Active clinical trials for "Eye Diseases"

Background: Achromatopsia is an inherited condition that causes vision loss because cells in the retina do not work properly. It causes loss of acuity, sensitivity to light, and loss of color vision. There are no effective treatments for achromatopsia. Four genes currently are known to cause achromatopsia. One of these, the cyclic nucleotide-gated channel beta 3 (CNGB3) gene, is the cause in about 50 percent of people. CNTF is a natural chemical found in the body that promotes survival and function of nerve cells. CNTF has been shown to be effective in treating retinal disease in animals and can slow vision loss. CNTF has also been studied in over 250 people with retinal disease other than achromatopsia. In these studies, a CNTF implant was placed into the eye during a simple surgery. The implant releases CNTF inside the eye, near the retina. These studies suggested that a CNTF implant might help vision in some eye diseases. Objectives: To learn whether a CNTF implant is safe for people with CNGB3 achromatopsia. To learn whether CNTF can improve visual acuity or color vision, and whether it may reduce sensitivity to light in people with CNGB3 achromatopsia. Eligibility: You may be able to take part in this study if you: Are at least 18 years old. Test positive for mutations in the CNGB3 gene and have no mutations in another achromatopsia gene. Have 20/100 vision or worse in at least one eye. Are not pregnant or nursing. Design: To determine if you can take part, we will ask about your medical history and do a physical examination and an eye examination. Blood and urine samples will be taken. This study requires 11 visits to the National Eye Institute over 3 years. One visit will be for the implant surgery. The implant will be placed in one eye only. Study visits will take place 1 day after implant surgery, and again 1 week later and 1 month, 3 months, 6 months, 1 year, 1.5 years and 3 years later. These visits will help us evaluate the safety and benefit of the implant on your eye. At the 3 year visit, you can choose to keep the CNTF implant in your eye, or you can have us remove it.

The primary purpose of this study is to determine the efficacy and safety of KPI-121 0.25% ophthalmic suspension compared to vehicle (placebo) in subjects who have a documented clinical diagnosis of dry eye disease. The product will be studied over 28 days, with 1-2 drops instilled in each eye four times daily (QID).

The purpose is to investigate tocilizumab administration in patients with moderately to severely or sight-threatening GO (Graves' ophthalmopathy) without response to treatment with corticoid intravenous pulses. Currently, these patients only have surgery as therapeutic alternative. The principal aim of this study is to evaluate efficacy and safety of tocilizumab treatment in order to provide a better alternative to surgery for this patients.

The purpose of the study is to evaluate the efficacy of SAR 1118 Ophthalmic Solution (5.0%) compared to placebo in the treatment of Dry Eye. The safety and tolerability of SAR 1118 Ophthalmic Solution (5.0%) compared to placebo in subjects with dry eye when administered BID for 12 weeks will also be evaluated.

This is a pilot study to determine the safety and efficacy of orbital injections of LIPO-102.

The purpose of this pilot study is to evaluate the effect of diquafosol tetrasodium Ophthalmic Solution, 2% in dry eye subjects.

Thyroid-associated ophthalmopathy (TAO) is an autoimmune process that can affect the orbital and periorbital tissues and the thyroid gland. Periorbital inflammation can cause swelling, fatty infiltration, and scarring of the eyelid muscles resulting in eyelid retraction and upper scleral exposure, which is the most common clinical features of TAO.Even with mild eyelid retraction and swelling, most patients become disappointed and depressed due to their cosmetically unacceptable appearance, and they are unwilling to wait for spontaneous resolution or a clinically inactive period for surgical intervention. Thus, most ophthalmologists and endocrinologists recommend surgery in the chronic burnt-out stage. Several treatment options have been described for correction of eyelid retraction, including Botox and filler injection, and surgeries in the burnt-out stage such as lowering the upper lid by recessing the levator muscle, excision of Müller's muscle, introducing a spacer, or myotomies.Surgical options have significant risks as well as an unpredictable course and outcome in some cases. Several authors have reported that subconjunctival botulinum toxin injection provides an immediate, effective treatment by reducing excessive levator function in patients who suffer from disfiguring eyelid appearance and do not want to wait for surgery for upper eyelid retraction.Botox treatment is usually temporary. However, unwanted ptosis, although temporary, was observed in five out of 24 patients (20.8%) in the study by Costa, which may be even more disappointing and cosmetically unacceptable to some patients.Recently, hyaluronic acid gel fillers, which were injected into the subconjunctival levator-Muller plane, demonstrated efficacy in managing Graves' eyelid retraction in three patients.However, complications such as a lumps, fluid buildup, and skin pigment darkening may occur using this technique.Steroid treatment represents a well-established TAO management strategy due to its anti-inflammatory and immunosuppressive actions. However, multiple systemic side effects such as diabetes, infection, hypertension, osteoporosis, and stomach ulcers are major drawbacks of systemic steroid treatment. Due to limitations of systemic steroid treatment, several studies reported TAO improvement with periorbital injections of methylprednisolone and triamcinolone, primarily focusing on reducing proptosis and diplopia. So far, however, only a single small case series study has suggested that an injection of 20 mg triamcinolone into the subconjunctival region of the lid, between the conjunctiva and Muller's muscle, improves upper eyelid retraction within 1 month in three of the four patients. The investigators are not aware of any study designed to demonstrate the treatment efficacy of locally administered triamcinolone to improve eyelid retraction and swelling in a prospective manner. Therefore, we aimed to evaluate both the short-term and long-term effects of subconjunctival triamcinolone injections in treating eyelid retraction and inflammatory swelling caused by TAO.

The purpose of this trial is to compare the effectiveness and safety of INS365 Ophthalmic Solution with Placebo when applied topically in subjects with dry eye disease.

This project will compare the efficacy and safety of 2 methods of disease modification in the treatment of active moderate and severe thyroid orbitopathy. A prospective, randomized, double-blind, parallel, controlled multidisciplinary clinical trial involving Singapore National Eye Centre, National University Hospital, Changi General Hospital, Tan Tock Seng Hospital and University of British Columbia Orbital Services, Singapore Eye Research Institute, Singapore General Hospital Endocrinology and Radiology Departments and Tan Tock Seng Hospital Rheumatology Department is planned. The SingHealth-SGH High Field MR Research Laboratory will be involved in the MR imaging of the trial patients. Patients who satisfy the inclusion and exclusion criteria will be asked to participate in this trial. After informed consent (Appendix B) is obtained, each patient will be randomized into one of two treatment arms: 1) Intravenous high-dose pulsed methylprednisolone (1 gram infusion over 1 hour per day with a total of 3 doses over 3 days; 4 cycles at 6 weekly intervals) and oral placebo and 2) Intravenous high-dose pulsed methylprednisolone (same dose) plus oral methotrexate 7.5 mg per week for 2 weeks, increased to 10 mg per week for another 2 weeks then 12.5 mg per week for 5 months (total 6 months of methotrexate treatment). Depending on patient response, the dose can be further increased by 2.5mg per week every 4 weeks to a maximum of 20 mg per week. A strict management protocol will be observed for each recruited patient. Patients who develop adverse side effects or need for surgical intervention will receive appropriate treatment (i.e. treatment will deviate from the protocol but will continue to be monitored). Patients who refuse treatment will be observed clinically and with imaging as a natural control group until such time as intervention is accepted. The patients will have a baseline assessment followed by regular visits to assess treatment response and adverse effects. Observations will include the use of an inflammatory index, motility measurements including quantitative ductions, exophthalmometry readings, palpebral aperture readings and indices of optic nerve function. With regards to the imaging, the patients will be assessed with an initial quantitative CT scan and 3-Tesla MRI scan prior to treatment. After treatment is started, patients will also undergo repeat MRI scan at 24 weeks and 72 weeks to assess quantitative changes with treatment using the Muscle Diameter Index (MDI) and Pixel Value Ratio (PVR) for the inferior rectus, superior rectus, the medial rectus, lateral rectus and orbital fat (Appendix E). Serum and urine will be obtained at the same time intervals as the MRI scan to assess levels of thyroid hormones, thyroid antibodies and urinary glycosaminoglycans (GAGs). Free T4, free T3 and TSH will be recorded to monitor control of hyperthyroidism. Thyroid antibodies measured will include thyroid stimulating immunoglobulin (TSI), thyrotropin-binding inhibition antibody (TB II), thyroid peroxidase antibodies and thyroglobulin antibody. Other tests including the full blood count, urea and electrolytes will be run prior to each dose of steroid treatment and during follow-up to monitor for adverse effects. The results of the assessments will be analyzed for significant differences in treatment response between the 2 groups. The indices of interest will include the percentage of patients in each group who demonstrate a decrease in the inflammatory index of at least 2 points and the time taken for 50% of patients to show such a decrease. Other parameters that reflect the visual function and motility will be compared at different points in time after starting treatment to observe response and sustainability of response. From the serial MRI scans, quantitative analysis of orbital tissues will be done to identify changes with treatment. Antibody and GAG levels will be analyzed to detect any change with treatment. The types and frequency of adverse side effects in the 2 groups will also be assessed. 80 normal subjects will be recruited for MRI scan of the orbits and brain to obtain normative values for the MDI and PVR for the Asian population (Appendix E). This will include 20 subjects from each of 4 decades (21-30 years, 31-40 years, 41-50 years, 51-60 years). The normative data will also be used to create a virtual orbital atlas. This aspect of the study will be performed in collaboration with the Labs for Information Technology (A-Star).

Oral supplementation with the Age-Related Eye Disease Study (AREDS) formulation (antioxidant vitamins C and E, beta carotene, and zinc) has been shown to reduce the risk of progression to advanced age-related macular degeneration (AMD). Observational data suggest that increased dietary intake of lutein + zeaxanthin (carotenoids), omega-3 long-chain polyunsaturated fatty acids (docosahexaenoic acid [DHA] + eicosapentaenoic acid [EPA]), or both might further reduce this risk. AREDS2 was designed to test whether adding lutein + zeaxanthin, DHA + EPA, or lutein + zeaxanthin and DHA + EPA to the AREDS formulation might further reduce the risk of progression to advanced AMD. A secondary goal was to test the effects of eliminating beta carotene and reducing zinc dose in the AREDS formulation.