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200 10$aCorneal Biomechanics and Refractive Surgery /$fedited by Fabio A. Guarnieri
205   $a1st ed. 2015.
210  1$aNew York, NY :$cSpringer New York :$cImprint: Springer,$d2015.
215   $a1 online resource (151 p.)
300   $aDescription based upon print version of record.
311   $a1-4939-1766-8 
320   $aIncludes bibliographical references and index.
327   $aContents; Contributors; Chapter 1: Introduction: Corneal Biomechanics and Refractive Surgery; 1 Refractive Surgery; 2 Biomedical Engineering; 3 Biomechanical Models for Refractive Surgery; 4 Chapter Organization; References; Chapter 2: Corneal Biomechanics; 1 Introduction; 2 The Cornea; 2.1 Anatomical and Physical Properties; 2.2 Histology of the Cornea; 2.3 Corneal Wound Healing; 3 Measurements of the Mechanical Parameters; 3.1 Extensibility of the Cornea; 3.2 Keratoconus Biomechanics; 3.3 Stromal and Descemet Membrane Extensibilities; 3.4 Bowman´s Membrane Importance
327   $a3.5 Viscoelastic Parameters4 Biomechanical Models; 5 Toward a Computer-Aided Design of the Refractive Surgery; 6 Data Acquisition; 6.1 Corneal Thickness; 6.2 Corneal-Limbal Ring; 6.3 Anterior Surface; 6.4 Intraocular Pressure; 6.5 Ocular Length and Depth of the Anterior Chamber; 6.6 Objective and Subjective Refraction; 7 Optical Model; 7.1 Generation of Incisions; 8 Mechanical Models; 8.1 Elastic Model; 8.2 Hyperelastic Model; 8.3 Viscoelastic Model; 9 Boundary Conditions; 10 Initial Conditions; 11 Summary; References; Chapter 3: Biomechanics of Incisional Surgery; 1 Introduction
327   $a2 Geometry from Corneal Topography3 Finite Element Analysis; 3.1 Generation of the Incision; 3.2 Generation of a Curvature Map; 4 Parametric Study of Radial Keratotomy; 4.1 Relation with the Incision Length; 4.2 Relation with the Optical Zone; 4.3 Relation with Incision Depth; 4.4 Effect of the Young´s Modulus; 4.5 Relation with the Poisson´s Ratio; 4.6 Relation with Intraocular Pressure; 5 Discussion; 6 An Exponential Hyperelastic Material Model for the Corneal Tissue; 7 Exponential Models for Biological Tissues; 7.1 Hyperelastic Nearly Incompressible Exponential Model for the Cornea
327   $a7.1.1 Fitting Inflation Tests Using an Inverse Method7.1.2 Fitting Normo-Hydrated Inflation Tests; 7.2 Simulation of Radial Keratotomy; Concluding Remarks; 8 Finite Linear Viscoelastic Model; 9 Constitutive Equations; 9.1 Multiplicative Decomposition of the Deformation Gradient; 9.2 Finite Linear Viscoelasticity; 9.3 Calibration with In Vivo Corneal Experiment; Conclusions; References; Chapter 4: Biomechanics of Subtractive Surgery: From ALK to LASIK; 1 Introduction; 1.1 Development of General Model for an Individual Lamella; 1.2 Corneal Model with Rotational Averaging of Lamella
327   $a2 Calibration Studies for the Corneal Model2.1 Introduction; 2.2 Calibration with ALK-H and Inflation Tests; 2.3 Normo-Hydrated Inflation Tests; 2.4 Simulation of RK and Comparison with Clinical Results; 3 Simulation of a Lamellar Surgery; 4 Finite Element Simulations of LASIK; 4.1 Comparison of Attempted and Simulated Correction; 4.2 Undercorrection in PRK and LASIK; 4.3 Undercorrection with the Optical Zone; 4.4 Undercorrection with the Preoperative Curvature; 4.5 Undercorrection with Ablation Depth and Optical Zone; Conclusions; References
327   $aChapter 5: Biomechanics of Additive Surgery: Intracorneal Rings
330   $aThis book presents a unique approach not found in any other text for those looking to improve the clinical results of refractive surgery by gaining a better understanding of corneal biomechanics and the instrumentation related to it. Written by leading experts in the field, this book provides authoritative coverage of the interactions of the cornea and the bioinstrumentation, such as corneal topography, pachymetry, aberrometers, tonometry and optical coherence tomography.  Organized in an easy-to-read manner, Corneal Biomechanics and Refractive Surgery is designed for refractive surgeons and general ophthalmologists alike and describes the biomechanical role of the corneal tissue and how each part is affected in refractive surgery. Additionally, showing what the bioinstrumentation can measure, how models can improve understanding of the interaction between biomechanics, bioinstrumentation, and refractive surgery, and how these models and bioinstrumentation together can improve the refractive results, are also discussed.
606   $aOphthalmology
606   $aBiomedical engineering
606   $aMedicine
606   $aOphthalmology$3https://scigraph.springernature.com/ontologies/product-market-codes/H44004
606   $aBiomedical Engineering and Bioengineering$3https://scigraph.springernature.com/ontologies/product-market-codes/T2700X
606   $aBiomedicine, general$3https://scigraph.springernature.com/ontologies/product-market-codes/B0000X
615  0$aOphthalmology.
615  0$aBiomedical engineering.
615  0$aMedicine.
615 14$aOphthalmology.
615 24$aBiomedical Engineering and Bioengineering.
615 24$aBiomedicine, general.
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