View clinical trials related to Corneal Dystrophy.
Filter by:Knowledge of the pathogenesis of ocular conditions, a leading cause of blindness, has benefited greatly from recent advances in ophthalmic imaging. However, current clinical imaging systems are limited in resolution, speed, or access to certain structures of the eye. The use of a high-resolution imaging system improves the resolution of ophthalmoscopes by several orders of magnitude, allowing the visualization of many microstructures of the eye: photoreceptors, vessels, nerve bundles in the retina, cells and nerves in the cornea. The use of a high-speed acquisition imaging system makes it possible to detect functional measurements such as the speed of blood flow. The combination of data from multiple imaging systems to obtain multimodal information is of great importance for improving the understanding of structural changes in the eye during a disease. The purpose of this project is to observe structures that are not detectable with routinely used systems.
This main goal of this study is to improve the detection, classification, monitoring, and treatment of irregular corneas due to keratoconus, warpage, dry eye, scar, stromal dystrophies, and other corneal conditions. The primary goal will be achieved by using optical coherence tomography (OCT) to: 1. Develop an OCT-based system to classify and evaluate corneal-shape irregularities. 2. Develop OCT metrics for more sensitive detection of keratoconus progression. 3. Develop OCT-and-topography guided phototherapeutic keratectomy (PTK) for irregular corneas.
Corneal dystrophies are usually classified histopathologically according to the layer of the cornea that is affected. The International Committee for the Classification of Corneal Dystrophies (IC3D) takes this anatomical classification as referral with summarizing clinical, genetic, and pathological data. Most of this classification relies on slit lamp findings or histologic specimen, since in-vivo imaging of corneal microstructures has only become available in the recent years. With confocal microscopy it is possible to image corneal microstructures at a high resolution, but this technique is limited by its reduced repeatability and the fact that only a small area can be imaged. By the use of optical coherence tomography (OCT) systems it is possible to overcome these limitations. Commercially available systems, however, only have an axial resolution of about 18 µm which is not sufficient for imaging of all corneal layers. Recently, a high-resolution optical coherence tomography (OCT) system was developed at the Center for Medical Physics and Biomedical Engineering that enables a resolution of about 1 µm. With this resolution, all corneal structures and several pathologies can be visualized. In the present study the investigators want to use this OCT system to image corneal dystrophies in patients scheduled for corneal transplantation.
The purpose of this study is to compare corneal endothelium morphology and central thickness in type II Diabetes Mellitus and normal subjects with special reference to glycemic status.