Nanoscaled Morphology and Mechanical Properties of a Biomimetic Polymer Surface on a Silicone Hydrogel Contact Lens.

Materials taking advantage of the characteristics of biological tissues are strongly sought after in medical science and bioscience. On the natural corneal tissue surface, the highly soft and lubricated surface is maintained by composite structures composed of hydrophilic biomolecules and substrates. To mimic this structure, the surface of a silicone hydrogel contact lens was modified with a biomimetic phospholipid polymer, poly(2-methacryloyloxyethyl phosphorylcholine) (PMPC), and the nanoscaled morphology and mechanical properties of the surface were confirmed with advanced surface characterization and imaging techniques under an aqueous medium. Concavities and convexities on the nanometer order were recognized on the surface. The surface was completely covered with a PMPC layer and remained intact even after 30 days of clinical use in a human ocular environment. The mechanical properties of the natural corneal tissue and the PMPC-modified surface were similar in the living environment, that is, low modulus and frictional properties comparable to natural tissues. These results show the validity of material preparation by biomimetic methods. The methodologies developed in this study may contribute to future development of human-friendly medical devices.

Surface characterization of a silicone hydrogel contact lens having bioinspired 2-methacryloyloxyethyl phosphorylcholine polymer layer in hydrated state.

A silicone hydrogel contact lens material, with a unique chemical and physical structure has been designed for long-term ocular performance. Enhancement of this silicone hydrogel contact lens material was achieved through surface modification using a cross-linkable bioinspired 2-methacryloyloxyethyl phosphorylcholine (MPC) polymer, which creates a soft surface gel layer on the silicone hydrogel base material. The surface properties of this MPC polymer-modified lens were characterized under hydrated condition revealing, inter alia, its unique polymer structure, excellent hydrophilicity, lubricity, and flexibility. Analysis of the MPC polymer layer in a hydrated state was performed using a combination of a high-resolution environmental scanning electron microscopy and atomic force microscopy. Compared to the silicone hydrogel base material, this surface had a higher captive bubble contact angle, which corresponds to higher hydrophilicity of the surface. In addition, the hydrated MPC polymer layer exhibited an extremely soft surface and reduced the coefficient of friction by more than 80 %. These characteristics were attributed to the hydration state of the MPC polymer layer on the surface of the silicone hydrogel base material. Also, interaction force of protein deposition was lowered on the surface. Such superior surface properties are anticipated to contribute to excellent ocular performance.

Freeze-fracture examination of cultured human trabecular meshwork cells: effect of dexamethasone.

Glucocorticoids can alter the trabecular meshwork in the aqueous outflow pathway of the eye leading to the development of ocular hypertension and glaucoma. Previous studies have shown biochemical and ultrastructural changes in cultured human trabecular meshwork (TM) cells treated with dexamethasone (DEX). In order to assess how the membranes of these treated cells were responding to this glucocorticoid, we compared DEX-treated and control TM cells using the freeze-fracture technique. Human TM cells were grown to confluence on either Millipore HA filter inserts or glass coverslips and then treated for 14 days with or without 0.1 microM dexamethasone. The cell cultures were then aldehyde fixed and prepared for electron microscopy and freeze-fracture. Junctional complexes in control and DEX-treated cells consisted of gap junctions of various shapes and sizes. No tight junctional complexes were apparent in either control or DEX-treated cells. The majority of vesicle fusion sites on the control cells appeared to be randomly distributed and were few in number. In contrast, DEX-treated cells had a significantly greater density of fusion sites, and the majority of the vesicles were aligned into linear arrays. These findings support our previous findings of increased secretory activity in DEX-treated cultured human TM cells. These in vitro model system data appear to correlate with previous in vivo biochemical, ultrastructural and freeze-fracture data.