The importance of parameter choice in modelling dynamics of the eye lens

Wang, Kehao; Venetsanos, Demetrios T.; Wang, Jian; Augousti, A.T.; Pierscionek, Barbara K.

doi:10.1038/s41598-017-16854-9

Cited by 20 publications

(36 citation statements)

References 65 publications

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“…Gross lens shape change caused by strain results microstructural level changes in all the regions of the lens that we examined. This provides critical information that will be useful in expanding current biomechanical models of lens shape changes (Reilly and Ravi, 2010;Reilly, 2014;Wang et al, 2017). Furthermore, the identification of a relationship between microstructure and tissue biomechanics supports the idea that age-dependent microstructural alterations, such as an increase in stiffness of cells or matrix (Starodubtseva, 2011;Lacolley et al, 2017), could have biomechanical consequences at the tissue level.…”

Section: Discussionsupporting

confidence: 53%

The effects of mechanical strain on mouse eye lens capsule and cellular microstructure

Parreno

Cheng

Nowak

et al. 2018

Preprint

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The understanding of multiscale load transfer within complex soft tissues is incomplete. The eye lens is ideal for multiscale tissue mechanics studies as its principal function is to fine focus light at different distances onto the retina via mechanical shape changes. The biomechanical function, resiliency, and intricate microstructure of the lens make it an excellent non-connective soft tissue model. We hypothesized that compressive strain applied onto whole lens tissue leads to deformation of specific microstructures and that this deformation is reversible following removal of load. For this examination, mouse lenses were compressed by sequential application of increasing load. Using confocal microscopy and quantitative image analysis, we determined that axial strain ≥10% reduces capsule thickness, expands epithelial cell area, and separates fiber cell tips at the anterior region of the lenses. At the equatorial region, strain ≥6% increases fiber cell widths. The effects of strain on lens epithelial cell area, capsule thickness, and equatorial fiber cell widths are reversible following the release of lenses from strain. However, although fiber cell tip separation following the removal of low loads is reversible, the separation becomes irreversible with application of higher loads. This irreversible separation between fiber cell tips leads to incomplete bulk lens resiliency. The lens is an accessible biomechanical model system that provides new insights on multiscale transfer of loads in soft tissues.

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Section: Discussionsupporting

confidence: 53%

The effects of mechanical strain on mouse eye lens capsule and cellular microstructure

Parreno

Cheng

Nowak

et al. 2018

Preprint

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“…Young's modulus E or shear modulus G. This log-log linear equation [25] is described as: log( ) = log( ) + (3) where a and b are material dependent coefficients that were determined for porcine lenses: a=0.093 and b=9.29 [25] which have similar elastic shear moduli to young human lenses [29], [reviewed in 30]. Taking the eye lens as nearly incompressible [31], [32] Young's and shear modulus can be linearly related: E=3G [10], [30]. The calculated Young's moduli E at the central plateau and at the lens poles are 0.82 kPa and 0.04 kPa respectively.…”

Section: Materials Properties and Opto-mechanical Couplingmentioning

confidence: 99%

“…Yet a number of modelling approaches simplify these forces as emanating from a single point [5], [6], [7], [8], [9]. Recently it was shown that separating directions of zonular force across the three sections makes a substantial difference to the shape change and renders the modelled simulation closer to the changes in shape seen in the biological lens [10]. This is fundamental for understanding the mechanical behaviour of the different zonular sections and for providing insights needed to understand the accommodative process and its loss with age.…”

mentioning

confidence: 99%

“…Such insights may resolve the conflicts between major accommodative theories [11], [12], [13], [14]. Recent modelling [10] and experimental studies on monkey lenses [15] suggest that the equatorial zonular section is less effective when compared to the anterior and posterior zonular sections in altering central curvatures and optical power of the lens during accommodation. This has been previously postulated [12], [16].…”

mentioning

confidence: 99%

“…Finite Element lens models were created based on human lenses from five different ages, covering the age range from the second to the sixth decade of life. A parametric analysis of 990 different combinations of zonular angles and hence directions of force on the lens, was conducted for each model using an exhaustive search scheme developed in a previous study [10]. The resultant changes in lens thickness and stress field distributions were analysed to investigate the optomechanical relationship and how this may alter with age.…”

mentioning

confidence: 99%

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A Modeling Approach for Investigating Opto-Mechanical Relationships in the Human Eye Lens

Wang

Venetsanos

Hoshino

et al. 2020

IEEE Trans. Biomed. Eng.

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Objective: The human visual system alters its focus by a shape change of the eye lens. The extent to which the lens can adjust ocular refractive power is dependent to a significant extent on its material properties. Yet, this fundamental link between the optics and mechanics of the lens has been relatively under investigated. This study aims to investigate this opto-mechanical link within the eye lens to gain insight into the processes of shape alteration and their respective decline with age. Methods: Finite Element models based on biological lenses were developed for five ages: 16, 35, 40, 57 and 62 years by correlating in vivo measurements of the longitudinal modulus using Brillouin scattering with in vitro X-ray interferometric measurements of refractive index and taking into account various directions of zonular force. Results: A model with radial cortical Young's moduli provides the same amount of refractive power with less change in thickness than a model with uniform cortical Young's modulus with a uniform stress distribution and no discontinuities along the cortico-nuclear boundary. The direction of zonular angles can significantly influence curvature change regardless of the modulus distribution. Conclusions: The present paper proposes a modelling approach for the human lens, coupling optical and mechanical properties, which shows the effect of parameter choice on model response. Significance: This advanced modelling approach, considering the important interplay between optical and mechanical properties, has potential for use in design of accommodating implant lenses and for investigating nonbiological causes of pathological processes in the lens (e.g. cataract).

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Some Considerations on the Composite Structure of the Human Eye

Lazăr

Baritz

2020

Macromolecular Symposia

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The construction of the human eyeball has characteristics of the composite structure considering the optically transparent media (cornea, crystalline) that participate in the formation of images on the surface of the retina. Both the cornea and the crystalline are formed by thin cellular layers that behave like structures composed of elastic curved plates. The first part of the article presents the theoretical aspects that are the basis of the biomechanical approach of this ensemble. In the second part, the aspects of the modeling of the optical behavior of the eyeball and elasticity of the lens are presented. The final part of the article presents the conclusions regarding the behavior of the composite structure of the ocular globe from a biomechanical and optical point of view.

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The importance of parameter choice in modelling dynamics of the eye lens

Cited by 20 publications

References 65 publications

The effects of mechanical strain on mouse eye lens capsule and cellular microstructure

The effects of mechanical strain on mouse eye lens capsule and cellular microstructure

A Modeling Approach for Investigating Opto-Mechanical Relationships in the Human Eye Lens

Some Considerations on the Composite Structure of the Human Eye

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