REFERENCES KOPF, M., YI, F., ISKANDER, D. R., COLLINS, M. J., SHAW, A. J. & STRAKER, B. (2008) Tear Film Surface Quality with Soft Contact Lenses Using Dynamic Videokeratoscopy. Journal of Optometry, 1, 14-21 KUPER, S. & STUKE, M. (1987) FEMTOSECOND UV EXCIMER LASER ABLATION. Applied Physics B-Photophysics <strong>and</strong> Laser Chemistry, 44, 199- 204. KWON, Y. & BOTT, S. (2008) Postsurgery corneal asphericity <strong>and</strong> spherical aberration due to ablation efficiency reduction <strong>and</strong> corneal remodelling in refractive surgeries. Eye. LACKNER, B., SCHMIDINGER, G., PIEH, S., FUNOVICS, M. A. & SKORPIK, C. (2005) Repeatability <strong>and</strong> reproducibility of central corneal thickness measurement with Pentacam, Orbscan, <strong>and</strong> ultrasound. Optometry <strong>and</strong> Vision Science, 82, 892-899. LE GRAND, Y. & EL HAGE, S. G. (1980) Physiological <strong>Optics</strong> (Vol. 1), Berlin- Heidelberg, Springer Verlag. LIANG, J., GRIMM, B., GOELZ, S. & BILLE, J. F. (1994) Objective measurement of wave aberrations of the human eye with the use of a Hartmann-Shack wavefront sensor. Journal of the Optical Society of America A, 11, 1949-1957. LINDSKOOG PETTERSSON, A., JARKO, C., ALVIN, A., UNSBO, P. & BRAUTASET, R. (2008) Spherical aberration in contact lens wear. Cont Lens Anterior Eye, 31, 189-93. LOPEZ-GIL, N., CASTEJON-MOCHON, J. F., BENITO, A., MARIN, J. M., LO-A- FOE, G., MARIN, G., FERMIGIER, B., RENARD, D., JOYEUX, D., CHATEAU, N. & ARTAL, P. (2002) Aberration generation by contact lenses with aspheric <strong>and</strong> asymmetric surfaces. 3rd International Confress of Wavefront Sensing <strong>and</strong> Aberration-free Refractive Correction. Interlaken, Switzerl<strong>and</strong>, Slack Inc. LU, F., MAO, X. J., QU, J., XU, D. & HE, J. C. (2003) Monochromatic wavefront aberrations in the human eye with contact lenses. Optometry <strong>and</strong> Vision Science, 80, 135-141. LLORENTE, L. (2009) Optical aberrations in ametropic eyes <strong>and</strong> their change with corneal refractive surgery. PhD <strong>Thesis</strong>, City University London. LLORENTE, L., BARBERO, B., MERAYO, J. & MARCOS, S. (2004a) Changes in corneal <strong>and</strong> total aberrations induced by LASIK surgery for hyperopia. Journal of Refractive Surgery, 20, 203-216. LLORENTE, L., BARBERO, S., CANO, D., DORRONSORO, C. & MARCOS, S. (2004b) Myopic versus hyperopic eyes: axial length, corneal shape <strong>and</strong> optical aberrations. http://journalofvision.org/4/4/5/. Journal of Vision, 4, 288. LLORENTE, L., DIAZ-SANTANA, L., LARA-SAUCEDO, D. & MARCOS, S. (2003) Aberrations of the human eye in visible <strong>and</strong> near infrared illumination. Optometry <strong>and</strong> Vision Science, 80, 26-35. LLORENTE, L., MARCOS, S., BARBERO, S., NAVARRO, R. & MORENO- BARRIUSO, E. (2001) Ocular aberrations in infrared <strong>and</strong> visible light using a laser ray tracing technique. Investigative Opthalmology <strong>and</strong> <strong>Visual</strong> Science, (Suppl.) 42, 87. LLORENTE, L., MARCOS, S., DORRONSORO, C. & BURNS, S. (2007) The effect of sampling on real ocular aberration measurements. Journal of the Optical Society of America A., 24, 2783-2796 277
REFERENCES MACRAE, S. M., SCHWIEGERLING, J. & SNYDER, R. (2000) Customized corneal ablation <strong>and</strong> super vision. Journal of Refractive Surgery, 16, 230-235. MAEDA, N. (2009) Clinical applications of wavefront aberrometry - a review. Clinical <strong>and</strong> Experimental Ophthalmology, 37, 118-129. MAEDA, P. Y. (2003) Zernike Polynomials <strong>and</strong> Their Use in Describing the Wavefront Aberrations of the Human Eye. Applied Vision <strong>and</strong> Imaging Systems. Stanford University. MALACARA, D. (1992) Optical Shop Testing, New York, John Wiley & Sons, Inc. MANNS, F., FERNANDEZ, V., ZIPPER, S., SANDADI, S., HAMAOUI, M., HO, A. & PAREL, J. M. (2004) Radius of curvature <strong>and</strong> asphericity of the anterior <strong>and</strong> posterior surface of human cadaver crystalline lenses. Experimental Eye Research, 78, 39-51. MANNS, F., HO, A., PAREL, J. M. & CULBERTSON, W. (2002a) Ablation profiles for wavefront-guided correction of myopia <strong>and</strong> primary spherical aberration. Journal of Cataract <strong>and</strong> Refractive Surgery, 28, 766-774. MANNS, F., MILNE, P. & PAREL, J. M. (2002b) Ultraviolet corneal photoablation. 3rd International Confress of Wavefront Sensing <strong>and</strong> Aberration-free Refractive Correction. Interlaken, Switzerl<strong>and</strong>, Slack Inc. MANZANERA, S., PRIETO, P. M., CANOVAS, C., WEEBER, H., PIERS, P. & ARTAL, P. (2009) Predicting <strong>Visual</strong> Estimates of Depth of Focus From Optical Data. ARVO Abstract. Invest. Ophthalmol. Vis. Sci., 50, E-Abstract 1157. MARCOS, S. (2001) Aberrations <strong>and</strong> <strong>Visual</strong> Performance following st<strong>and</strong>ard laser vision correction. J. Refract. Surgery, 17, 596-601. MARCOS, S. (2002) Are changes in ocular aberrations with age a significant problem for refractive surgery Journal of Refractive Surgery, 18, 572-578. MARCOS, S., BARBERO, B., LLORENTE, L. & MERAYO-LLOVES, J. (2001a) Optical response to LASIK for myopia from total <strong>and</strong> corneal aberration measurements. Investigative Ophthalmology <strong>and</strong> <strong>Visual</strong> Science, 42, 3349- 3356. MARCOS, S., BARBERO, S. & JIMÉNEZ-ALFARO, I. (2005a) Optical quality <strong>and</strong> depth-of-field of eyes implanted with spherical <strong>and</strong> aspheric intraocular lenses. Journal of Refractive Surgery, 21, 223-235. MARCOS, S., BARBERO, S. & LLORENTE, L. (2001b) Why high myopic eyes tend to be more aberrated Optical Society of America Technical Digest. Long Beach, CA. MARCOS, S. & BURNS, S. A. (2000) On the symmetry between eyes of wavefront aberration <strong>and</strong> cone directionality. Vision Research, 40, 2437-2447. MARCOS, S., BURNS, S. A., MORENO-BARRIUSO, E. & NAVARRO, R. (1999) A new approach to the study of ocular chromatic aberrations. Vision Research, 39, 4309-4323. MARCOS, S., CANO, D. & BARBERO, S. (2003) Increase of corneal asphericity after st<strong>and</strong>ard myopic LASIK surgery is not inherent to the Munnerlyn algorithm. Journal of Refractive Surgery, 19, 592-596. MARCOS, S., DÍAZ-SANTANA, L., LLORENTE, L. & DAINTY, C. (2002) Ocular aberrations with ray tracing <strong>and</strong> Shack-Hartmann wavefront sensors: does polarization play a role Journal of the Optical Society of America A., 19, 1063-1072. 278
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Doctoral thesis Corneal Ablation an
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Contents Corneal Ablation and Conta
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2.2.1. Fitting surfaces............
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5.3.3. Ablation efficiency factors
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10.5. DISCUSSION...................
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We thank José Antonio Sánchez-Gil
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BOZR Back Optic Zone Radius BCVA Be
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INTRODUCTION 1.1. MOTIVATION The fr
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INTRODUCTION 1.2. THE OPTICAL SYSTE
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INTRODUCTION Myopia is a very commo
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INTRODUCTION a point focus: the dif
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INTRODUCTION system, and tilt repre
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INTRODUCTION term Z 0 2 stands for
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INTRODUCTION which image was shadow
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INTRODUCTION The defocus Zernike te
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INTRODUCTION 1.4.6.3. Internal Aber
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INTRODUCTION 1.5.2.3. Alternating v
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INTRODUCTION and further-more, at l
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INTRODUCTION alcohol is used to loo
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INTRODUCTION changes in reflectivit
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INTRODUCTION Marcos et al. (Marcos
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INTRODUCTION 1.7.3. Ablation effici
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INTRODUCTION corneal surface may be
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INTRODUCTION Algorithm design: The
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INTRODUCTION contact lenses the fie
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INTRODUCTION 1.10.1. Tear studies A
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INTRODUCTION there are still many u
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INTRODUCTION 6. Evaluation and unde
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METHODS 2Chapter Chapter 2 - Method
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METHODS 2.1. MEASUREMENT OF OPTICAL
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METHODS In both profilometers, cust
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METHODS The measurement method that
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METHODS Fig. 2. 9. Set of points in
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METHODS Slit lamp Scheimpflug Camer
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METHODS representing the deviation
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METHODS 2.2.2.2. Ablation pattern f
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METHODS direction. These calculatio
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METHODS eye through the whole pupil
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METHODS (1993) power thresholds for
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METHODS alignment (frontal-illumina
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METHODS Fig. 2. 24. Example frame f
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METHODS 4) New image processing too
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METHODS Fig. 2. 28. Corrected entra
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METHODS Badal lens, corresponds to
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METHODS Each VA measurement consist
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REFRACTIVE SURGERY PMMA MODEL 3.1.
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CHAPTER 3 optimization of refractiv
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CHAPTER 3 These data demonstrate th
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CHAPTER 3 regression line, since it
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CHAPTER 3 Figure 3.3 shows one of t
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CHAPTER 3 Ablation efficiency facto
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CHAPTER 3 considering the same set
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CHAPTER 3 3.5.3 Impact of correctio
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ABLATION PROPERTIES OF FILOFOCON A
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ABLATION PROPERTIES OF FILOFOCON A
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ABLATION PROPERTIES OF FILOFOCON A
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ABLATION PROPERTIES OF FILOFOCON A
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ABLATION PROPERTIES OF FILOFOCON A
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ABLATION PROPERTIES OF FILOFOCON A
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ABLATION PROPERTIES OF FILOFOCON A
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ABLATION PROPERTIES OF FILOFOCON A
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OPTIMIZED LASER PLATFORMS 5.1 ABSTR
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CHAPTER 5 pulses. Fluence, repetiti
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CHAPTER 5 ablations. The slit-confo
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CHAPTER 5 (Anera et al., 2003): d S
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CHAPTER 5 asymmetries also appeared
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CHAPTER 5 5.3.4. Ablation patterns
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CHAPTER 5 a) b) : 6.5 mm c) Fig. 5.
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CHAPTER 5 achieve proper reflection
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CHAPTER 5 Both the ablation algorit
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HYBRID PORCINE/PLASTIC MODEL 6.1. A
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CHAPTER 6 6.3.1. Hybrid porcine-pla
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CHAPTER 6 is detected. Therefore, i
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CHAPTER 6 no preferential orientati
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ANTERIOR AND POSTERIOR CORNEAL ELEV
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ANTERIOR AND POSTERIOR CORNEAL ELEV
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ANTERIOR AND POSTERIOR CORNEAL ELEV
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ANTERIOR AND POSTERIOR CORNEAL ELEV
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ANTERIOR AND POSTERIOR CORNEAL ELEV
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ANTERIOR AND POSTERIOR CORNEAL ELEV
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ANTERIOR AND POSTERIOR CORNEAL ELEV
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183
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SOFT CONTACT LENS FITTING USING MOD
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SOFT CONTACT LENS FITTING USING MOD
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ON-EYE OPTICAL PERFORMANCE OF RIGID
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ON-EYE OPTICAL PERFORMANCE OF RIGID
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ON-EYE OPTICAL PERFORMANCE OF RIGID
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- Page 244 and 245: REFERENCES References AIZAWA, D., S
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