C. E. Purslow

This paper presents the two-dimensional simulation of heat propagation in the human eye model during contact lens wear with finite element analysis. Three types of contact lens are studied: Lotrafilcon A, Balafilcon A, and Etafilcon A. The models are solved for both steady and transient solutions. The corneal surface temperature during contact lens wear is found to decrease (average, 0.52 +/- 0.05 degrees C compared with a bare cornea for all lens types). A contact lens with a higher water content has a lower steady state temperature than a contact lens with a lower water content does. Various initial temperatures for the contact lens are found to affect the first 400 s of the temperature variation. When the initial temperature is lower than the corneal temperature, a reduction in temperature is observed during contact lens insertion while the opposite is observed when the initial temperature is higher than the corneal temperature. The increase in evaporation rate when a contact lens is worn increases the cooling effect on the ocular surface. This is suggested to be the cause of lower corneal surface temperature when wearing a contact lens.

PURPOSE: Mucins adhere to contact lenses (CLs), reflecting the renewal of the preocular fluid and enzymatic activity at the ocular surface. In this study, we aimed to analyze mucin fragmentation on materials new to the ocular surface and investigate whether this correlates with wearing comfort. METHODS: Lenses were obtained from new CL wearers after 2 weeks each of wearing vifilcon A, followed by senofilcon A, and then by vifilcon A lenses. Symptoms were evaluated using the Ocular Surface Disease Index (OSDI). CLs were extracted in a mixture of guanidinium hydrochloride and radioimmunoprecipitation assay buffer. Mucin mobility was analyzed after electrophoresis, Western blotting, and visualization with antibodies against mucin peptide core. Mobilities, normalized to total reactivity in the lane, were compared between visits for each subject and were expressed as shifts. RESULTS: Mucin (MUC)5AC polymers exceeding 260 kDa were observed in agarose gels; NuPAGE resolved polymers from 260 to 3.5 kDa: when large mucins were detected, the smallest fragments were missing. Fragmentation patterns were significantly different between lens types for MUC1 (analysis of variance, P = 0.006) and MUC4 (P < 0.001) but not for MUC5AC or MUC16 (P > 0.293). Mobility shifts of MUC1 and MUC4 were significantly negatively correlated (Pearson, r = -0.908; P = 0.002). For OSDI scores >15, mucin fragmentation was unchanged, whereas for OSDI scores <15, MUC4 and MUC5AC fragments were longer on vifilcon A than on senofilcon lenses (unpaired t test, P = 0.046), irrespective of the direction of change (analysis of variance, P > 0.366). Changes in MUC1 breakdown were significantly negatively correlated to the overall OSDI score (r = -0.891, P = 0.001). CONCLUSIONS: In asymptomatic CL wearers, only changes in mucin fragmentation in response to a new material were consistent and fast, irrespective of CL order. Lack of change seems, therefore, to be connected with discomfort during CL wear.

Many myodocopid ostracods are unusual in that they have well-developed compound eyes yet must view their environment through a shell. The cypridinid Macrocypridina castanea is relatively large among ostracods (about 5-10 mm) and is a pelagic predator. This species possess highly pigmented shells with a transparent region lying just above the eye. Here we examine the ultrastructure and transparency of this window using electron microscopy, serial-block face scanning electron microscopy and X-ray diffraction analysis and optical modelling. An internal, laminar stack was identified within the window region of the shell that formed a more regular half-wave reflector than in non-window regions, and where the distance between molecules in the chitin-protein fibrils decreases as compared to the non-window area. This results in excellent transmission properties-at around 99% transmission-for wavelengths between 350 and 630 nm due to its half-wave reflector organization. Therefore, blue light, common in the mid and deep sea, where this species inhabits, would be near-optimally transmitted as a consequence of the sub-micrometre structuring of the shell, thus optimizing the ostracod's vision. Further, pore canals were identified in the shell that may secrete substances to prevent microbial growth, and subsequently maintain transparency, on the shell surface. This article is part of the theme issue 'Bioinspired materials and surfaces for green science and technology'.