Socioeconomics of retinopathy of prematurity screening and treatment in the United States.

BACKGROUND: Retinopathy of prematurity (ROP) screening, an integral part of pediatric ophthalmology, can be time consuming and resource intensive. The purpose of this study was to evaluate the economic landscape of ROP screening and treatment among pediatric ophthalmologists in the United States. METHODS: An online survey was distributed to US pediatric ophthalmologists through a pediatric ophthalmology email listserv. Survey results were compiled, and responses were deidentified and analyzed, with particular focus on factors affecting financial compensation. RESULTS: A total of 97 responses were collected. Almost half of respondents worked in private practice settings. Over 80% of respondents had a formal contract to perform ROP care, but only 26% enlisted the assistance of an attorney to negotiate their contract. Just over half of respondents believed themselves adequately compensated for their services. Respondents that had retained an attorney for contractual negotiations were more likely to have a higher mean annual compensation rate ($126,545 ± $145,133 vs $70,214 ± $50,671; P = 0.05). Physicians who believed themselves adequately compensated were more likely to be in academic practice settings (78% academic vs 55% combo/other vs 24% private; P < 0.001) and were more likely to have contracts to perform ROP care (68% with contracts vs 15% without; P = 0.001). Average annual compensation was $82,968 ± $84,132, approximately $24,000 higher than reported in 2013. CONCLUSIONS: More pediatric ophthalmologists among our respondents obtained contracts for their services, and compensation rates have increased since 2013. Nevertheless, concerns regarding under-compensation and time commitment persist, raising concerns about the long-term sustainability of current models for providing ROP services.

Analysis of RPE morphometry in human eyes.

PURPOSE: To describe the RPE morphometry of healthy human eyes regarding age and topographic location using modern computational methods with high accuracy and objectivity. We tested whether there were regional and age-related differences in RPE cell area and shape. METHODS: Human cadaver donor eyes of varying ages were dissected, and the RPE flatmounts were immunostained for F-actin with AF635-phalloidin, nuclei stained with propidium iodide, and imaged with confocal microscopy. Image analysis was performed using ImageJ (NIH) and CellProfiler software. Quantitative parameters, including cell density, cell area, polygonality of cells, number of neighboring cells, and measures of cell shape, were obtained from these analyses to characterize individual and groups of RPE cells. Measurements were taken from selected areas spanning the length of the temporal retina through the macula and the mid-periphery to the far periphery. RESULTS: Nineteen eyes from 14 Caucasian donors of varying ages ranging from 29 to 80 years were used. Along a horizontal nasal to temporal meridian, there were differences in several cell shape and size characteristics. Generally, the cell area and shape was relatively constant and regular except in the far periphery. In the outer third of the retina, the cell area and shape differed from the inner two-thirds statistically significantly. In the macula and the far periphery, an overall decreasing trend in RPE cell density, percent hexagonal cells, and form factor was observed with increasing age. We also found a trend toward increasing cell area and eccentricity with age in the macula and the far periphery. When individuals were divided into two age groups, <60 years and ≥60 years, there was a higher cell density, lower cell area, lower eccentricity, and higher form factor in the younger group in the macula and the far periphery (p<0.05 for all measurements). No statistically significant differences in RPE morphometry between age groups were found in the mid-periphery. CONCLUSIONS: Human cadaver RPE cells differ mainly in area and shape in the outer one third compared to the inner two-thirds of the temporal retina. RPE cells become less dense and larger, lose their typical hexagonal shape, and become more oval with increasing age.

Tauroursodeoxycholic Acid Protects Retinal Function and Structure in rd1 Mice.

We explored the potential protective effects of tauroursodeoxycholic acid (TUDCA) on cone photoreceptor survival in a model of rapid retinal degeneration, the ß-Pde6 (rd1) (rd1) mouse model. We injected two strains of rd1 mice (B6.C3-Pde6b (rd1) Hps4(le)/J and C57BL/6J-Pde6b (rd1-2)/J mice) daily from postnatal day (P) 6 to P21 with TUDCA or vehicle. At P21, retinal function was evaluated with light-adapted electroretinography (ERG) and retinal structure was observed with plastic or frozen sections. TUDCA treatment partially preserved function and structure in B6.C3-Pde6b (rd1) Hps4(le)/J mice but only partially preserved structure in C57BL/6J-Pde6b (rd1-2)/J mice. Our results suggest a possible intervention for patients undergoing rapid retinal degeneration.

RPE Cell and Sheet Properties in Normal and Diseased Eyes.

Previous studies of human retinal pigment epithelium (RPE) morphology found spatial differences in density: a high density of cells in the macula, decreasing peripherally. Because the RPE sheet is not perfectly regular, we anticipate that there will be differences between conditions and when and where damage is most likely to begin. The purpose of this study is to establish relationships among RPE morphometrics in age, cell location, and disease of normal human and AMD eyes that highlight irregularities reflecting damage. Cadaveric eyes from 11 normal and 3 age-related macular degeneration (AMD) human donors ranging from 29 to 82 years of age were used. Borders of RPE cells were identified with phalloidin. RPE segmentation and analysis were conducted with CellProfiler. Exploration of spatial point patterns was conducted using the "spatstat" package of R. In the normal human eye, with increasing age, cell size increased, and cells lost their regular hexagonal shape. Cell density was higher in the macula versus periphery. AMD resulted in greater variability in size and shape of the RPE cell. Spatial point analysis revealed an ordered distribution of cells in normal and high spatial disorder in AMD eyes. Morphometrics of the RPE cell readily discriminate among young vs. old and normal vs. diseased in the human eye. The normal RPE sheet is organized in a regular array of cells, but AMD exhibited strong spatial irregularity. These findings reflect on the robust recovery of the RPE sheet after wounding and the circumstances under which it cannot recover.