Open Access

Ophthalmic lenses are ideally measured in accordance with the center of rotation of the eye. Therefore a measuring device was constructed due to this principle to measure lenses with a focimeter. In this work that measuring device was validated. Lenses of ± 4 dpt in spherical and aspherical design were measured across a field of 9x9 measuring points being at 5° distance from each other. This corresponds to a field of view of 40°. The measurement points in x- and y- direction were theoretically calculated to validate the measurement results. Regarding angles of incidence up to 20° it was supposed that the main optical aberration depends on a change in the sagittal and tangential sphere powers which is also defined as astigmatism. Therefore the calculation presents the tangential and sagittal oblique sphere powers depending on the different angles of the line of vision. On average the measurement results and the calculated data of the spherical designed lenses coincide quite good (correlation at 0,98), the systematic deviation of both values on average is 0.01 dpt and the random error (standard deviation) amounts 0.03 dpt on average. The minimum deviation is -0.06 dpt and the maximum is 0.09 dpt. Common focimeters have a measuring inaccuracy of up to 0.06 dpt (Diepes, Blendowske 2002). Therefore the quality of the measured data should be reliable. The aspherical designed lenses were compared to the spherical designed lenses. With increased angles of incidence the astigmatism of the aspherical lenses leads to lower values than the astigmatism of the spherical lenses

Purpose The purpose of this study was to evaluate the validity of the iPad Aniseikonia Test for measurement size lens-induced aniseikonia. The iPad Aniseikonia Test is a new computer-based test designed for measuring aniseikonia in vertical direction. The iPad Test uses red-green anaglyphs. Methods Aniseikonia was induced in 21 subjects by means of afocal size lenses. Resulting aniseikonia was measured in vertical direction by the iPad Aniseikonia Test. The measurement was performed in dark condition with appropriate correction of refractive error. All subject were patients with normal vision with no anisometropia or other ocular problem. Results: Afocal size lenses of known magnification were used to induce aniseikonia. 5 measurements were taken in each subject, ranging from zero to 7 % magnification. When using the regression analysis, the slope of the fitted line significantly differs from 1. The average slope of regression line is 0,58. Conclusions: Only moderate accuracy was found for tested target size and orientation. In all cases the iPad Aniseikonia Test underestimates the level of aniseikonia. However for gross assessment of anisometropia in clinical practice it could be successfully used. Further study with different target size should be addressed.

Aim Patrick J. Caroline and Mark P. Andre first reported about soft lens orthokeratology in 2005. In a number of articles in the past five years, they reported about their research on this topic and their new findings. The aim of this study was to continue the research of Patrick J. Caroline and Mark P. Andre and to collect more information about the outcome of the technique. Methods Ten subjects with low myopia from -0.25 D to -1.25 D and a refractive astigmatism from plano to -0.75 D were fitted with a -10.00 D CIBA VISION AIR OPTIX® NIGHT&DAY® silicone hydrogel contact lens and were told to wear the lenses over night and everted. Corneal topography and refraction measurements were taken after one night, one week and one month of contact lens wear. Results Eight out of ten subjects finished the study, six female and two male. The mean age of the subjects was 23.9 years. With the eight subjects who finished the study, the mean change in subjective refraction was about +1.00 D in the sphere and +0.22 D in the cylinder, with maximum changes of +1.75 D sphere and +0.75 D cylinder. The mean apical power change, measured with the topographer, was 1.11 D. Changes in K - readings ranged from slight corneal steepening in both of the meridians to 0.23 mm of corneal flattening in the horizontal meridian and 0.27 mm of corneal flattening in the vertical meridian. Corneal eccentricity decreased about 0.65 on average. The main complaints and problems were the high minus power and the decentration of the contact lens and the occurrence of ghosting at night. Conclusion The results of this study show that everted wear of a high minus silicone hydrogel contact lens can lead to orthokeratology - such as changes in corneal topography and subjective refraction. These changes range from plano to +1.75 D sphere and +0.25 D to +0.75 D cylinder but are unpredictable and vary from subject to subject. Additional studies regarding the contact lens decentration and the unpredictability of the outcome need to be done to optimize the process.

Purpose The purpose of this study was to investigate the correlation of measured visual acuity (VA) both static and dynamic obtained with static and dynamic measuring tests, as well as, response time to visual stimulus and analysis of its influence on dynamic visual acuity. The aim was to compare the results gathered for the three age groups and analyze the possible differences. Methods The test groups consisted of 75 subjects between 10 and 60 years old, categorized in three age groups. The measurements of static and dynamic visual acuity and reaction time were conducted. The set of nine tests (five with radial magnification speed and four simulating driving condition at 72 km/h and 130 km/h) was designed in order to measure dynamic visual acuity and the set of two tests for reaction time measurement. Results Compared to static visual acuity in both tests, the results obtained with measurements of dynamic visual acuity resulted in lower values depending on Landolt ring size and magnification speed of animation. In average, the dynamic visual acuities in tests with different magnification speeds were lower than static by 0.4 visual acuity units, or 31% and the average of dynamic visual acuity after subtracting motoric component (reaction time) was for 0.2 visual acuity worse than static or 15%. In the second test simulating driving conditions at 72 km/h the average drop in dynamic visual acuity was 33% while at 130 km/h average drop for younger and middle age groups was 37% and for older group was 44% and after subtracting motor component values for 72 km/h speed simulation average drop in visual acuity values was 23% for all three groups; for 130 km/h speed simulation younger and middle aged group average drop of visual acuity was 20% and with older group it was 24%. Conclusion The tests used in this study were simple and fast and revealed significant difference between static and dynamic visual acuity and influence of reaction time on dynamic Nataša Vujko Muždalo Abstract 2 visual acuity values. It is hoped that this thesis will be a positive contribution in testing and training of dynamic visual and sensory response skill with drivers, sportsmen and people with visual-motor dysfunction. Keywords: Dynamic visual acuity (DVA), static visual acuity (SVA), reaction time (RT), motoric component, dynamic visual acuity test, reaction time test, radial increase in size

The Purpose of this thesis is to determine the indices of the Pentacam HR® which change enough in longitudinal data to detect and predict Keratoconus progression and how they correlate to demographic/other predictor variables.