Andrés de la Hoz scite author profile

Andrés de la Hoz

3Publications

27Citation Statements Received

81Citation Statements Given

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155

Affiliations

Institute of Optics, Spanish National Research Council, Unidades Centrales Científico-Técnicas

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Material Properties from Air Puff Corneal Deformation by Numerical Simulations on Model Corneas

et al. 2016

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ObjectiveTo validate a new method for reconstructing corneal biomechanical properties from air puff corneal deformation images using hydrogel polymer model corneas and porcine corneas.MethodsAir puff deformation imaging was performed on model eyes with artificial corneas made out of three different hydrogel materials with three different thicknesses and on porcine eyes, at constant intraocular pressure of 15 mmHg. The cornea air puff deformation was modeled using finite elements, and hyperelastic material parameters were determined through inverse modeling, minimizing the difference between the simulated and the measured central deformation amplitude and central-peripheral deformation ratio parameters. Uniaxial tensile tests were performed on the model cornea materials as well as on corneal strips, and the results were compared to stress-strain simulations assuming the reconstructed material parameters.ResultsThe measured and simulated spatial and temporal profiles of the air puff deformation tests were in good agreement (< 7% average discrepancy). The simulated stress-strain curves of the studied hydrogel corneal materials fitted well the experimental stress-strain curves from uniaxial extensiometry, particularly in the 0–0.4 range. Equivalent Young´s moduli of the reconstructed material properties from air-puff were 0.31, 0.58 and 0.48 MPa for the three polymer materials respectively which differed < 1% from those obtained from extensiometry. The simulations of the same material but different thickness resulted in similar reconstructed material properties. The air-puff reconstructed average equivalent Young´s modulus of the porcine corneas was 1.3 MPa, within 18% of that obtained from extensiometry.ConclusionsAir puff corneal deformation imaging with inverse finite element modeling can retrieve material properties of model hydrogel polymer corneas and real corneas, which are in good correspondence with those obtained from uniaxial extensiometry, suggesting that this is a promising technique to retrieve quantitative corneal biomechanical properties.

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Design and ex situ performance of a shape-changing accommodating intraocular lens

Hoz

Germann

Martinez-Enriquez

et al. 2019

Optica

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Presbyopia, the age-related loss of the crystalline lens's ability to dynamically focus, occurs primarily because of stiffening of lens material, making the ciliary muscle forces insufficient to reshape the lens. Despite its prevalence, there is no satisfactory solution to presbyopia. Here we present a novel accommodating intraocular lens (AIOL) able to reshape upon equatorial forces in compliance with the eye's accommodating mechanism. The concept and design parameters are demonstrated through finite element model simulations and measurements in a manufactured AIOL prototype, using custom quantitative 3D OCT (geometrical changes) and laser ray tracing (power changes), with forces radially applied using a custom eight-arm mechanical stretcher. There was an excellent agreement between simulations and measurements (1% for the focal length and 11.4% for geometrical parameters, on average) for radial load up to 0.6 N. The developed design is expected to achieve ∼2.5D of effective power change with a polymer material with 0.10-0.25 MPa Young's modulus and n 1.43 − 1.46.

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Estimation of scleral mechanical properties from air-puff optical coherence tomography

Ciriza

Birkenfeld

Hoz

et al. 2021

Biomed. Opt. Express

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We introduce a method to estimate the biomechanical properties of the porcine sclera in intact eye globes ex vivo, using optical coherence tomography that is coupled with an air-puff excitation source, and inverse optimization techniques based on finite element modeling. Air-puff induced tissue deformation was determined at seven different locations on the ocular globe, and the maximum apex deformation, the deformation velocity, and the arc-length during deformation were quantified. In the sclera, the experimental maximum deformation amplitude and the corresponding arc length were dependent on the location of air-puff excitation. The normalized temporal deformation profile of the sclera was distinct from that in the cornea, but similar in all tested scleral locations, suggesting that this profile is independent of variations in scleral thickness. Inverse optimization techniques showed that the estimated scleral elastic modulus ranged from 1.84 ± 0.30 MPa (equatorial inferior) to 6.04 ± 2.11 MPa (equatorial temporal). The use of scleral air-puff imaging holds promise for non-invasively investigating the structural changes in the sclera associated with myopia and glaucoma, and for monitoring potential modulation of scleral stiffness in disease or treatment.

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Andrés de la Hoz

Material Properties from Air Puff Corneal Deformation by Numerical Simulations on Model Corneas

Design and ex situ performance of a shape-changing accommodating intraocular lens

Estimation of scleral mechanical properties from air-puff optical coherence tomography

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