The present invention relates to a method for treating a surface in order to improve the removability of microorganisms from the surface, comprising the steps: —applying a treatment solution onto the surface, wherein the treatment solution comprises an aqueous solution of a collagen hydrolysate; and—allowing the surface to dry. The present invention further relates to the use of collagen hydrolysate for treating a surface in order to improve the removability of microorganisms from the surface.

The present invention relates to a method for treating a surface in order to improve the removability of microorganisms from the surface, comprising the steps: —applying a treatment solution onto the surface, wherein the treatment solution comprises an aqueous solution of a collagen hydrolysate; and—allowing the surface to dry. The present invention further relates to the use of collagen hydrolysate for treating a surface in order to improve the removability of microorganisms from the surface.

Provided is a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a hydrogel matrix formed from a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a 3D biomaterial scaffold comprising a hydrogel matrix of the disclosure as a first hydrogel layer and a hydrogel matrix of the disclosure as a second hydrogel layer, optionally having an intervening layer between the first hydrogel layer and the second hydrogel layer, and methods of forming and using same.

Provided is a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a hydrogel matrix formed from a bioink comprising a mixture comprising a collagen and a polysaccharide, and a polyhedral oligomeric silsesquioxane (POSS), a 3D biomaterial scaffold comprising a hydrogel matrix of the disclosure as a first hydrogel layer and a hydrogel matrix of the disclosure as a second hydrogel layer, optionally having an intervening layer between the first hydrogel layer and the second hydrogel layer, and methods of forming and using same.

Protein polyurethane alloys including one or more proteins dissolved within one or more polyurethanes. The protein polyurethane alloy may have one or more mechanical properties that are superior to the polyurethane in the absence of protein. The protein polyurethane alloys may be incorporated into a layered material including one or more protein polyurethane alloy layers.

Protein polyurethane alloys including one or more proteins dissolved within one or more polyurethanes. The protein polyurethane alloy may have one or more mechanical properties that are superior to the polyurethane in the absence of protein. The protein polyurethane alloys may be incorporated into a layered material including one or more protein polyurethane alloy layers.

A coating, a method for coating surfaces, and the coated surfaces. The method includes providing a substrate with a cleaned metal surface; contacting and coating the metal surface with an aqueous composition having a ph of from 0.5 to 7.0 and in the form of a dispersion and/or a suspension; optionally rinsing the organic coating; and drying and/or baking the organic coating, or optionally drying the organic coating and coating same with a similar or another coating composition thereto. The composition contains a complex fluoride in a quantity of 1.1 10.sup.−6 mol/l to 0.30 mol/l based on the cations. An anionic polyelectrolyte in a quantity of 0.01 to 5.0 wt % based on the total mass of the resulting mixture is added to an anionically stabilized dispersion made of film-forming polymers and/or a suspension made of film-forming inorganic particles.

A coating, a method for coating surfaces, and the coated surfaces. The method includes providing a substrate with a cleaned metal surface; contacting and coating the metal surface with an aqueous composition having a ph of from 0.5 to 7.0 and in the form of a dispersion and/or a suspension; optionally rinsing the organic coating; and drying and/or baking the organic coating, or optionally drying the organic coating and coating same with a similar or another coating composition thereto. The composition contains a complex fluoride in a quantity of 1.1 10.sup.−6 mol/l to 0.30 mol/l based on the cations. An anionic polyelectrolyte in a quantity of 0.01 to 5.0 wt % based on the total mass of the resulting mixture is added to an anionically stabilized dispersion made of film-forming polymers and/or a suspension made of film-forming inorganic particles.

A cell culture article is provided. The cell culture article includes a substrate of a polygalacturonic acid compound crosslinked with a divalent cation, the polygalacturonic acid compound being selected from at least one of: pectic acid; partially esterified pectic acid, partially amidated pectic acid and salts thereof. The substrate is digestible by digestion reagents into components including of galacturonic acid monomers and the divalent cation. Methods of harvesting cells from the cell culture article are also provided. The methods include performing a series of wash and/or centrifugation cycles to reduce components in the harvest solution.

The present invention provides an artificial bionic blood vessel and a manufacturing method thereof. The artificial bionic blood vessel includes a three-layer-structured artificial bionic blood vessel body, where the three-layer structure of the artificial bionic blood vessel consists of a natural silk layer, a diluted liquid silica-gel layer and a weaved tube layer, the diluted liquid silica-gel layer is located on the inner side of the natural silk layer, the weaved tube layer is located on the outer side of the natural silk layer, and the weaved tube layer is made of catgut by weaving.