S Piselli

Revisited Microanatomy of the Corneal Endothelial Periphery: New Evidence for Continuous Centripetal Migration of Endothelial Cells in Humans

The control of corneal transparency depends on the integrity of its endothelial monolayer, which is considered nonregenerative in adult humans. In pathological situations, endothelial cell (EC) loss, not offset by mitosis, can lead to irreversible corneal edema and blindness. However, the hypothesis of a slow, clinically insufficient regeneration starting from the corneal periphery remains debatable. The authors have re‐evaluated the microanatomy of the endothelium in order to identify structures likely to support this homeostasis model. Whole endothelia of 88 human corneas (not stored, and stored in organ culture) with mean donor age of 80 ± 12 years were analyzed using an original flat‐mounting technique. In 61% of corneas, cells located at the extreme periphery (last 200 μm of the endothelium) were organized in small clusters with two to three cell layers around Hassall‐Henle bodies. In 68% of corneas, peripheral ECs formed centripetal rows 830 ± 295 μm long, with Descemet membrane furrows visible by scanning electron microscopy. EC density was significantly higher in zones with cell rows. When immunostained, ECs in the extreme periphery exhibited lesser differentiation (ZO‐1, Actin, Na/K ATPase, CoxIV) than ECs in the center of the cornea but preferentially expressed stem cell markers (Nestin, Telomerase, and occasionally breast cancer resistance protein) and, in rare cases, the proliferation marker Ki67. Stored corneas had fewer cell clusters but more Ki67‐positive ECs. We identified a novel anatomic organization in the periphery of the human corneal endothelium, suggesting a continuous slow centripetal migration, throughout life, of ECs from specific niches. STEM CELLS2012;30:2523–2534

Novel Technique for the Preparation of Corneal Grafts for Descemet Membrane Endothelial Keratoplasty

PURPOSE To report a simple novel technique to facilitate preparation of Descemet membrane grafts for Descemet membrane endothelial keratoplasty (DMEK). DESIGN Laboratory investigation and retrospective, single-center, consecutive case series. METHODS Preparation of the endothelial graft is performed on an artificial anterior chamber, endothelial side up. After an incomplete circular superficial trephination, we describe a simple technique using a 27 gauge cannula to detach the Descemet membrane (DM). Endothelial cell density (ECD) was measured before dissection on 12 human corneas for research and 3 days after storage in organ culture. Histologic and electron microscopy analysis were performed. A DMEK was performed in 50 patients with Fuchs dystrophy. Visual acuity and ECD were evaluated 2 and 6 months after surgery. RESULTS ECD was 2765 ± 256 cells/mm(2) on corneas for research before dissection and 2651 ± 305 cells/mm(2) after 3 days in organ culture (P < .01). Histologic and electronic sections confirm that the cleavage was between DM and posterior stroma. Clinically, preparation of 2 corneas from a single donor was unsuccessful; 48 corneas were clear at 2 months and 47 at 6 months. At 2 months 77% of the patients had recovered a visual acuity of at least 20/30. At 6 months, 91.5% of the patients had a visual acuity of at least 20/30. ECD was 2656 ± 28 cells/mm(2) (range: 2450-3100 cells/mm(2)) preoperatively, 1797 ± 41 cells/mm(2) (range: 1100-2700 cells/mm(2)) at 2 months, and 1658 ± 43 cells/mm(2) (range: 900-2600 cells/mm(2)) at 6 months. CONCLUSION We report here a reliable and efficient technique for the preparation of pure Descemet membrane grafts.

Use of Poloxamers for Deswelling of Organ-Cultured Corneas

PURPOSE Dextran T500, routinely used as a deswelling supplement in organ culture (OC), has been suspected of being toxic to corneal endothelial cells (ECs). This study was conducted to evaluate the innovative use of poloxamers compared with dextran for deswelling OC corneas. METHODS Five poloxamers (P124, P188, P237, P338, and P407) were dissolved respectively in a standard OC medium to reach 350 mOsmol/kg. In vitro cytotoxicity of these media was tested by MTT assay on human corneal epithelial and endothelial cell lines and on primary human corneal fibroblasts. Paired human corneas stored in OC for at least 21 days were assigned for 48 hours to a poloxamer medium or to a standard deswelling medium containing 5% dextran T500. Corneal EC density, morphometry, visualization, mortality, stromal thickness, transparency, and folding were evaluated before and after deswelling. Corneas were finally cut into three parts for histologic and ultrastructural observation. RESULTS Besides similar corneal transparency improvement and thickness deswelling, poloxamers (except P124) reduced EC loss and facilitated endothelial visualization, but improved stromal folding less than dextran. The similar ultrastructures observed in the two groups were epithelial shedding, normal collagen fiber diameter and organization, uptake of deswelling agents by ECs, vacuolization but normal organelles in ECs and keratocytes, and endothelial surface modifications. CONCLUSIONS P188, P237, P338, and P407 performed similarly in preserving ECs, improving EC visualization, deswelling corneal stroma and inducing moderate injuries to corneal ultrastructure. They appear superior to dextran for corneal deswelling in OC.

Endothelial morphometry by image analysis of corneas organ cultured at 31 degrees C.

PURPOSE To determine the factors influencing endothelial morphometry by using image analysis of corneas stored in organ culture to determine the coefficient of variation (CV) in cell area and percentage of hexagonal cells. METHODS The endothelia of 505 of the 559 corneas consecutively stored at the eye bank were routinely analyzed with Sambacornea image-analysis software (ver. 1.2.10; Tribvn, Châtillon, France) on three large-field images of 750 x 1000 microm, obtained after osmotic dilation of the intercellular spaces with 0.9% sodium chloride. Analysis was performed on at least 300 cells. The quality of the three-image set was graded poor, average, or good by an independent observer. The studied parameters were donor age and sex, lens status, storage time, and intrinsic quality of captured images. Statistics were analyzed by nonparametric tests. RESULTS Image analysis was possible for 504 of the 505 assessed corneas. Donor age correlated significantly with endothelial cell density (ECD; r = -0.343), CV (r = 0.221), and hexagonality (r = -0.314; P < 0.001 for the three). Image quality significantly influenced these three parameters. ECD and hexagonality decreased parallel to image quality, whereas the CV increased. In the 258 corneas assessed twice (on average, at day [D] +4, then D +14) ECD, CV, and hexagonality decreased during storage. CONCLUSIONS Despite the sometimes mediocre quality of the transmitted light microscopy images, endothelial parameters supplied by the analyzer were clinically reliable, since variations similar to those long known in specular microscopy were found. Endothelial morphometry (CV and hexagonality) is likely to provide further information on the endothelial function of the graft tissue, perhaps particularly for grafts of borderline ECD, close to the discard threshold.

Microarray Analysis of Cell Cycle Gene Expression in Adult Human Corneal Endothelial Cells

Corneal endothelial cells (ECs) form a monolayer that controls the hydration of the cornea and thus its transparency. Their almost nil proliferative status in humans is responsible, in several frequent diseases, for cell pool attrition that leads to irreversible corneal clouding. To screen for candidate genes involved in cell cycle arrest, we studied human ECs subjected to various environments thought to induce different proliferative profiles compared to ECs in vivo. Donor corneas (a few hours after death), organ-cultured (OC) corneas, in vitro confluent and non-confluent primary cultures, and an immortalized EC line were compared to healthy ECs retrieved in the first minutes of corneal grafts. Transcriptional profiles were compared using a cDNA array of 112 key genes of the cell cycle and analysed using Gene Ontology classification; cluster analysis and gene map presentation of the cell cycle regulation pathway were performed by GenMAPP. Results were validated using qRT-PCR on 11 selected genes. We found several transcripts of proteins implicated in cell cycle arrest and not previously reported in human ECs. Early G1-phase arrest effectors and multiple DNA damage-induced cell cycle arrest-associated transcripts were found in vivo and over-represented in OC and in vitro ECs. Though highly proliferative, immortalized ECs also exhibited overexpression of transcripts implicated in cell cycle arrest. These new effectors likely explain the stress-induced premature senescence that characterizes human adult ECs. They are potential targets for triggering and controlling EC proliferation with a view to increasing the cell pool of stored corneas or facilitating mass EC culture for bioengineered endothelial grafts.

Development of immunostaining of cell cycle related proteins in flat mounted corneal endothelium

Purpose Immunostaining of cell cycle proteins is necessary for the study of the proliferative status of corneal endothelial cells (EC). Most studies use cross sections, which offer direct access to intracellular antigens but allow visualization of only few cells, without giving a global view of an intact endothelium. We developed protocols for immunostaining of ECs of flat mounted corneas Methods Studied proteins: 4 proteins with a known expression pattern (intra-membranous ZO-1, cytoplasmic α actin, nuclear hnRNP and H3 histone) and 8 others, already described within EC: 3 cell cycle inhibitors (P27, P21, P16); 3 proliferation markers (PCNA, MCM2, Ki67), cyclins D1, and E. Fresh and organ cultured (OC) human corneas were used. Fixation/permeabilization: paraformaldehyde (PFA), acetone, methanol, ethanol, Hg, Zn, acetic acid, triton, sodium docecyl sulfate, alone or in combination. Antigen retrieval: heating and biochemical or chemical agents. Patterns of expression were also compared between endothelium and epithelium Results There was no universal protocol. Most of the time 0.5% PFA gave the best results, but for p21, and cyclins, specific protocols were necessary. Homogeneous staining was always obtained with a clear subcellular localization (nuclear or cytoplasmic). OC did not globally modify expression within EC whereas several nuclear or cytoplasmic translocations were observed within the epithelium Conclusion The use of protocols specifically designed for the endothelium of whole intact flat mounted corneas would allow a better localization of cell cycle proteins. They will be especially useful during attempts to alter the cell cycle and trigger EC proliferation. Grant: Fondation de l’Avenir 2007 ET7-468