Abstract
The absorption of protein and formation of biofilms on the surface of ophthalmic lenses is one of the factors that destroy their useful performance by causing severe visual impairment, inflammation, dryness and ultimate eye discomfort. Therefore, eye lenses need to be resilient to protein absorption, which is one of the opacity factors in minimizing protein absorption on the lenses. The purpose of this study was to investigate and reduce sediment biotransformation on the surface of the semi-hardened lens based on acrylate by bulk-free radical polymerization method. In this respect, the effect of poly(ethylene glycol) diacrylate (PEGDA) with two different molecular weights of 200 and 600 g/mol on the surface roughness, protein absorption, and hydrophilicity of the lenses were studied. The surface hardness of the lenses, on shore D scale, was measured using a durometer hardness test. The presence of higher molecular weight of PEGDA hydrophilic polymeric monomers reduced the hardness of the lenses. The effect of introducing PEGDA, with two molecular weights, into lens fabrication formulations was studied with respect to their water content parameters and hydrophilicity. The presence of a crosslinker such as poly(ethylene glycol) diacrylates, at two different molecular weights, increased the water content and hydrophilicity of the produced lenses. Surface roughness is associated with the formation of bio-film and accumulation of microorganisms on the surface. Due to the roughness of the lens surface developed in this research, the lenses containing PEGDA 600 exhibited less roughness compared to that of PEGDA 200, which could also affect the absorption of protein. Therefore, according to the results of protein absorption test, the PEGDA 600 lenses showed lower protein absorption, which could be due to their high degree of water absorption and hydrophilicity.
Highlights
One of the common problems in the ophthalmology is opacification of the hard and soft contact lenses
Hydrogel ophthalmic lenses based on a wide variety of different acrylic monomers including 2-hydroxyethyl-methacrylate, acrylamide, acrylic acid, ethylene glycol diamethacrylate, ethylhexyl methacrylate, methyl acrylate, and silicon acrylic monomers were developed (Muter 2015; Musgrave and Fang 2019)
Poly(ethylene glycol) diacrylates can form chemical gels alone or in combination with other polymer monomers linked by covalent bonding through networking reactions
Summary
One of the common problems in the ophthalmology is opacification of the hard and soft contact lenses. Acrylic-based hydrogels as the main component of contact lens formulations should provide certain physical and chemical properties such as good transparency, excellent permeability (especially oxygen permeability), dimensional stability, hydraulic permeability, and protein and cell repellence, as well as good. Silicone acrylic-based hydrogels have advantages such as high oxygen permeability and high flexibility, but hydrophobic nature of this group of lenses leads to very low wettability and high protein deposition rates (Santos et al 2007). To overcome this problem, most hydrogel silicone lenses need to be modified to reduce the hydrophobic nature of the silicon components, as well as decrease the protein deposition on the surface of the lens. Physical and chemical properties of the lens such as water content, refractive index, hardness, mechanical strength and oxygen permeability can be aptly controlled by selection of the appropriate acrylic monomers (Marc et al 2018)
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