Correlation of diabetic retinopathy and corneal neuropathy using confocal microscopy.

PURPOSE/AIM: To employ corneal confocal microscopy to assess differences in the extent of corneal nerve fiber alterations between diabetic patients classed according to retinopathy status and nondiabetic patients. MATERIALS AND METHODS: Two hundred seventy-eight corneas of 139 patients with type 2 diabetes mellitus and 94 corneas of 47 age-matched control participants were scanned using corneal confocal microscopy. Images of the subbasal nerve plexus were collected and analyzed for nerve fiber density (NFD), nerve branch density (NBD), nerve fiber length (NFL), and nerve fiber tortuosity (NFT). Diabetic patients were categorized into three groups according to the classification of diabetic retinopathy (DR) proposed in the Early Treatment of Diabetic Retinopathy Study, based on indirect fundoscopy, fundus photography, and fluorescein angiography findings. A separate classification into four groups according to the severity of peripheral diabetic neuropathy (DN) was also used, based on the results of clinical and electrodiagnostic examinations. RESULTS: Average NFD, NBD, and NFL differed significantly according to DR status and were found to be lower, whereas NFT was found to be higher in diabetic patients than control participants. A positive correlation between diabetic corneal neuropathy and peripheral DN was also found. CONCLUSIONS: Nerve fiber alterations of the subbasal nerve plexus of diabetic corneas appear to progress in parallel with DR and peripheral DN. Corneal confocal microscopy could possibly represent a promising adjuvant technique for the early diagnosis and assessment of human DN.

Adaptive optics ophthalmoscopy: results and applications.

PURPOSE: The living human eye's optical aberrations set a limit to retinal imaging in the clinical setting. Progress in the field of adaptive optics has offered unique solutions to this problem. The purpose of this review is to summarize the most recent advances in adaptive optics ophthalmoscopy. METHODS: Adaptive optics technology has been combined with flood illumination imaging, confocal scanning laser ophthalmoscopy, and optical coherence tomography for the high resolution imaging of the retina. RESULTS: The advent of adaptive optics technology has provided the technical platform for the compensation of the eye's aberration and made possible the observation of single cones, small capillaries, nerve fibers, and leukocyte dynamics as well as the ultrastructure of the optic nerve head lamina cribrosa in vivo. CONCLUSIONS: Detailed imaging of retinal infrastructure provides valuable information for the study of retinal physiology and pathology.