Abstract
This paper presents a computational modeling study of the effects of the collagen fiber structure on the mechanical response of the sclera and the adjacent optic nerve head (ONH). A specimen-specific inverse finite element method was developed to determine the material properties of two human sclera subjected to full-field inflation experiments. A distributed fiber model was applied to describe the anisotropic elastic behavior of the sclera. The model directly incorporated wide-angle X-ray scattering measurements of the anisotropic collagen structure. The converged solution of the inverse method was used in micromechanical studies of the mechanical anisotropy of the sclera at different scales. The effects of the scleral collagen fiber structure on the ONH deformation were evaluated by progressively filtering out local anisotropic features. It was found that the majority of the midposterior sclera could be described as isotropic without significantly affecting the mechanical response of the tissues of the ONH. In contrast, removing local anisotropic features in the peripapillary sclera produced significant changes in scleral canal expansion and lamina cribrosa deformation. Local variations in the collagen structure of the peripapillary sclera significantly influenced the mechanical response of the ONH.
This is a preview of subscription content, access via your institution.
References
Bellezza AJ, Hart RT, Burgoyne C (2000) The optic nerve head as a biomechanical structure: initial finite element modeling. Invest Ophthalmol Vis Sci 41:2991–3000
Burgoyne CF, Downs JC, Bellezza AJ, Francis Suh JK, Hart RT (2005) The optic nerve head as a biomechanical structure: a new paradigm for understanding the role of IOP-related stress and strain in the pathophysiology of glaucomatous optic nerve head damage. Prog Retin Eye Res 24(1):39–73
Coudrillier B, Tian J, Alexander S, Myers KM, Quigley HA, Nguyen TD (2012) Biomechanics of the human posterior sclera: age- and glaucoma-related changes measured using inflation testing. Invest Ophthalmol Vis Sci 53(4):1714–1728
Eilaghi A, Flanagan JG, Tertinegg I, Simmons CA, Brodland GW, Ethier CR (2010) Biaxial mechanical testing of human sclera. J Biomech 43(9):1696–1701
Ethier CR (2006) Scleral biomechanics and glaucoma, a connection?. Can J Ophthalmol 41(1):9–12, 14
Girard MJA, Suh JKF, Hart RT, Burgoyne CF, Downs JC (2007) Effects of storage time on the mechanical properties of rabbit peripapillary sclera after enucleation. Curr Eye Res 32(5):465–470
Girard MJA, Downs JC, Burgoyne CF, Suh JKF, (2009a) Peripapillary and posterior scleral mechanics—part i: development of an anisotropic hyperelastic constitutive model. J Biomech 131 (5):051011. doi:10.1115/1.3113682
Girard MJA, Suh JKF, Bottlang M, Burgoyne CF, Downs JC (2009b) Scleral biomechanics in the aging monkey eye. Invest Ophthalmol Vis Sci 50(11):5226–5237
Gokhale NH, Barbone PE, Oberai AA (2008) Solution of the nonlinear elasticity imaging inverse problem: the compressible case. Inverse Probl 24 (4):45010. doi:10.1088/0266-5611/2414/045010
Grytz R, Meschke G, Jonas JB (2011) The collagen fibril architecture in the lamina cribrosa and peripapillary sclera predicted by a computational remodeling approach. Biomech Model Mechanobiols 10(3):371–382
Hernandez MR, Luo XX, Igoe F, Neufeld AH (1987) Extracellular matrix of the human lamina cribrosa. Am J Ophthalmol 104(6):567–576
Jonas JB, Berenshtein E, Holbach L (2003) Anatomic relationship between lamina cribrosa, intraocular space, and cerebrospinal fluid space. Invest Ophthalmol Vis Sci 44(12):5189–5195
Jonas JB, Holbach L (2005) Central corneal thickness and thickness of the lamina cribrosa in human eyes. Invest Ophthalmol Vis Sci 46(4):1275–1279
Lari DR, Schultz DS, Wang AS, Lee O, Stewart JM (2011) Scleral mechanics: comparing whole globe inflation and uniaxial testing. Exp Eye Res 94(1):128–135
Morrison JC, Johnson EC, Cepurna W, Jia L (2005) Understanding mechanisms of pressure-induced optic nerve damage. Prog Retin Eye Res 24(2):217–240
Myers KM, Coudrillier B, Boyce B, Nguyen TD (2010) The inflation response of bovine sclera. Acta Biomater 6(11):4327–4335
Nguyen TD, Boyce BL (2011) An inverse finite element method for determining the anisotropic properties of the cornea. Biomech Model Mechanobiols 10(3): 323–337
Nguyen TD, Jones RE, Boyce BL (2008) A nonlinear anisotropic viscoelastic model for the tensile behavior of the corneal stroma. J Biomech Eng 130(4):041020.doi:10.1115/1.2947399
Norman RE, Flanagan JG, Sigal IA, Rausch SMK, Tertinegg I, Ethier CR (2011) Finite element modeling of the human sclera: influence on optic nerve head biomechanics and connections with glaucoma. Exp Eye Res 93(1):4–12
Pandolfi A, Holzapfel GA (2008) Three-dimensional modeling and computational analysis of the human cornea considering distributed collagen fibril orientations. J Biomech Eng 130:061006–1
Pijanka JK, Coudrillier B, Ziegler K, Sorensen T, Meek KM, Nguyen TD, Quigley HA, Boote C (2012) Quantitative mapping of collagen fiber orientation in non-glaucoma and glaucoma posterior human scleras. Invest Ophthalmol Vis Sci 53(9):5258–5270
Pinsky PM, Van Der Heide D, Chernyak D (2005) Computational modeling of mechanical anisotropy in the cornea and sclera. J Cataract Refract Surg 31(1):136–145
Quigley HA, Brown AE, Morrison JD, Drance SM (1990) The size and shape of the optic disc in normal human eyes. Arch Ophthalmol 108(1):51–57
Quigley HA, Brown AE, Dorman-Pease ME (1991) Alterations in elastin of the optic nerve head in human and experimental glaucoma. Br J Ophthalmol 75(9):552–557
Ren R, Wang N, Li B, Li L, Gao F, Xu X, Jonas JB (2009) Lamina cribrosa and peripapillary sclera histomorphometry in normal and advanced glaucomatous chinese eyes with various axial length. Invest Ophthalmol Vis Sci 50(5):2175–2184
Sigal IA, Flanagan JG, Ethier CR (2005) Factors influencing optic nerve head biomechanics. Invest Ophthalmol Vis Sci 11(46):4189–4199
Sigal IA, Flanagan JG, Tertinegg I, Ethier CR (2009) Modeling individual-specific human optic nerve head biomechanics. Part I: IOP-induced deformations and influence of geometry. Biomech Model Mechanobiol 8(2):85–98
Sigal IA, Yang H, Roberts MD, Burgoyne CF, Downs JC (2011) IOP-induced lamina cribrosa displacement and scleral canal expansion: An analysis of factor interactions using parameterized eye-specific models. Invest Ophthalmol Vis Sci 52(3):1896–1907
Studer H, Larrea X, Riedwyl H, Büchler P (2010) Biomechanical model of human cornea based on stromal microstructure. J Biomech 43(5):836–842
Vurgese S, Panda-Jonas S, Jonas JB (2012) Scleral thickness in human eyes. PLoS One 7(1):e29692. doi:10.1371/journal.pone.0029692
Watson PG, Young RD (2004) Scleral structure, organization and disease. A review. Exp Eye Res 78(3):609–623
Yan DB, Metheetrairut A, Trope GE, Ethier CR (1994) Deformation of the lamina cribrosa by elevated intraocular pressure. Brit J Ophthalmol 78(8):643–648
Acknowledgments
Baptiste Coudrillier and Thao D. Nguyen would like to thank Dr. Victor Barocas and Dr. Peter Pinsky for helpful discussions regarding this work. This work was supported in part by the Public Health Service Research Grants EY021500 (Thao D. Nguyen), EY02120 and EY01765 (Harry A. Quigley and Wilmer Institute), the Fight For Sight grant 1360 (Craig Boote), the Leonard Wagner Charitable Trust, William T. Forrester, and Saranne and Livingston Kosberg (Harry A. Quigley).
Author information
Authors and Affiliations
Corresponding author
Appendix: Effects of the midposterior sclera fiber structure on the mechanical response of the ONH for FC71r
Appendix: Effects of the midposterior sclera fiber structure on the mechanical response of the ONH for FC71r
The study of paragraph 3.4.1 was repeated for FC71r. Figure 23 shows the evolution of the area of the sclera described as isotropic with increasing values of anisotropic ratio threshold. Figure 24 plots the evolutions of the deformation of the ONH with increasing isotropic area.
A white square represents a WAXS measurement for which the anisotropic ratio is below the anisotropic ratio (AR) threshold indicated on top of the figure. An isotropic (constant) probability density function was used to describe the fiber structure of the white square regions instead of the normalized WAXS measurements. The portion of the sclera modeled as isotropic increased with increasing anisotropic ratio threshold
Evolution of the ONH deformation as the sclera became more isotropic (Fig. 23). The posterior deformation of the LC decreased with increasing isotropic area. The scleral canal expansion and maximum principal tensile and shear LC strains increased with increasing isotropic area. Increasing the threshold to \(\text{ AR}=1.4\) converted sclera specimen to an isotropic material. Yet, this caused changes to the deformation response of the ONH. The star corresponds to the fully isotropic model
Rights and permissions
About this article
Cite this article
Coudrillier, B., Boote, C., Quigley, H.A. et al. Scleral anisotropy and its effects on the mechanical response of the optic nerve head. Biomech Model Mechanobiol 12, 941–963 (2013). https://doi.org/10.1007/s10237-012-0455-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10237-012-0455-y