Provided herein are fluorinated compounds having chemical structures: (I) where n is 0 or greater, or (II) where m and n are 0 or greater, or an amino acid, a soluble polymer, an oligo(ethylene glycol), a poly(ethylene glycol), or a carbohydrate each fluorinated with perfluorocarbons having the chemical structure (III) where n is 0 or greater. These fluorinated compounds are utilized in contact lenses to impart lipid-resistant, protein-resistant and biofouling-resistant properties, thus reducing discomfort and infection caused by contact lens wear without changing its transmission characteristics. Also provided is an ophthalmic drug delivery system comprising at least one of the compounds described above embedded in the contact lens and a kit to incorporate the ophthalmic into a contact lens. Methods for incorporating these compounds onto a contact lens without affecting transparency and for use in treating an ophthalmologic-associated condition are provided.

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The present disclosure discloses compositions and methods for multipurpose disinfection and sterilization solutions broadly effective against multiple microbial pathogens. The present disclosure demonstrates broad spectrum antimicrobial activity against environmental and pathogenic amoeba, bacterial spores, vegetative bacteria, fungi, rickettsia, viruses, parasites and toxic microbial products. The multipurpose disinfection solutions of the present disclosure may be used alone or in combination for a variety of purposes, including disinfection of medical devices such as contact lenses, contact lens cases, surgical instruments, and dental instruments.

The present disclosure discloses compositions and methods for multipurpose disinfection and sterilization solutions broadly effective against multiple microbial pathogens. The present disclosure demonstrates broad spectrum antimicrobial activity against environmental and pathogenic amoeba, bacterial spores, vegetative bacteria, fungi, rickettsia, viruses, parasites and toxic microbial products. The multipurpose disinfection solutions of the present disclosure may be used alone or in combination for a variety of purposes, including disinfection of medical devices such as contact lenses, contact lens cases, surgical instruments, and dental instruments.

The present invention relates to: a composition; a contact lens coating agent; a method of producing a contact lens; and a contact lens. The composition contains: a polymer which includes a repeating unit (A) having an HLB value of 14 or higher and a repeating unit (B) having an HLB value of 1 to less than 14; and a cationic group-containing bactericidal compound.

An anti-microbial preservative for use in ophthalmic and dermatologic products. The preservative includes from about 0.005 wt. % to about 0.20 wt. % chlorite compound and from about 0.005 wt. % to about 0.05 wt. % peroxy compound. Additionally, the preservative does not generate chlorine dioxide within the pH range of 5.0-8.8. Also included are an antimicrobial ophthalmic and dermatologic compositions for direct application onto an eye or skin of a living being including from about 0.005 wt. % to about 0.20 wt. % chlorite compound and from about 0.005 wt. % to about 0.05 wt. % peroxy compound. Also included are methods for treating dryness of the eyes and skin disorders (e.g., wounds, burns, infections, ulcerations, psoriasis, etc.) and for disinfecting and cleansing contact lenses while in place upon an eye by applying the composition to the eye or to the contact lens.

An anti-microbial preservative for use in ophthalmic and dermatologic products. The preservative includes from about 0.005 wt. % to about 0.20 wt. % chlorite compound and from about 0.005 wt. % to about 0.05 wt. % peroxy compound. Additionally, the preservative does not generate chlorine dioxide within the pH range of 5.0-8.8. Also included are an antimicrobial ophthalmic and dermatologic compositions for direct application onto an eye or skin of a living being including from about 0.005 wt. % to about 0.20 wt. % chlorite compound and from about 0.005 wt. % to about 0.05 wt. % peroxy compound. Also included are methods for treating dryness of the eyes and skin disorders (e.g., wounds, burns, infections, ulcerations, psoriasis, etc.) and for disinfecting and cleansing contact lenses while in place upon an eye by applying the composition to the eye or to the contact lens.

A sump sanitizing system is provided including a UV energy source within a sump tank. The UV energy source may be a light bulb or tube that is submersed in the collected groundwater water within the sump tank. The light bulb or tube may be self contained and waterproof, and may utilized light emitting diodes (LED), or other functional similar UV producing mechanism. For new sump installations the system may be integrated within the other operational components and controls utilized for water removal. For aftermarket installations, a UV source may be fixed to or mounted within an existing sump tank in a manner so as to not interfere with the systems other operations. An electrical power supply may be in communication with the UV source. Power may be communicated in a constant manner, or controlled for intermittent operation with a timer or other type of controller.

A sump sanitizing system is provided including a UV energy source within a sump tank. The UV energy source may be a light bulb or tube that is submersed in the collected groundwater water within the sump tank. The light bulb or tube may be self contained and waterproof, and may utilized light emitting diodes (LED), or other functional similar UV producing mechanism. For new sump installations the system may be integrated within the other operational components and controls utilized for water removal. For aftermarket installations, a UV source may be fixed to or mounted within an existing sump tank in a manner so as to not interfere with the systems other operations. An electrical power supply may be in communication with the UV source. Power may be communicated in a constant manner, or controlled for intermittent operation with a timer or other type of controller.

Provided herein are fluorinated compounds having chemical structures: (I) where n is 0 or greater, or (II) where m and n are 0 or greater, or an amino acid, a soluble polymer, an oligo(ethylene glycol), a poly(ethylene glycol), or a carbohydrate each fluorinated with perfluorocarbons having the chemical structure (III) where n is 0 or greater. These fluorinated compounds are utilized in contact lenses to impart lipid-resistant, protein-resistant and biofouling-resistant properties, thus reducing discomfort and infection caused by contact lens wear without changing its transmission characteristics. Also provided is an ophthalmic drug delivery system comprising at least one of the compounds described above embedded in the contact lens and a kit to incorporate the ophthalmic into a contact lens. Methods for incorporating these compounds onto a contact lens without affecting transparency and for use in treating an ophthalmologic-associated condition are provided.

Provided herein are fluorinated compounds having chemical structures: (I) where n is 0 or greater, or (II) where m and n are 0 or greater, or an amino acid, a soluble polymer, an oligo(ethylene glycol), a poly(ethylene glycol), or a carbohydrate each fluorinated with perfluorocarbons having the chemical structure (III) where n is 0 or greater. These fluorinated compounds are utilized in contact lenses to impart lipid-resistant, protein-resistant and biofouling-resistant properties, thus reducing discomfort and infection caused by contact lens wear without changing its transmission characteristics. Also provided is an ophthalmic drug delivery system comprising at least one of the compounds described above embedded in the contact lens and a kit to incorporate the ophthalmic into a contact lens. Methods for incorporating these compounds onto a contact lens without affecting transparency and for use in treating an ophthalmologic-associated condition are provided.