A preservative-free, sterile packaged ophthalmic device product is disclosed. The preservative-free, sterile packaged ophthalmic device product is obtained by (a) adding at least one polyquaternium polymer to an aqueous packaging solution for preventing antimicrobial contamination during storage; (b) packaging the aqueous packaging solution and an ophthalmic device in a manner preventing contamination of the ophthalmic device by one or more microorganisms; and (c) heat sterilizing the aqueous packaging solution and the ophthalmic device, whereby the at least one polyquaternium polymer decomposes during the heat sterilizing to obtain the preservative-free packaged ophthalmic device product.

A glycophospholipid polymer is disclosed. The glycophospholipid polymer comprises a reaction product of one or more glycosaminoglycans and one or more phospholipids. Also disclosed is a glycophospholipid polymeric network comprising a reaction product of one or more glycosaminoglycans, one or more phospholipids and, one or more crosslinking agents.

A corrective lens system for the eyes of an individual includes first and second pairs of lenses of first and second prescriptions, respectively. In certain embodiments, the first pair of lenses includes a first lens for the left eye and a first lens for the right eye, and the second pair of lenses includes a second lens for the left eye and a second lens for the right eye. The first and second pairs of lenses may be configured in package having a plurality of compartments with individual lenses disposed in individual compartments. A set of instructions may be provided for wearing the first pair of lenses for a first time period and the second pair of lenses for a second time period. The first prescription is different from the second prescription. The lenses may inhibit the progression of myopia in the individual. Methods of arranging, prescribing, and using the lens system are described.

A method for detecting the presence or absence of an ophthalmic lens (10), in particular of a contact lens, within a receptacle (1), including the steps of: detecting infrared radiation coming from at least a portion (3) of the receptacle (1) where the ophthalmic lens (10) is supposedly accommodated, analyzing the detected infrared radiation in a spectral portion in which absorbance (A.sub.L) of a material the ophthalmic lens is made of is significantly different from absorbance (A.sub.R) of a material the receptacle is made of, and from the analysis of the spectral portion detecting the presence or absence of the ophthalmic lens (10) within the receptacle.

A packaging system for storing ophthalmic devices such as contact lenses and methods for packaging such ophthalmic devices with solutions is disclosed. The packaging system contains an unused, ophthalmic device in an aqueous packaging solution comprising tris(hydroxymethyl)aminomethane or a salt thereof; wherein the solution has an osmolality of at least about 200 mOsm/kg and a pH in the range of about 6 to about 9.

A blister package for a contact lens is provided. A deformable slider supporting a lens is movable via pull-tab or hinge to lift the contact lens out of a lens well. The deformable slider can include a hinge connected to a flexible peel-away top of the blister package or connected to a pull tab that can be pulled to pull taut the deformable slider. A blister package is also provided that includes a hinged shell having a lateral opening opposite the hinge, and a deformable slider that is folded over onto itself and seals both a top chamber and a bottom chamber. By pulling a tongue of the deformable slider, which extends from the lateral opening, the deformable slider can be removed from the closed shell and the closed shell can be opened enabling access to the contact lens.

The present invention relates to a method to load a water insoluble phospholipid as nanoparticles to load into a hydrogel contact lens in autoclaving process during the hydrogel contact lens manufacturing process without an extra manufacturing step and without swelling the hydrogel contact lens with an organic solvent. The phospholipid nanoparticles loaded in hydrogel contact lens subsequently releases to the eye upon wearing.

The present invention relates to a method to load a water insoluble phospholipid as nanoparticles to load into a hydrogel contact lens in autoclaving process during the hydrogel contact lens manufacturing process without an extra manufacturing step and without swelling the hydrogel contact lens with an organic solvent. The phospholipid nanoparticles loaded in hydrogel contact lens subsequently releases to the eye upon wearing.

A method for determining whether a sealing area of a primary packaging container for an ophthalmic lens is unacceptable for properly sealing a foil to the sealing area is disclosed. The method involves comparing the temperature of an infrared image of the sealing area to a reference temperature to determine if the difference in temperature exceeds a predetermined threshold.

Contact lens packaging (2) includes two or more individual, sealed blister packs (1) coupled together by a connecting label (5), which includes a uni-axial shear polymer film (6). The connecting label (5) is arranged and oriented such that the tear direction of the polymer film (6) is parallel to a line (A) bisecting adjacent blister packs (1). Methods of binding together two or more blister packs (1) are also described.