View clinical trials related to Glaucoma.
Filter by:The Boston keratoprosthesis (KPro) is a special plastic device that is used to replace a sick cornea (transparent part of the eye, in front of the iris) in order to restore vision in patients who have failed traditional corneal transplants or have a very poor prognosis of success. Glaucoma is a chronic disease which causes optic nerve damage secondary to high pressure inside the eye and could lead to vision loss in the long term. Glaucoma is highly prevalent in patients who require a KPro and even more after their procedure. In order to decrease the intra-ocular pressure, surgeons can use multiple eyedrops. Unfortunately, following the KPro surgery, eyedrops lose their efficiency because they are less absorbed by the eye. The transscleral cyclophotocoagulation (TS-CPC) is a laser treatment used in advanced refractory glaucoma. This laser helps decrease the intra-ocular pressure and have a better control of the disease. There are different methods of laser transmission, including the continuous transmission (G-Probe) and the micro-pulsation method (Micopulse). Given the high prevalence of glaucoma in patients receiving a KPro, the investigators are studying the effect of giving the TS-CPC treatment prophylactically to patients before their Boston keratoprosthesis. Our hypothesis is that prophylactic TS-CPC will decrease glaucoma progression as well as the risks of developing glaucoma following the Boston keratoprosthesis . METHOD The investigators aim to recruit twenty (20) patients who are scheduled to receive Boston KPro. Participants will be randomized into two groups: 1) Groupe 1 will receive a prophylactic treatment of transscleral cyclophotocoagulation a G-Probe. 2) Groupe 2 will receive a prophylactic treatment of transscleral cyclophotocoagulation with a micropulse transmission (MicroPulse). The patients will receive their laser treatment by a glaucoma specialist 4 to 8 weeks before their KPro surgery. One week following their laser treatment, the participants will be examined by their glaucoma specialist. Following their KPro surgery, patients will have a follow-up at day-1, weeks 1 and 2, months 1 and 3, then every 4 to 6 months for 5 years. Additional non-invasive glaucoma tests will be performed twice during the first 3 months following the surgery and will be repeated every 4-6 months. Visual acuity results, the visual field tests and rates of post-operative complications will be compared between the different groups.
In this retrospective observational study, we collected intraocular structure parameters of malignant glaucoma and primary angle closure glaucoma. Anterior chamber depth (ACD) and width (ACW), lens vault (LV), ciliary process-ciliary process distance(CCD), trabecular-ciliary processes distance (TCPD), ciliary body max thickness (CBMT), peripheral iris thickness (PIT), trabecular ciliary process angle (TCPA), and anterior vault (AV), were measured by ultrasound biomicroscopy. Other parameters measured by A-scan ultrasonography and optical coherence tomography. To analyze the high risk factors and the possible pathogenesis of the disease and discuss the long-term effect of different treatment methods.
Topical Prostaglandin Analog vs Betablocker - Corneal Biomechanical Evaluation using CATS Tonometer Prism
In patients with Glaucoma, Xalost S or Xalatan or Taflotan-S are administered for 12 weeks. After 12 weeks, among them, Xalatan administration group are switched to Xalost S or Taflotan-S. Extension study period is 8 weeks. To compare effect (ocular surface damage) and safety of preservative-free Latanoprost/Tafluprost to Benzalkonium chloride-preserved Latanoprost in primary open angle glaucoma or normal tension glaucoma.
Cystoid macular edema (CME) can limit visual acuity after cataract surgery. Little is known whether the incidence is similar between standard ultrasound phacoemulsification cataract surgery (phaco), femtolaser assisted cataract surgery (FLACS), and combined phacoemulsification cataract surgery plus micro invasive glaucoma surgery (phaco+MIGS) procedures.
The purpose of this study is to determine whether Metformin could prevent the progression of glaucoma in a safe and effective manner.
Pediatric patients who have undergone surgery for congenital or infantile cataracts have a risk of developing suspected glaucoma and glaucoma, but the current evidence does not address our understanding of the incidence and associated risk factors of suspected glaucoma/glaucoma for application in clinical standard care. Therefore, this study investigated the incidence of and risk factors for suspected glaucoma/glaucoma in patients who have undergone surgery for congenital/infantile cataracts.
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.
Glaucoma, a leading cause of irreversible blindness worldwide, is characterized by a permanent loss of retinal ganglion cells (RGCs), a group of central nervous system (CNS) neurons that convey visual information from the retina to the brain via their long axons. Clinically, axonal damage in RGC results in a loss of visual field and may lead to blindness. Currently, reducing eye pressure remains the sole target of proven glaucoma therapies. However, many patients continue to lose vision even when standard interventions are implemented, accentuating the unmet need for novel therapies. Dendrites are processes that determine how neurons receive and integrate information. Dendrite retraction and synapse breakdown are early signs of several neurodegenerative disorders. In mammals, CNS neurons have an extremely limited capacity to regenerate after injury. To date, the ability of mammalian neurons to regrow dendrites and reestablish functional synapses has been largely ignored. Insufficient insulin signaling has been implicated in diseases characterized by dendritic pathology, notably Alzheimer's disease and glaucoma. A versatile hormone, insulin readily crosses the blood-brain-barrier and influences numerous brain processes. In a mouse model of optic nerve transection, our team showed that insulin administration after optic nerve injury promoted robust dendritic regrowth, RGCs survival and retinal responses rescue, providing the first evidence of successful dendrite regeneration in mammalian neurons. Our research validates insulin as a powerful medication to restore dendritic function in glaucoma, forming the basis for using insulin as glaucoma treatment in humans. Currently, insulin is approved for diabetes. Adverse events of systemic insulin include hypoglycemia, hypokalemia, lipodystrophy, allergies, weight gain, peripheral edema and drug interactions. Experimental use of ocular topical insulin have been tested in small cohorts of healthy individuals and diabetic patients, reporting no significant adverse events. However, these protocols varied in insulin posology and adverse events were only touched upon briefly, indicating the necessity to better characterize the safety profile of such off-label use of insulin before its application as a neuroprotective and regenerative treatment for glaucoma. In this study, the investigators hypothesize that topical ocular insulin (up to 500 U/ml) at once per day dosing is safe in patients with open angle glaucoma.
Intraocular pressure (IOP) is the most important modifiable risk factor to prevent and delay progression of glaucoma. IOP reduction has been proven to delay the onset and progression of glaucoma, and uncontrolled IOP is constantly associated with progression of visual field loss. Medical therapy is the first line in IOP reduction for Primary Open Angle Glaucoma (POAG). It is a known fact that glaucoma patients often require addition of a second antiglaucoma medications when disease progresses or tachyphylaxis occurs. It was reported that more than 50% of patients require 2 or more medications to achieve optimum IOP control. Nevertheless, compliance and adherence are often impaired with multiple-drug therapy. Combining two ocular hypotensive agents in one bottle may help patients adhere to therapeutic regimen by reducing the number of medications used and the total number of doses administered.