PEER-REVIEWED PUBLICATION

2010

Biaxial Mechanical Testing of Human Sclera

Eilaghi A, Flanagan JG, et al.

Journal of Biomechanics

University of Toronto, University of Waterloo, Imperial College London

RESEARCH SUMMARY

This study quantified the biaxial mechanical properties of human sclera to better understand the biomechanical environment of the optic nerve head, a region implicated in glaucoma. Using planar biaxial testing, scleral samples from multiple ocular quadrants were subjected to physiologically relevant stresses and fit to a Fung-type constitutive model. Results demonstrated that human sclera exhibits nonlinear, near-isotropic mechanical behavior with substantial heterogeneity both within and between individuals. No significant dependence of stiffness on tissue thickness or sample location was observed. These findings provide critical material parameters for computational modeling of ocular biomechanics and glaucoma-related tissue loading.

Mechanical testing of human scleral tissue was performed using a CellScale BioTester 5000 biaxial testing system equipped with low-force load cells and BioRake attachments. The CellScale platform enabled precise equi-biaxial tensile loading of small scleral samples under fully hydrated, temperature-controlled conditions while synchronizing force measurements with optical strain tracking. This capability was essential for capturing nonlinear stress–strain behavior and directional stiffness in physiologically relevant loading states. Data generated using the CellScale system formed the basis for constitutive modeling of scleral mechanics and for assessing biomechanical variability relevant to optic nerve head function.

AUTHORS

Armin Eilaghi, John G. Flanagan, Inka Tertinegg, Craig A. Simmons, G. Wayne Brodland, C. Ross Ethier.

PUBLICATION DETAILS

JOURNAL

Journal of Biomechanics

YEAR

2010

INSTITUTIONS

University of Toronto, University of Waterloo, Imperial College London

COUNTRIES

Canada, United Kingdom

INSTRUMENT USED

BioTester

TESTING METHODS

Biaxial TestingHydrated and Temperature Controlled TestingMicro-Mechanical TestingTensile TestingViscoelastic & Time-Dependent Testing

RESEARCH APPLICATIONS

ECM & Decellularized Matrix MechanicsMechanotransductionOphthalmic Biomechanics & Corneal Tissue Engineering

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