Low_resolution_Thesis_CDD_221009_public - Visual Optics and ...

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$XXX Congress of the European Society of Cataract and Refractive ...$

REFERENCES SAKIMOTO, T., ROSENBLATT, M. I. & AZAR, D. T. (2006) Laser eye surgery for refractive errors. Lancet, 367, 1432-1447. SALMON, T. O. & DE POL, C. V. (2006) Normal-eye Zernike coefficients and rootmean-square wavefront errors. Annual Meeting of the American-Academy-of- Optometry. San Diego, CA, Elsevier Science Inc. SAWIDES, L., GAMBRA, E., PASCUAL, D., DORRONSORO, C. & MARCOS, S. (2009) Visual performance with real-life tasks under Adaptive-Optics ocular aberration correction. Journal of Vision, Submitted. SCHULTZE, R. (1998) Accuracy of corneal elevation with four corneal topography systems. J Refract Surg, 14, 100-104. SCHWIEGERLING, J., GREIVENKAMP, J. & MILLER, J. (1995) Representation of videokeratoscopic height data with Zernike polynomials. Journal of the Optical Society of America A, 12, 2105-2113. SCHWIEGERLING, J. & GREIVENKAMP, J. E. (1997) Using corneal height maps and polynomial decomposition to determine corneal aberrations. Optometry and Vision Science, 74, 906-16. SCHWIEGERLING, J., SNYDER, R. & MACRAE, S. (2001) Optical aberrations and ablation pattern design. IN MCRAE, S., KRUEGER, R. & APPLEGATE, R. (Eds.) Customized corneal ablation: The quest for super vision. SEILER, T., KAEMMERER, M., MIERDEL, P. & KRINKE, H.-E. (2000) Ocular optical aberrations after photorefractive keratectomy for myopia and myopic astigmatism. Archive of Ophthalmology, 118, 17-21. SEILER, T. & WOLLENSAK, J. (1986) INVIVO EXPERIMENTS WITH THE EXCIMER LASER - TECHNICAL PARAMETERS AND HEALING- PROCESSES. Ophthalmologica, 192, 65-70. SEITZ, B., TORRES, F., LANGENBUCHER, A., BEHRENS, A. & SUAREZ, E. (2001) Posterior corneal curvature changes after myopic laser in situ keratomileusis. Ophthalmology, 108, 666-673. SHACK, R. V. & PLATT, B. C. (1971) PRODUCTION AND USE OF A LENTICULAR HARTMANN SCREEN. Journal of the Optical Society of America, 61, 656-&. SICAM, V., DUBBELMAN, M. & VAN DER HEIJDE, R. G. L. (2006) Spherical aberration of the anterior and posterior surface of the human cornea. Journal of the Optical Society of America a-Optics Image Science and Vision, 23, 544-549. SMIRNOV, M. S. (1961) Measurement of the wave aberration of the human eye. Biofizika, 6, 687-703. SMITH, G. & ATCHISON, D. A. (1997) The Eye and Visual Optical Instruments, Cambridge University Press. SMITH, G., COX, M., CALVER, R. & GARNER, L. (2001) The spherical aberration of the crystalline lens of the human eye. Vision Research, 15, 235-243. SMOLEK, M. K. (1993) Interlamellar cohesive strength in the vertical meridian of human eye bank corneas. Investigative Ophthalmology & Visual Science, 34, 2962-2969. SPADEA, L., FASCIANI, R., NECOZIONE, S. & BALESTRAZZI, E. (2000) Role of the corneal epithelium in refractive changes following laser in situ keratomileusis for high myopia. J Refract Surg., 16, 133-139. SRINIVASAN, R. (1986) Ablation of polymers and biological tissue by ultraviolet lasers. Science, 234, 559-565. 283
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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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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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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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Page 208 and 209: ON-EYE OPTICAL PERFORMANCE OF RIGID
Page 210 and 211: ON-EYE OPTICAL PERFORMANCE OF RIGID
Page 212: SOFT MONOFOCAL AND MULTIFOCAL CONTA
Page 216: SOFT MONOFOCAL AND MULTIFOCAL CONTA
Page 220 and 221: CORRELATION BETWEEN RADIUS AND ASPH
Page 230: CONCLUSIONS Conclusions This thesis
Page 233 and 234: CONCLUSIONS 5We have developed a pr
Page 236: CONCLUSIONS LIST OF METHODOLOGICAL
Page 240 and 241: CONCLUSIONS FUTURE RESEARCH LINES T
Page 242 and 243: CONCLUSIONS LIST OF PUBLICATIONS AN
Page 244 and 245: REFERENCES References AIZAWA, D., S
Page 246 and 247: REFERENCES PHOTODECOMPOSITION (APD)
Page 248 and 249: REFERENCES DORRONSORO, C., CANO, D.
Page 250 and 251: REFERENCES GISPETS, J., ARJONA, M.
Page 252 and 253: REFERENCES KOPF, M., YI, F., ISKAND
Page 254 and 255: REFERENCES MARCOS, S., DORRONSORO,
Page 256 and 257: REFERENCES NOVO, A., PAVLOPOULOS, G
Page 260: REFERENCES WANG, L., DAI, E., KOCH,
Page 263 and 264: RESÚMENES pacientes reales fue com
Page 265 and 266: RESÚMENES experimentales de cirug
Page 267 and 268: RESÚMENES cada punto de las cornea
Page 269 and 270: RESÚMENES plástico medidas anteri
Page 272 and 273: RESÚMENES 8 Evaluación óptica de
Page 274 and 275: RESÚMENES 9 Prestaciones ópticas
Page 276 and 277: RESÚMENES 10 Calidad óptica y cal
Page 278: RESÚMENES A Correlación entre rad
Page 281 and 282: CONCLUSIONES clínicos. La descripc
Page 283 and 284: CONCLUSIONES 12 Las superficies ocu
Page 286: CONCLUSIONES IMPLICACIONES DE ESTA
Page 289 and 290: CONCLUSIONES contribuyen a la compr
Page 291: (y muchísimo más difícil). Me da
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