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Laboratory of
Ocular Biomechanics

University of Pittsburgh

Latest News

Cover of Investigative Ophthalmology & Visual Science

  • "Collagen Architecture of the Posterior Pole:
    High-Resolution Wide Field of View Visualization and Analysis Using Polarized Light Microscopy"

  • Read the article here.

New paper accepted

  • "Mapping in-vivo optic nerve head strains caused by intraocular and intracranial pressure"
    by SPIE Proceedings.

Two podium presentations (one invited)

  • SPIE Photonics West, San Francisco, California, Jan 28 - Feb 2, 2017.

Oxyopia lecture (invited)

  • University of California at Berkeley, California, Jan 27, 2017.

New paper accepted

  • "Collagen architecture of the posterior pole; high-resolution, wide-field-of-view visualization and analysis using polarized light microscopy"
    by Investigative Ophthalmology and Visual Science.

New paper accepted

  • "Development of computational tools for analyzing 3D in vivo deformations of monkey optic nerve head"
    by Ingenium.

  • Read the paper here.

Active projects
Click images for more info.

Why biomechanics of the eye?

In our daily lives we rarely think of the eye as a biomechanical structure. The eye, however, is a remarkably complex structure with biomechanics involved in many of its functions. For our eyes to be able to track moving objects, for example, requires a delicate balance of the forces exerted by several muscles. Forces are also responsible for deforming the lens and allow focusing. A slight imbalance between the forces and tissue properties may be enough to alter or even preclude vision. These effects may take place quickly or over long periods, even years. Understanding ocular biomechanics is therefore important for preventing and treating vision loss.


Eye diagram

Schematic cross-section through a human eye. Light enters the eye through the cornea, passes through the pupil, lens and vitreous humour and strikes the retina, where it is absorbed. Retinal nerve fibers transmit visual information to the brain. These fibers converge at the optic nerve head region, exit the eye through the scleral canal, and form the optic nerve. The lamina cribrosa is a porous structure spanning the scleral canal. The vitreous chamber is filled with the vitreous humor, which exerts a pressure, the intraocular pressure, on the surface of the retina. [Sigal et al. Biomech Model Mechanobiol, 8(2):85-98, Apr 2009] (adapted from an illustration from NIH)



The objective of the Laboratory of Ocular Biomechanics is to study the eye as a biomechanical structure. More specifically our work is aimed at identifying the causes of glaucoma, with the ultimate intention of finding a way to prevent vision loss.