P03-A138†Comparison of specular and light transmission microscopy for endothelial control of corneas stored in the active storage machine.

PURPOSE: The Active Storage Machine (ASM), designed by Sincler (a company of group Laboratoires Théa) for eyebanks, will be used for long term donor corneas preservation at 31°C before transplantation. In this device, the endothelial cell density (ECD) counting is expected to be performed non-invasively throughout the storage, thus without changing the storage medium nor handling the cornea. To meet these constraints, specular microscopy (SM), also used for cold storage was selected, instead of the standard light transmission microscopy (LTM-NaCl) used in eye banks storing corneas in organ culture at 31-34°C. The purpose of this study is to compare both imaging methods for ECD measurement of corneas preserved in ASM. METHODS: Five human corneas from body donation to Science were preserved in a prototype ASM with 35mmHg in the endothelial chamber, 2.5µl/min of Corneamax® (Eurobio, France) at 31°C for 5 days. The endothelium of the cornea was imaged through the ASM window using the CellChek® D+ SM (Konan Medical, California, United-States) equipped with an add on device at customized stage. The cornea was then immediately removed from the ASM and prepared for standard endothelial assessment (dilation of the intercellular spaces using 0.9% NaCl and light transmission imaging). Finally, the endothelium was stained with alizarine red and trypan blue and observed again with the same microscope, to determine ECD using the referenced method up to now. For each cornea and each observation method, 5 images were acquired: 1 central and 4 paracentral. The SM images were counted with the Konan software. The LTM-NaCl and 'Alizarin Red' counts were performed with a dedicated plugin of ImageJ after microscope calibration. RESULTS: The means ± SD of the ECD calculated for SM, LTM-NaCl and 'Alizarine' images were respectively of 2314 ± 537, 2243 ± 506 and 2354 ± 543 cells/mm2. There was no significant difference between the 3 methods (ANOVA one-way, p-value = 0.1066). The percentage error was -1.7% +/- 3.3% for SM and -4.7 +/- 4.0% for light transmission microscopy. CONCLUSION: Quality control of the endothelium of corneas stored in ASM can be performed non-invasively with a standard eye bank SM. The ECD measured by SM does not differ from that measured by the conventional microscopy technique used until now in organoculture.

Epithelial Regeneration in Human Corneas Preserved in an Active Storage Machine.

Purpose: To characterize the corneal epithelium (CE) and limbal epithelium (LE) of human corneas stored in an innovative active storage machine (ASM) after a period of organ culture (OC). Methods: Corneas unsuitable for graft and stored in a standard commercial OC medium for 2 to 5 weeks were transferred into our ASM for 14 days. The ASM actively maintained an overpressure on the endothelial side (20 mm Hg) while ensuring medium renewal. We compared three modalities of storage in the ASM's epithelial chamber: (1) alternating exposure to a supplemental hormonal epithelial medium (SHEM) and air (air-lifting), (2) continuous immersion in SHEM, and (3) continuous immersion in OC medium. Passive immersion of the whole cornea in OC medium or of the CE in SHEM with or without airlifting served as controls. Paired corneas were used for better comparability. Histology, differentiation (by immunolabeling), and ultrastructure were analyzed at the end. Results: The ASM with air-lifting was most effective in regenerating a pluristratified and differentiated CE (apical ZO-1 and MUC16 staining and regeneration of the glycocalyx). In addition, the LE was stratified with preserved expression of ABCB5. The ASM with immersion in SHEM or OC medium gave a less stratified and differentiated CE. In the three control groups, the epithelia, when present, were paucistratified and less differentiated. Conclusions: In human corneas previously stored in OC, the ASM regenerates a CE with differentiation characteristics close to normal. Translational Relevance: Regeneration of the epithelium of human corneas discarded by eye banks will increase tissue availability for research.

Tolerance to Light of Patients Suffering From Infectious Keratitis.

PURPOSE: With very photophobic patients, the advantages of red or near infrared light to develop new ophthalmology imaging devices seem obvious: no or little glare, possibility of long signal integration, no phototoxicity, and lesser autofluorescence of ocular tissues. Nevertheless, in this range, the shortest possible wavelength facilitates signal detection. The aim of this study was, thus, to determine the maximal irradiance tolerated with 6 wavelengths: 2 red, 2 far red, and 1 near infrared lights to determine the shortest wavelength well tolerated by patients, in comparison with the standard cobalt blue light of ophthalmology slitlamp. METHODS: An interventional, monocentric, single-group assignment study was conducted on 30 eyes of 30 patients with infectious keratitis. Thanks to a customized machine, the photophobic eye was exposed to the 6 lights with increasing intensity. The patients switched off the light when the discomfort was too elevated. The maximal cumulative irradiance possible at 482, 650, 675, 700, 750, and 800 nm were 171, 689, 759, 862, 920, and 889 mW/cm, respectively. RESULTS: The maximal cumulative irradiance tolerated by patients increased significantly with wavelength (P < 0.001), but the difference was not significant between each increment: red at 675 nm gave a significantly higher cumulative irradiance than blue at 482 nm; red at 700 nm did not provide significant gain compared with 675 nm; and far red at 750 nm still provided additional gain compared with 700 nm, but no significant gain was observed between 750 and 800 nm. The shortest wavelengths were stopped more quickly, and more than 50% of patients reached the maximum irradiance delivered by the source at 750 and 800 nm. CONCLUSIONS: We demonstrate that a light source at 750 and 800 nm can be used for ophthalmic imaging with good tolerance in photophobic patients. CLINICAL TRIAL REGISTRATION: NCT03586505.

Three-month Storage of Human Corneas in an Active Storage Machine.

BACKGROUND: Corneal storage for the very long term, without degradation, would make it possible to optimize a very limited resource worldwide. We previously demonstrated the superiority, compared to conventional 4-week passive organ culture (OC), of an active storage machine (ASM) that restores intraocular pressure and medium renewal. Here, we investigate eye banking for up to 3 months. METHODS: In a randomized preclinical trial with 24 paired corneas, 1 was stored in OC and the other in ASM, using the same medium. Assessments were done on the second day and at 3 months: endothelial cell density (ECD in cells/mm), corneal transparency and thickness. At day 86, OC corneas were deswelled in a common hyperosmotic medium, but not the ASM corneas, which had remained thin. In addition, at day 88, viable ECD was measured using a live/dead assay, and endothelial expression of Na/K ATPase, Cox IV, ZO-1, N-CAM, and CD166 was observed. RESULTS: The ASM extended storage to 3 months with unprecedented endothelial cell quality: no OC corneas remained suitable for transplantation, but one-third of ASM corneas were compliant (ECD > 2000/mm). Given that corneas with ECD > 1600/mm were also usable for emergency, 58% of ASM corneas were usable versus 33% in OC. EC survival was 53% higher in ASM (P < 0.001), structural and functional proteins of ECs were much better preserved in ASM, and it prevented the constant major edema of OC. CONCLUSIONS: By extending graft survival to 3 months, the ASM will optimize eye banking and open up new perspectives in experimental research.

Innovative corneal active storage machine for long-term eye banking.

Optimal ex vivo corneal storage in eye banks is crucial to increase both the number of corneas suitable for graft and their intrinsic quality, mainly the number of viable endothelial cells, which dictates graft survival in recipients. With both passive storage methods used worldwide (short-term cold storage in the United States, long-term organ culture in Europe), significant endothelial cell loss is inevitable. Here we show that, with an active storage machine, also called a bioreactor, which restores 2 fundamental physiological parameters, intraocular pressure and medium renewal, endothelial cell survival is improved by 23% compared with organ culture after 4 weeks' storage. Also observed in the bioreactor is a 4-fold higher expression of Na+ /K+ ATPase, which supports one of the major endothelial cell pumping functions. In addition, corneas remain thin and transparent, so they are suitable for surgery at any time. This new active eye banking method may help to reduce the severe global scarcity of donor corneas.

Storage of Porcine Cornea in an Innovative Bioreactor.

Purpose: To quantify cell survival and tissue structure preservation of porcine cornea stored in a bioreactor (BR) that recreates a transcorneal pressure gradient equivalent to intraocular pressure (IOP) and renews the medium. Methods: A BR comprising endothelial and epithelial chambers was machined in a biocompatible material. The porcine cornea, securely held, separated the chambers. Medium flow and pressure inside the endothelial chamber were maintained by a peristaltic pump. In the epithelial chamber, the corneal surface was alternatively exposed to air and a specific medium. Two transparent windows allowed thickness measurement by optical coherence tomography without opening the BR. Porcine corneas stored in the BR-on (pressure 20 mm Hg, flow 5 µL/min, temperature 31°C) were compared with (1) BR-off (no pressure or flow); (2) organ culture; and (3) Petri dish with agar on the endothelial side. Epithelial and limbal structure and differentiation, corneal transparency and thickness, and endothelial viability were compared after 7 days of storage and with fresh corneas. Results: Corneas stored in the BR-on were thinner and more transparent than those stored with the other methods. The BR-on preserved a stratified and differentiated (K3/K12+) corneal epithelium and undifferentiated basal limbal cells with stemness markers (K3/K12-; ABCB5, K14, p75+), as well as endothelial integrity. Conclusions: By recreating equivalent IOP and medium renewal, the BR obtained unprecedented storage quality of porcine corneas and preserved their main epithelial, limbal, and endothelial characteristics.