The role of light in measuring ocular biomechanics

The role of light in measuring ocular biomechanics

The cornea is a highly specialised tissue with a unique set of biomechanical properties determined by its complex structure. The maintenance of these mechanical properties is fundamental to maintain clear vision as the cornea provides the majority of the focussing power of the eye. Changes to the bi...

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Bibliographic Details
Published in:Eye (London) Vol. 30; no. 2; pp. 234 - 240
Main Authors: Wilson, A, Marshall, J, Tyrer, J R
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-02-2016
Nature Publishing Group
Subjects:
692/699/3161/3163
692/700/139
Biomechanical Phenomena
Cambridge Ophthalmological Symposium
Cornea - physiology
Corneal Surgery, Laser
Elasticity - physiology
Humans
Interferometry
Laboratory Medicine
Light
Medicine
Medicine & Public Health
Ophthalmology
Pharmaceutical Sciences/Technology
Refraction, Ocular - physiology
Surgery
Surgical Oncology
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Summary:The cornea is a highly specialised tissue with a unique set of biomechanical properties determined by its complex structure. The maintenance of these mechanical properties is fundamental to maintain clear vision as the cornea provides the majority of the focussing power of the eye. Changes to the biomechanics of the cornea can occur during ageing, disease, and trauma, or as a result of surgery. Recently there has been increased interest in the mechanical properties of the cornea as knowledge of these properties has significant implications for the improvement of current ocular treatments including PRK and LASIK, and for the diagnosis and tracking of corneal diseases and therapy such as keratoconus and crosslinking. Biomechanics are also important for the development of artificial corneal replacements. This paper describes the use of a novel, non-destructive lateral electronic speckle pattern shearing interferometer (ESPSI). The data generated via this technique give a full-field view of the mechanical response of the cornea under simulated physiological loading conditions, and enables strain and displacement to be determined in three planes. The technique allows corneal stiffness to be quantified and enables changes and non-homogeneities that occur due to surgery or disease to be detected.
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ISSN:0950-222X
1476-5454
DOI:10.1038/eye.2015.263