Study of melanopsin responses in optic neuropathy and sleep disturbance by means of the pupillary light reflex

Among the retina ganglion cells there are a small population of cells containing melanopsin and which respond directly to light. They are the intrinsically photosensitive ganglion cells (ipRGCs), whose functions are mainly non-visual. Among these non-visual functions of the ipRGCs, their influence on the pupillary response as a function of light was the central subject of this thesis. Both the inner retina through the ipRGCs and the outer retina through the rods and cones, provide neural information that regulates the pupillary light response (PLR) to light. This study evaluated the integrity of ipRGCs through PLR in patients with Primary Open Angle Glaucoma (POAG), mild, moderate and advanced, and in patients with Obstructive Sleep Apnea Syndrome (OSAS), moderate and severe. We evaluated also the color discrimination and achromatic spatial contrast sensitivity (CS), visual perimetry and retinal thickness evaluated by Optical Coherence Tomography (OCT). 98 participants were evaluated, 45 patients with POAG ( 27 18; mean age = 65.84 + 10.20), 28 with OSAS ( 14 14; mean age = 52.93 + 7.13) and 25 controls ( 17 8; mean age = 54.27 + 8.88). After the ophthalmological exam it was evaluated the contrast sensitivity and color discrimination measures using the Cambridge Colour Test (CCT). Pupil responses were elicited by Ganzfeld (Q450 SC, Roland Consult) presentation of 1-sec flashes of 470- and 640-nm at 7 luminance from -3 to 2.4 log cd/m2. PLR was measured with the eye tracker system View Point (Arrington Research Inc.). The tests were performed monocularly, on both eyes, in a darkened room. In order to compare data across groups, we used a General Estimating Equations (GEE) to adjust for within subject inter-eye correlations. Patients with moderate and advanced POAG had a significantly decreased PLR that depends on the severity of the glaucoma, for both the 470- and 640-nm stimuli, making evident the reduction of the contributions of the cones and rods to the PLR. The contributions of ipRGCs to PLR (assessed by the amplitude of the sustained response between 6 8 sec) were also significantly lower in patients with moderate and advanced POAG. In the initial and mild stages of POAG the contribution of ipRGCs to the PLR is preserved. However, POAG appears to affect spatial processing from the early stages of the disease. Mild-POAG patients showed a marked loss in the low spatial frequency bands, compatible with selective loss of magnocellular ganglion cells. The CS of patients with moderate and advanced POAG showed losses at both low and high spatial frequencies, suggesting a loss in both parvo- and margnocellular channels. A significant loss of color discrimination along the blue-yellow axis was observed in all stages of POAG. The PLR in patients with OSAS is partially preserved, however the peak amplitude responses for the 470-nm flash decreased with increased severity of OSAS. The contributions of the photoreceptors of the outer retina to the PLR were significantly lower at some of the luminance. Significant differences in CS or color discrimination were not observed in patients with OSAS. In conclusion, in moderate and advanced stages of glaucoma, both the contributions of ipRGCs to PLR as well as the M- and P channels, were found more affected than at the beginning of POAG, in contrast the parvocellular channel and the contributions of ipRGCs on the PLR would be more preserved (AU)