View clinical trials related to Macular Degeneration.
Filter by:This study is designed to compare the effect of combined intravitreal Bevacizumab and Propranolol injection versus Bevacizumab monotherapy in patients with Age Related Macular Degeneration. Methods: In this study patients with Age Related Macular Degeneration who are naïve or had history of previous treatment are included. The eligible patients in randomized in two groups "Bevacizumab" and "Bavacizumab + propranolol" and in injected intravitreally for 3 times monthly. In "Bevacizumab+propranolol" group patients receive two injections at each session Bavacizumab and propranolol. In "Bevacizumab" group patients receive only Bevacizumab. The patients are followed for 6 months and central macular thickness and visual acuity is measured at baseline and monthly for 6 month. Baseline ancillary exams include Fluorescein Angiography and OCT-Angiography which is performed at the final exam as well. Patients needing any therapeutic intervention is addressed during the 6 month follow up period.
This study will evaluate the safety and efficacy of intense dosing for a limited period in patients who demonstrate refractory disease on monthly IAI. Patients will be followed for 52 weeks
Age-related macular degeneration (AMD) is the leading cause of blindness after 50 years in industrialized countries, compromising daily activities and reducing quality of life. And whose treatment is one of the first health expenditures. Since September 2015, Bevacizumab, which does not have marketing authorization in AMD, has been given a temporary recommendation for use. Studies in other countries have shown that bevacizumab is cost-effective in the treatment of AMD compared to other anti-VEGF therapies used.
The purpose of this prospective interventional study is to compare patient experience, ocular surface irritation, and bacterial colony counts and microbial spectrum between povidine iodine and aqueous chlorhexidine as ocular surface antiseptic prior to intravitreal injection
Because of a shared ontogenic origin, the retina displays similarities to the brain and spinal cord in terms of anatomy, functionality, response to insult, and immunology. Hence, the retina can be approached as an integral part of the central nervous system. The occurence of ocular manifestations in several neurodegenerative pathologies, such as Alzheimer's disease and Parkinson's disease, accentuates the strong relationship between eye and brain. Particularly retinal changes can present a substrate for cerebral changes in these disorders. Offering a 'window to the brain', the transparent eye enables non-invasive imaging of these changes in retinal structure and vasculature. In this project, the potential of retinal biomarkers for e.g. Alzheimer's will be explored with the aim to overcome some of the hurdles in the current management of these pathologies, mainly the lack of techniques for patient screening and early diagnosis. The aim of this clinical trial is to correlate the retinal biomarkers for Alzheimer's with neuro-imaging, and cognitive function. Integrating the results will yield non-invasive retinal biomarkers for clinical research, screening, and follow-up of disease progression in various neurodegenerative disorders.
To evaluate the correlation between macular pigment optical density (MPOD) levels and risk of progression in patients with age-related macular degeneration
Background: Macular degeneration can cause permanent loss of central vision. This vision is important for seeing details. Age-related macular degeneration (AMD) is the leading cause of vision loss in people over 55 in the United States. Researchers want to follow people with AMD to study the early to middle stages of the disease. Objective: To follow for another 5 years participants who completed NIH study 11-EI-0147. Eligibility: Participant was enrolled in and completed study 11-EI-0147. Design: Participants will have at least 6 study visits over 5 years. Each visit takes about 5 hours. At visit 1, participants will be asked about their medical and eye disease history. They will have an eye exam. The exam will test vision, eye pressure, and eye movements. The pupil will be dilated with eye drops. Participants will have baseline exams. These include a health history and questions about problems that affect their eyes under different lighting. They will answer these questions each year. At each visit, participants will have some or all of these tests: Eye exam Dark adaptation protocol. This measures how fast the eyes recover when exposed to decreasing levels of light. The pupil will be dilated with eye drops. Participants will sit in front of a metal box with a camera inside. They will push a button when they see a light in the machine. View a bright background light for 5 minutes. After the light is turned off participants will push a button when a blue or red light is seen. Sit in the dark for about 30 minutes. Participants will push a button when they see a blue or red light.
This study is an open-label investigation of the safety and preliminary efficacy of the subretinal transplantation of human retinal pigment epithelial cells on Macular Degeneration.
This pathology, DMLA, whose evolution is chronic, requires regular follow-up and care (IVTs) over a long period (several months or even years). Increasing the number of patients to be followed and treated poses increasing problems for ophthalmologists to ensure regular follow-up of patients, followed by a need for satisfactory functional results. Moreover, this regular follow-up imposes enormous constraints on patients and their families (some children or patients are still working). Studies are beginning to emerge on the reliability of patient follow-up in telemedicine. The use of a measure of visual acuity by patients, Electronic Tablet (TE) or computer (O), and at home, seems a logical step to help us improve the quality of patient follow-up while spacing controls. The aim of our study is thus to demonstrate that the measurement of the VA performed by TE or O is reliable. Indeed, during the follow-up of the patients, in the case where the patient's AV decreases, and whatever the reason
Age-related macular degeneration (AMD) is an eye disease which causes people to lose their sharp central vision over time. Aging damages the macula, which is in the middle of the retina - the light-sensitive part at the back of the eye. There are 2 types of AMD - wet AMD and dry AMD. The advanced stage of dry AMD causes vision loss. This is known as geographic atrophy. AMD makes everyday tasks like reading or driving difficult. ASP7317 is a potential new treatment for people with AMD. ASP7317 are human stem cells which have changed into cells found in the retina. ASP7317 is injected under the macula. It is hoped that ASP7317 will replace some of the damaged cells in the macula and improve vision for people with dry AMD. Before ASP7317 is available as a treatment, the researchers need to check its safety and how well it is tolerated. They will also check for signs of improved vision. People taking part in this study will be older people who have geographic atrophy caused by dry AMD. This is an open-label study. This means that people in this study and clinic staff will know that people will receive ASP7317. There will be 3 doses of ASP7317. These are low, medium and high numbers of cells. ASP7317 will be injected under the macula after the person is given either a local or a general anesthetic. To prevent the body from rejecting the cells, people will take tablets of tacrolimus a few days before receiving ASP7317 for up to a few weeks afterwards. Other medicines will be taken during this time to stop infections. There will be 2 groups in the study. Group 1 will be people with severe vision loss and Group 2 will be people with moderate vision loss. There will be different small groups of people within Group 1 and Group 2, with each small group receiving 1 of the 3 doses of ASP7317. Different small groups of people within Group 1 and Group 2 will receive lower to higher doses of ASP7317. Each small group will only receive 1 dose. Group 1 will start treatment first. At each dose, a medical expert panel will check the results of the first person in the group to decide if the rest of the group will receive the same dose. Then, the panel will decide if more people may receive the same dose or if the next group may receive the next highest dose. The panel will use the results from the lower dose of Group 1 to decide when Group 2 starts treatment (also at the lower dose). The panel will also use the results of the middle and higher doses in Group 1 to decide when and how many people in Group 2 can receive these doses. During the study, people will visit the clinic several times for up to 12 months (1 year). During all visits, the study doctors will check for any medical problems after receiving ASP7317. Vital signs will be checked a few days before treatment with ASP7317 and up to about a month afterwards. Vital signs include blood pressure, pulse, and temperature. At some visits, the study doctors will also take blood samples for blood tests. At most visits, people will have eye tests and have different images, scans, and measurements taken. This could be for the affected eye or both eyes, depending on the test. People can visit the clinic extra times, if needed.