Modelling the elastic properties of the anterior eye and their contribution to maintenance of image quality: the role of the limbus

Asejczyk-Widlicka, Magdalena; Sródka, D W; Kasprzak, Henryk T.; Pierscionek, Barbara K.

doi:10.1038/sj.eye.6702464

Cited by 39 publications

(21 citation statements)

References 23 publications

(17 reference statements)

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“…[102][103][104][105][106][107][108] These models are complex but can be understood generally by assuming that tissues behave as perfectly elastic bodies and incorporate experimentally obtained material properties, such as YM, to describe tissue function. As noted in the introduction, YM values of soft tissues can be obtained only if one assumes that the tissue behaves as an elastic body under small stress conditions.…”

Section: Discussionmentioning

confidence: 99%

Indentation Versus Tensile Measurements of Young's Modulus for Soft Biological Tissues

McKee

Russell

Murphy³

2011

Tissue Engineering Part B: Reviews

554

387

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Section: Discussionmentioning

confidence: 99%

Indentation Versus Tensile Measurements of Young's Modulus for Soft Biological Tissues

McKee

Russell

Murphy³

2011

Tissue Engineering Part B: Reviews

554

387

View full text Add to dashboard Cite

“…As the interferometric phase information represents the change of the optical path-length, the displacement from the corneal surface (cornea-air interface) affects the phase profiles measured at the underlying layers [59]. To correct these errors and obtain the true displacement profiles inside the cornea, we have developed algorithms of using the surface deformation to compensate the extra optical path-length change [50] [60] in our calculation. After getting the displacement profiles for all the transverse-depthwise positions of the cornea, a binarized two-dimensional depth-resolved OCT image is used as a mask to eliminate the spatial points with random optical phase information.…”

Section: Data Processingmentioning

confidence: 99%

Noncontact depth-resolved micro-scale optical coherence elastography of the cornea

Wang

Larin

2014

Biomed. Opt. Express

151

125

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High-resolution elastographic assessment of the cornea can greatly assist clinical diagnosis and treatment of various ocular diseases. Here, we report on the first noncontact depth-resolved micro-scale optical coherence elastography of the cornea achieved using shear wave imaging optical coherence tomography (SWI-OCT) combined with the spectral analysis of the corneal Lamb wave propagation. This imaging method relies on a focused air-puff device to load the cornea with highly-localized lowpressure short-duration air stream and applies phase-resolved OCT detection to capture the low-amplitude deformation with nano-scale sensitivity. The SWI-OCT system is used here to image the corneal Lamb wave propagation with the frame rate the same as the OCT A-line acquisition speed. Based on the spectral analysis of the corneal temporal deformation profiles, the phase velocity of the Lamb wave is obtained at different depths for the major frequency components, which shows the depthwise distribution of the corneal stiffness related to its structural features. Our pilot experiments on ex vivo rabbit eyes demonstrate the feasibility of this method in depth-resolved micro-scale elastography of the cornea. The assessment of the Lamb wave dispersion is also presented, suggesting the potential for the quantitative measurement of corneal viscoelasticity. 3026-3031 (2007). 3. L. T. Nordan, "Keratoconus: diagnosis and treatment," Int. Ophthalmol. Clin. 37(1), 51-63 (1997). 4. C. Edmund, "Corneal elasticity and ocular rigidity in normal and keratoconic eyes," Acta Ophthalmol. (Copenh.) 66(2), 134-140 (1988 Biol. 93(1-3), 176-191 (2007). 17. G. Scarcelli and S. H. Yun, "Confocal Brillouin microscopy for three-dimensional mechanical imaging," Nat. ©2014 Optical Society of AmericaPhotonics 2(1), 39-43 (2008). 18. J. Schmitt, "OCT elastography: imaging microscopic deformation and strain of tissue," Opt. Express 3(6), 199-211 (1998). 19. G. Scarcelli and S. H. Yun, "In vivo Brillouin optical microscopy of the human eye," Opt. Express 20(8), 9197-9202 (2012). 20. G. Scarcelli, R. Pineda, and S. H. Yun, "Brillouin optical microscopy for corneal biomechanics," Invest.Ophthalmol. Vis. Sci. 53(1), 185-190 (2012). 21. G. Scarcelli, S. Kling, E. Quijano, R. Pineda, S. Marcos, and S. H. Yun, "Brillouin microscopy of collagen crosslinking: noncontact depth-dependent analysis of corneal elastic modulus," Invest. Ophthalmol. Vis. Sci.

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“…We have determined ratio m in our preliminary studies to be in the range between 4.6 and 6. This ratio has its significance even in a linear model of the eyeball 49 and has its confirmation in experimental studies. 9 We have numerically validated this proposed nonlinear model by comparing its stiffness to that of a real eye.…”

Section: Methodsmentioning

confidence: 82%

Optically inspired biomechanical model of the human eyeball

Śródka

Iskander

2008

J. Biomed. Opt.

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Currently available biomechanical models of the human eyeball focus mainly on the geometries and material properties of its components while little attention has been given to its optics--the eye's primary function. We postulate that in the evolution process, the mechanical structure of the eyeball has been influenced by its optical functions. We develop a numerical finite element analysis-based model in which the eyeball geometry and its material properties are linked to the optical functions of the eye. This is achieved by controlling in the model all essential optical functions while still choosing material properties from a range of clinically available data. In particular, it is assumed that in a certain range of intraocular pressures, the eye is able to maintain focus. This so-called property of optical self-adjustments provides a more constrained set of numerical solutions in which the number of free model parameters significantly decreases, leading to models that are more robust. Further, we investigate two specific cases of a model that satisfies optical self-adjustment: (1) a full model in which the cornea is flexibly attached to sclera at the limbus, and (2) a fixed cornea model in which the cornea is not allowed to move at the limbus. We conclude that for a biomechanical model of the eyeball to mimic the optical function of a real eye, it is crucial that the cornea is allowed to move at the limbal junction, that the materials used for the cornea and sclera are strongly nonlinear, and that their moduli of elasticity remain in a very close relationship.

show abstract

Modelling the elastic properties of the anterior eye and their contribution to maintenance of image quality: the role of the limbus

Cited by 39 publications

References 23 publications

Indentation Versus Tensile Measurements of Young's Modulus for Soft Biological Tissues

Indentation Versus Tensile Measurements of Young's Modulus for Soft Biological Tissues

Noncontact depth-resolved micro-scale optical coherence elastography of the cornea

Optically inspired biomechanical model of the human eyeball

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