A slit-lamp is a binocular microscope used for eye examination using a slit-like light beam. In 1911, Allvar Gullstrand a Swedish Ophthalmologist designed table-mounted binocular eyepiece for 3-dimensional visualization of optically clear eye structures. Later Otto Henker, combined Gullstrand slit lamp with Czapski’s binocular microscope resulting in first slit lamp biomicroscope, allowing hand-fr...Read More
Macular Diseases
Ten Pearls for Performing Vitrectomy in Diabetic Retinopathy
Important terms: Truncation: To relieve all the surrounding traction 360 degree Segmentation: Dividing a larger membranes/FVP into smaller islands of FVP by 360-degree truncation around them. Delamination: Separation of these membranes/FVP from the retinal surface to which they are firmly adherent by creating a plane of dissection between them. Pearl #1 When not to perform vitrectomy in diabetic r...Read More
Visual Electrophysiology Made Simple for the Postgraduates
Visual electrophysiology is an extremely useful tool to study the retinal function objectively. It assesses the functional aspects of not only the retina but also the visual pathway as a whole. Even in this era of advanced imaging, one cannot ignore the importance of the functional aspects of the cellular network in the retina. The commonly used tests with their salient applications are enumerated...Read More
Ten Clinical Trials in Retinal Diseases Every Postgraduate Should Know
1. CATT (Comparison of Age-related Macular Degeneration Treatments Trials)1 Description A prospective, multicenter, single-blind, noninferiority randomized clinical trial. 1208 patients with neovascular AMD were enrolled from February 2008 and randomly assigned to receive intravitreal injections of ranibizumab (0.5 mg/0.05 ml) or bevacizumab (1.25 mg/0.05 ml) on either a monthly schedule or as nee...Read More
Clinical Applications of Multicolor Imaging
Multicolor imaging (MCI) is a non-invasive retinal imaging modality available in the Spectralis platform (Heidelberg Engineering, Heidelberg, Germany). It simultaneously acquires three reflectance images of the retina using three individual lasers of different wavelengths: blue (488 nm), green (515 nm), and infrared (820 nm). These penetrate the tissue to different depths, simultaneously capturing...Read More
Retinal imaging has come a long way today. From times of appropriately concentrating the fluorescein dye from scratch in the lab itself to times where we have a dye-free angiography system, technology has covered vast boundaries. There is a platter of different modalities in the market today, each having their own ebb and flow. And what the future beholds for us is certainly inexplicable. To throw...Read More