Systems and methods for recharging zirconium phosphate and zirconium oxide are provided. The systems and methods provide for recharging of the zirconium phosphate and zirconium oxide in reusable sorbent modules. The systems and methods include recharging flow paths for recharging zirconium phosphate independently or concurrently.

The present invention recognizes that medical devices, such as but not limited to contact lenses, can be made having a coating made at least in part using printing technologies to provide drug storage and drug release structures. The coating preferably includes at least one drug reservoir layer and a least one barrier layer, and can include structures, such as but not limited to capillary structures, which alone or in combination modulate the release of the drug from the coating. One aspect of the present invention is a medical device that incorporates a drug in at least one coating. A second aspect of the present invention is a method of making a medical device that incorporates a drug in at least one coating. A third aspect of the present invention is a method of using a medical device of the present invention to treat or prevent a disease, disorder or condition.

The present invention recognizes that medical devices, such as but not limited to contact lenses, can be made having a coating made at least in part using printing technologies to provide drug storage and drug release structures. The coating preferably includes at least one drug reservoir layer and a least one barrier layer, and can include structures, such as but not limited to capillary structures, which alone or in combination modulate the release of the drug from the coating. One aspect of the present invention is a medical device that incorporates a drug in at least one coating. A second aspect of the present invention is a method of making a medical device that incorporates a drug in at least one coating. A third aspect of the present invention is a method of using a medical device of the present invention to treat or prevent a disease, disorder or condition.

The present invention recognizes that medical devices, such as but not limited to contact lenses, can be made having a coating made at least in part using printing technologies to provide drug storage and drug release structures. The coating preferably includes at least one drug reservoir layer and a least one barrier layer, and can include structures, such as but not limited to capillary structures, which alone or in combination modulate the release of the drug from the coating. One aspect of the present invention is a medical device that incorporates a drug in at least one coating. A second aspect of the present invention is a method of making a medical device that incorporates a drug in at least one coating. A third aspect of the present invention is a method of using a medical device of the present invention to treat or prevent a disease, disorder or condition.

The present invention recognizes that medical devices, such as but not limited to contact lenses, can be made having a coating made at least in part using printing technologies to provide drug storage and drug release structures. The coating preferably includes at least one drug reservoir layer and a least one barrier layer, and can include structures, such as but not limited to capillary structures, that alone or in combination modulate the release of the drug from the coating. One aspect of the present invention is a medical device that incorporates a drug in at least one coating. A second aspect of the present invention is a method of making a medical device that incorporates a drug in at least one coating. A third aspect of the present invention is a method of using a medical device of the present invention to treat or prevent a disease, disorder or condition.

A container (1) for accommodating an ophthalmic lens during a lens treatment process has a longitudinal axis (11) and comprises as separate elements a containment element (2), a mounting element (3), and a retaining element (4). The containment element (2) comprises a tubular section (21) and a bottom (22) arranged at a distal end of the tubular section (21), the bottom (22) protruding convexly towards the outside at the distal end of the tubular section (21) and being provided with a number of apertures (23, 24), the tubular section (21) at a proximal end (25) thereof having a latch (26) protruding from the proximal end (25) of the tubular section (21) towards the mounting element (3). The mounting element (3) comprises a sidewall (31) extending along the longitudinal axis (11) of the container (1), the sidewall (31) being provided with recesses or orifices (32) which are in engagement with the latch (26) of the containment element (2). The mounting element (3) further comprises an access opening (37) arranged at a proximal end of the mounting element (3) remote from the containment element (2). The retaining element (4) is fixedly arranged in between the containment element (2) and the mounting element (3), the retaining element (4) being configured to prevent the ophthalmic lens from being washed out of the containment element (2) and to permit access for a gripper through the access opening (37) of the mounting element (3) into the containment element (2) for insertion and removal of the ophthalmic lens.

The present invention is generally related to a lens care system and method for disinfecting and cleaning contact lenses. A lens care system or method of the invention is based on electrolysis of an aqueous chloride solution for generating germicide species (e.g., chlorine, hypochlorous acid, hypochlorite, or combinations thereof) and subsequent in-situ electrolysis of hypochlorous acid or hypochlorite in the aqueous solution for neutralizing the generated germicide species.

The present invention is generally related to a lens care system and method for disinfecting and cleaning contact lenses. A lens care system or method of the invention is based on electrolysis of an aqueous chloride solution for generating germicide species (e.g., chlorine, hypochlorous acid, hypochlorite, or combinations thereof) and subsequent in-situ electrolysis of hypochlorous acid or hypochlorite in the aqueous solution for neutralizing the generated germicide species.

A container (1) for accommodating an ophthalmic lens during a lens treatment process has a longitudinal axis (11) and comprises as separate elements a containment element (2), a mounting element (3), and a retaining element (4). The containment element (2) comprises a tubular section (21) and a bottom (22) arranged at a distal end of the tubular section (21), the bottom (22) protruding convexly towards the outside at the distal end of the tubular section (21) and being provided with a number of apertures (23, 24), the tubular section (21) at a proximal end (25) thereof having a latch (26) protruding from the proximal end (25) of the tubular section (21) towards the mounting element (3). The mounting element (3) comprises a sidewall (31) extending along the longitudinal axis (11) of the container (1), the sidewall (31) being provided with recesses or orifices (32) which are in engagement with the latch (26) of the containment element (2). The mounting element (3) further comprises an access opening (37) arranged at a proximal end of the mounting element (3) remote from the containment element (2). The retaining element (4) is fixedly arranged in between the containment element (2) and the mounting element (3), the retaining element (4) being configured to prevent the ophthalmic lens from being washed out of the containment element (2) and to permit access for a gripper through the access opening (37) of the mounting element (3) into the containment element (2) for insertion and removal of the ophthalmic lens.

A lens drying system includes a sterile gas supply, a supply line, and an annular body. The body is connected to the supply line and defines an internal channel. The internal channel, which is in fluid communication with the sterile gas supply via the supply line, defines a plurality of openings. The openings are collectively configured to direct a flow of a sterile gas, e.g., a filtered and desiccated medical grade gas, from the sterile gas supply onto a lens surface of an ophthalmic front lens. This occurs during a non-contact wide-angle visualization process to mitigate fogging of the lens surface. A processor of a surgical console may receive user preference settings, including a desired steady-state flow rate and/or a desired pulse rate of the sterile gas. The processor could then command the desired steady-state flow rate and/or a desired pulse rate from the surgical console.