Combined data from SAXS/WAXS experiments at the ESRF and Diamond provide a better understanding of the structure of the human cornea, which in turn has the potential to improve the results of corneal surgery.
The cornea is the external lens of the eye, responsible for refracting incoming light onto the crystalline lens behind, which in turn focuses it on to the retina. It also plays a protective role, shielding the rest of the eye from dust and infection. To function, the cornea must be transparent to visible light, possess high mechanical strength, and have precisely defined curvature to focus.
90% of the thickness of the cornea is made of the stroma, a thick transparent layer primarily composed of collagen fibrils. The transparency stems from the small, uniform diameter and regular separation of these fibrils, whereas mechanical strength is related to their arrangement in the tissue. The shape of the cornea is almost spherical at the centre of the eye (near the visual axis), flattening out towards the white sclera. The shape of the cornea is thought to be strongly influenced by the arrangement of collagen fibrils in the stroma and surrounding tissues, and this knowledge is key to understanding how corneal disease and surgery can affect vision.
Professor Keith Meek, Dr Craig Boote, and a team from the Cardiff University have been using Diamond Light Sources’s I22 and the ESRF's ID13 beamlines to study the microstructure of the peripheral cornea and the limbus, where the cornea meets the sclera. This work has been published in the Biophysical Journal.
Results of the SAXS experiments which determined how collagen fibril diameter varies across the human cornea. Courtesy of K. Meek.
Human corneas without any history of corneal disease or surgery were obtained from the Bristol Eye Bank. Microfocus Wide Angle X-ray Scattering (WAXS) on ID13 was used to examine the preferred fibril orientation and the relative number of fibrils oriented in a particular direction. The SAXS experiments at Diamond used a conventional (rather than microfocus) beam, enabling greater sampling and reducing the signal to noise ratio, enabling the team to accurately measure fibril size. The results showed that the fibril diameter is constant in the central 6mm of the cornea but increases rapidly when moving out towards the periphery.
Prof Meek says, “Our study showed that the integration of collagen fibrils between the cornea and limbus is not circularly symmetrical, but varies noticeably depending on direction. This may be an important factor in understanding how the cornea responds to surgery involving peripheral incision – for example, cataract surgery. Astigmatism is a common complication following such surgery and our research will help to explain observations by clinicians that the extent of astigmatic changes depends on the location the cut is made.”
Manfred Burghammer, ID13 beamline scientist at the ESRF, says, “The investigations on cornea illustrate very well the efficient use of complementary techniques across beamlines at different synchrotron radiation sources. The combined application of scanning micro-diffraction and small angle scattering for biomedical applications is expected to be a rapidly growing field in the years to come.”
Reference: Craig Boote, Christina Kamma-Lorger, Sally Hayes, Jonathan Harris, Manfred Burghammer, Jennifer Hiller, Nicholas Terrill and Keith Meek:Quantification of Collagen Organization in the Peripheral Human Cornea at Micron-Scale Resolution, Biophysical Journal 101, July 2011. DOI: 10.1016/j.bpj.2011.05.029.
This news item is published jointly by Diamond Light Source and the ESRF.