support; and a latex binder.

Provided is an antiviral filter medium. An antiviral filter medium according to one embodiment of the present invention includes a first member provided with an antiviral coating layer formed of fibers and including, on part or all of the outer surface of the fibers, an antiviral fusion protein in which an antiviral motif is bound to an adhesive protein. Accordingly, the antiviral filter medium exhibits antiviral properties, is excellent in filtration efficiency and ventilation amount (or flow rate), and has low pressure loss. In addition, the antiviral filter medium is characterized in that the coating layer exhibiting antiviral properties retains adhesiveness for a long period of time after being attached to the surface. Moreover, the antiviral filter medium can retain antiviral activity for a long time without loss of the antiviral activity due to external conditions during production, storage, and use.

Provided is an antiviral filter medium. An antiviral filter medium according to one embodiment of the present invention includes a first member provided with an antiviral coating layer formed of fibers and including, on part or all of the outer surface of the fibers, an antiviral fusion protein in which an antiviral motif is bound to an adhesive protein. Accordingly, the antiviral filter medium exhibits antiviral properties, is excellent in filtration efficiency and ventilation amount (or flow rate), and has low pressure loss. In addition, the antiviral filter medium is characterized in that the coating layer exhibiting antiviral properties retains adhesiveness for a long period of time after being attached to the surface. Moreover, the antiviral filter medium can retain antiviral activity for a long time without loss of the antiviral activity due to external conditions during production, storage, and use.

An antiviral fabric including a fabric and an antiviral coating layer which is provided in the fabric and which includes an antiviral fusion protein having an antiviral motif bound to an adhesive protein. The antiviral fabric has excellent processability that enables simple implementation of the antiviral coating layer even on the curved surface of a fiber, the porous surface of a fabric, or a recessed or protruding surface. In addition, the antiviral fabric can have activity persistence that enable maintenance of antiviral activity for a long time without losing the same according to a condition during preparation, storage, use and washing, while having adhesion persistence that enables the maintenance of an adhesive state for a long time after the antiviral coating layer is formed on the surface thereof, and thus can be widely applied to various articles for which fabric is used.

An antiviral fabric including a fabric and an antiviral coating layer which is provided in the fabric and which includes an antiviral fusion protein having an antiviral motif bound to an adhesive protein. The antiviral fabric has excellent processability that enables simple implementation of the antiviral coating layer even on the curved surface of a fiber, the porous surface of a fabric, or a recessed or protruding surface. In addition, the antiviral fabric can have activity persistence that enable maintenance of antiviral activity for a long time without losing the same according to a condition during preparation, storage, use and washing, while having adhesion persistence that enables the maintenance of an adhesive state for a long time after the antiviral coating layer is formed on the surface thereof, and thus can be widely applied to various articles for which fabric is used.