Antitoxic fibers and fabrics contain impregnated material including an antitoxin. A method for producing antitoxic fabric and products includes impregnating a fabric formed from nonpolymeric or polymeric fibers by fully immersing the fabric in a solution of a concentrate of triiodide and an additive portion that includes an oil of ethoxylated fatty acids in sufficient proportion to stabilize the triiodide in the fabric. An antitoxic fabric includes polymeric or nonpolymeric fibers and impregnated material, which includes an antitoxin, the antitoxin being triiodide, and additional chemical components including an oil of ethoxylated fatty acids in sufficient proportion to stabilize the triiodide in the antitoxic fabric. The antitoxic fabric is efficacious on contact, and maintains efficacy with negligible toxicity in use. Products with antitoxic fabric include wound dressings, gowns, surgical drapes, protective clothing, shoe covers, gloves, hair covers, air filters, including facemasks, privacy, hygienic products, curtains, medical tape, and wipes.

Antitoxic fibers and fibrous media contain impregnated material including an antitoxin. A method for producing antitoxic fibers and fibrous media includes impregnating a fibrous media by dipping in a dipping solution containing a concentrate of an antitoxin to form a fiber with impregnated material including an antitoxin. The impregnated material is at least about 1.0% to about 2.5% by weight of the fibers and includes additive chemical components including at least one of an anionic, cationic or nonionic component, an oil and/or an organic solvent, and an alcohol. The additives include those found in a spin finish. The antitoxin is in an amount of at least 0.1% by weight of the fiber. The manufacturing process can be applied to any woven or nonwoven media. Products with antitoxic properties formed therefrom include wound dressings, gowns, articles of clothing, surgical drapes, protective clothing, shoe covers, gloves, hair covers, air filters, including facemasks, privacy, hygienic products, curtains, medical tape, and wipes.

Antitoxic fibers and fibrous media contain impregnated material including an antitoxin. A method for producing antitoxic fibers and fibrous media includes impregnating a fibrous media by dipping in a dipping solution containing a concentrate of an antitoxin to form a fiber with impregnated material including an antitoxin. The impregnated material is at least about 1.0% to about 2.5% by weight of the fibers and includes additive chemical components including at least one of an anionic, cationic or nonionic component, an oil and/or an organic solvent, and an alcohol. The additives include those found in a spin finish. The antitoxin is in an amount of at least 0.1% by weight of the fiber. The manufacturing process can be applied to any woven or nonwoven media. Products with antitoxic properties formed therefrom include wound dressings, gowns, articles of clothing, surgical drapes, protective clothing, shoe covers, gloves, hair covers, air filters, including facemasks, privacy, hygienic products, curtains, medical tape, and wipes.

Provided is a method of imparting antibacterial and deodorant functions by reacting iodic acid, and a material that is given antibacterial and deodorant functions. The method of imparting antibacterial and deodorant function is as follows. Reacting iodate to a material that includes elements capable of producing iodate insoluble in water and non-toxic to a living body to form iodic acid of such elements on the surface of the material, thereby the iodate is made to be supported so that antibacterial and deodorant is possible without elution of said iodate to the outside.

Provided is a method of imparting antibacterial and deodorant functions by reacting iodic acid, and a material that is given antibacterial and deodorant functions. The method of imparting antibacterial and deodorant function is as follows. Reacting iodate to a material that includes elements capable of producing iodate insoluble in water and non-toxic to a living body to form iodic acid of such elements on the surface of the material, thereby the iodate is made to be supported so that antibacterial and deodorant is possible without elution of said iodate to the outside.

The uses of the disclosed copper-cysteamine (Cu-Cy) complex for methods for treating Gram-positive and Gram-negative infections in subjects and for disinfecting a surface are disclosed. In addition, the disclosed Cy-Cy nanoparticles provide Fenton-like reactions in vivo, in vitro and ex vivo.

The uses of the disclosed copper-cysteamine (Cu-Cy) complex for methods for treating Gram-positive and Gram-negative infections in subjects and for disinfecting a surface are disclosed. In addition, the disclosed Cy-Cy nanoparticles provide Fenton-like reactions in vivo, in vitro and ex vivo.

This disclosure provides a method of disinfecting a surface within an area, comprising the steps of: a) dispersing into the area a multiplicity of droplets of a first aqueous composition comprising a first iodine reactant compound that is either a peroxide compound or an iodine salt compound: b) allowing sufficient time for the first aqueous composition to distribute throughout the area, and to deposit and coalesce into a layer upon the surface: c) dispersing into the area a multiplicity of droplets of a second aqueous composition comprising a second iodine reactant compound that is the other of the first iodine reactant compound, and: d) again allowing sufficient time for the droplets of the second aqueous composition to deposit onto the coalesced layer of the first aqueous composition, thereby forming iodine and other iodine biocides in situ and disinfecting the surface.

This disclosure provides a method of disinfecting a surface within an area, comprising the steps of: a) dispersing into the area a multiplicity of droplets of a first aqueous composition comprising a first iodine reactant compound that is either a peroxide compound or an iodine salt compound: b) allowing sufficient time for the first aqueous composition to distribute throughout the area, and to deposit and coalesce into a layer upon the surface: c) dispersing into the area a multiplicity of droplets of a second aqueous composition comprising a second iodine reactant compound that is the other of the first iodine reactant compound, and: d) again allowing sufficient time for the droplets of the second aqueous composition to deposit onto the coalesced layer of the first aqueous composition, thereby forming iodine and other iodine biocides in situ and disinfecting the surface.

This disclosure provides a method of disinfecting a surface within an area, comprising the steps of: a) dispersing into the area a multiplicity of droplets of a first aqueous composition comprising a first iodine reactant compound that is either a peroxide compound or an iodine salt compound: b) allowing sufficient time for the first aqueous composition to distribute throughout the area, and to deposit and coalesce into a layer upon the surface: c) dispersing into the area a multiplicity of droplets of a second aqueous composition comprising a second iodine reactant compound that is the other of the first iodine reactant compound, and: d) again allowing sufficient time for the droplets of the second aqueous composition to deposit onto the coalesced layer of the first aqueous composition, thereby forming iodine and other iodine biocides in situ and disinfecting the surface.