Clinical Research Directory

High Resolution, High-speed Multimodal Ophthalmic Imaging

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.

OCT in Diagnosis of Irregular Corneas

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.

National Ophthalmic Genotyping and Phenotyping Network (eyeGENE (Registered Trademark)), Stage 3 - Expansion of DNA and Data Repositories for Rare Inherited Ophthalmic Diseases

Background: The eyeGENE (Registered Trademark) program is a research resource for inherited eye conditions which includes genotypic and phenotypic data, imaging, and a corresponding biobank of DNA samples from people with a variety of eye diseases. Since 2007 this registry has been helping researchers learn more about the genetic sources for many inherited eye diseases. These findings helped them create better treatments. Now researchers want to expand eyeGENE (Registered Trademark) to include more people for certain eye diseases. Objective: To collect information and DNA samples for the study of eye diseases. * Primary objective --To expand the current eyeGENE (Registered Trademark) data repository with targeted participant accrual * Secondary objectives * To enhance recruitment for clinical trials and investigations in inherited eye diseases * To establish genotype-phenotype correlations for rare eye diseases Eligibility: People of any age with certain eye diseases. These can include aniridia; Best disease; blue-cone monochromacy; corneal dystrophy; and disorders of pigmentation, such as albinism. Relatives unaffected by the eye disease of interest may also be needed. Design: Researchers will select participants based on their diagnosis. The data may include images and test results from eye exams. Participants will provide a sample of saliva. They will receive a kit with written instructions. They will spit in a tube and mail it to the NIH. Participants may be asked to provide a blood sample. The blood may be drawn at the NIH or at a local clinic. The eyeGENE (Registered Trademark) repository will offer researchers data about the participants eye conditions. The data may include pictures of their eyes, results of the genetic testing, and history of other diseases. Researchers will be able to see data such as age and gender, but they will not see names, dates of birth, or contact information.

Microsurgical Robot-assisted Corneal Transplant

Full-thickness corneal grafting (transfixing keratoplasty) is a tissue graft described at the beginning of the 20th century, which has remained technically unchanged for several decades. Around 900 transfixing keratoplasties are performed every year in France. This microsurgical procedure is intended for patients with severe corneal pathology that seriously impairs visual function, and for whom no therapeutic alternative - optical devices, medication or other surgical procedure - exists. The initial anatomical outcome of surgery depends on the accurate execution of the corneal sutures. Very recently, a robot with microsurgical capabilities was developed by the MMI company (Symani® surgical system, now available from the Reims University Hospital). This robot is equipped with forceps and a needle holder capable of handling fragile tissues and microsurgical needles with an amplitude of movement greater than that of the human hand. It is operated by a surgeon via a wireless controller and foot pedal. It could thus be used to perform the usual sutures of a transfixing keratoplasty. To our knowledge, no study to date has evaluated the contribution of a microsurgical robot to transfixing keratoplasty in humans. The Symani® microsurgical robot recently received CE marking for microsurgery. The investigators were able to carry out a series of ex vivo keratoplasties using the robot to suture non-conforming human corneas (destined for destruction), thus proving the feasibility of the procedure. On the basis of this proof of concept, our project aims to evaluate the performance of robot-assisted transfixing keratoplasty in patients requiring corneal transplantation. Robotic assistance for human eye surgery, particularly corneal transplants, has never been evaluated. The use of a robot to perform corneal sutures during transfixing keratoplasty could equal or even surpass the performance of this crucial surgical step, which is conventionally performed manually. Ultimately, visual results could be equivalent or even better than those obtained after conventional surgery. At the same time, the use of the robot will be evaluated in terms of surgical cost, in order to obtain a quantified financial evaluation of robot-assisted keratoplasty.

FECD-TRACE: Fuchs' Endothelial Corneal Dystrophy TRAjectory and Correlation With Genotype in the United Kingdom

FECD-TRACE is an integral component of a large research program dedicated to Fuchs Endothelial Corneal Dystrophy (FECD) in the United Kingdom. This longitudinal, observational study aims to comprehensively characterize a cohort of younger research participants who have a genetic predisposition to developing FECD. By utilizing advanced anterior segment imaging techniques, the study will monitor these individuals over a span of several years, capturing phenotypic changes that reflect the progression of the disease. Concurrently, genetic biomarkers will be examined to establish correlations with the observed phenotypic changes. The primary objective of FECD-TRACE is to enhance our understanding of the intricate genetic mechanisms underlying FECD and establish connections between these genetic findings and clinical outcomes. Ultimately, this research strives to facilitate the development of personalized care approaches for individuals affected by FECD.