Transplantation of cryopreserved human corneas in a xenograft model

An ideal model to test methods of corneal storage for transplantation would simulate the environment of the grafted human cornea and predict the success of clinical corneal transplants (human to human). In this study, we tested such a model, the corneal xenograft (human to cat). Nine pairs of human corneas were transplanted into both eyes of nine recipient cats. One cornea of each pair was cryopreserved at -196 degrees C in 2.5 M dimethyl sulfoxide while the other was stored in preservative medium at 4 degrees C (control) for 6 +/- 2 (mean +/- SD) days before transplantation. One week after transplantation, the cats were euthanized and the eyes were examined. Three of the grafts (all cryopreserved) were clinical failures and showed no survival of donor corneal endothelial cells on scanning electron microscopy. The remaining six pairs of grafts were examined with a specular microscope and showed endothelial cell losses of 48 +/- 16% in cryopreserved and 8 +/- 16% in control corneas (p < 0.05). This survival is similar to survival in an earlier corneal perfusion model. The nine cryopreserved grafts were thicker than the control grafts, had fewer surviving keratocytes in the central stroma, and had more apoptotic central keratocytes (TUNEL assay). This failure rate in cryopreserved corneas clearly shows that this technique of cryopreservation was not adequate for clinical use. The corneal xenograft model can be used to study cellular survival and apoptosis in vivo after preservation as well as to test new methods of corneal preservation before initiating clinical trials.     

Corneal cryopreservation with dextran.

Different methods of corneal cryopreservation have been introduced, those employing intracellular cryoprotectants such as Me2SO or glycerol being the most widely favored. We investigated the influence of several freeze-thaw trauma variables on the survival of porcine endothelial monolayers when employing the extracellular cryoprotective agent dextran. We first examined the effects of various dextran concentrations and then, having ascertained the optimal concentration, further investigated the influence of fetal calf serum (FCS) concentration in the cryopreservation medium, the cooling rate, the thawing temperature, and the length of the preincubation in the freezing medium prior to cryopreservation. The numerical densities of endothelial cells were determined at dissection in hypoosmotic balanced salt solution and after organ culture by staining with alizarin red S and trypan blue. Morphological evaluation was not performed directly after thawing but after a subsequent organ culture at 37 degrees C to detect latent cell damage after freeze-thaw trauma. Our data revealed that corneas cryopreserved in minimal essential medium containing 10% dextran but lacking FCS, preincubated for 3 h, frozen at a cooling rate of 1 degrees C/min, and thawed at 37 degrees C incurred the lowest cell losses (22.4%, SD +/- 3.8). We conclude that dextran is an effective cryoprotectant for freezing of porcine corneas. However, variations between species in the results of cryopreservation require further investigation of an in vivo animal model and studies with human corneas before its clinical use can be recommended.     

Tolerance of human corneal endothelium to glycerol

As an initial step in the development of a method for corneal cryopreservation by vitrification, we attempted to establish the maximum concentration of glycerol to which human corneal endothelium could be exposed at 4 degrees C for 15 min without damage. Damage was defined as an increase in mean endothelial cell size or the inability to maintain corneal thickness for 1 week after exposure to glycerol. Using a system for long-term corneal perfusion, we perfused 24 paired human corneas with glycerol at 4 degrees C. The concentration of glycerol increased at a rate of 20% (w/v) (2.2 M) per hour until the desired maximum concentration was reached for that cornea, stabilized for 15 min, and then decreased at the same rate. The corneas were then perfused at 37 degrees C with Dulbecco's medium at a rate of 5 microliters/min under 18 mm Hg intracameral pressure for 7 days with daily measurements of corneal thickness. Endothelial morphology was examined by specular microscopy and by scanning electron microscopy. After 7 days of perfusion at 37 degrees C, there was a statistically significant direct relationship between the maximum concentration of glycerol to which the experimental eyes had been exposed and the increase in mean endothelial cell size. The mean endothelial cell size increased in corneas exposed to glycerol concentrations of 40, 50, and 60% (w/v), but did not differ significantly from baseline measurements in the corneas exposed to 30% glycerol or less. Thus, there was no detectable damage to human corneas exposed to 30% (w/v) (3.3 M) glycerol in this system. Tolerance of higher concentrations may be achieved by changes in the rates of addition and removal of glycerol or in the composition of the perfusate.     

Optimization of a Method for the Cryopreservation of Rabbit Corneas: Attempted Application to Human Corneas

The purpose of the present study was to set up and test a cryopreservation method for long-term storage of human corneas. Therefore the freezing solution was optimized in 264 rabbit corneas by testing the type of cryoprotectant, its concentration, addition and dilution pattern and exposure temperature. Then rabbit corneas were frozen in the optimum solution at different cooling rates and thawed in a water bath at different temperatures. Eight human corneas were cryopreserved with the method showing optimum results in rabbit corneas and four additional corneas were used as controls. Endothelial viability was assessed after each step by vital staining and scanning electron microscopy. Best results after exposure of rabbit corneas to the freezing solution were achieved when using a 10% cryoprotectant concentration, with direct addition/dilution and exposure at room temperature (3512 ±300 viable cellsmm² when using dimethylsulfoxide; 3403 ± 245 viable cellsmm² when using 1,2-propanediol). Cryopreserved rabbit corneas had the highest endothelial cell survival when frozen at 1°C/min and thawed at 37°C (2003 ± 372 viable cells/mm² when using dimethylsulfoxide and 1357 ± 667 viable cells/mm² when using 1,2-propanediol). Cryopreserved human corneas had 753 ± 542 viable cells/mm² when using dimethylsulfoxide and 56 ± 56 viable cells/mm² when using 1,2-propanediol. We can conclude that the method developed is easy to handle and shows optimum results in rabbit corneas, with an endothelial cell survival that is consistent with transplant acceptability criteria. The results obtained in human corneas are below prediction and are still unsatisfactory for successful use in eye banking.     

The effect of cryoprotection and cryodamage on corneal rehydration and endothelial structure

Corneal rehydration rate and endothelial ultrastructure were compared during postthaw perfusion of cryopreserved corneas and corneas that had been frozen and thawed without the benefit of cryoprotective solutions. The postthaw swelling rate of cryopreserved rabbit corneas was 171 μm/hr compared to 333 μm/hr in the cryodamaged corneas. Most of the endothelial cells were intact in the cryopreserved corneas, but the intercellular spaces were enlarged. In contrast, all of the endothelial cells in the cryodamaged corneas were disrupted and Descemet's membrane was only partially covered by the remaining cell fragments.     

Restoring the endothelium of cryopreserved arterial grafts: co-culture of venous and arterial endothelial cells

The use of arterial homografts in clinical practice is becoming increasingly common, yet there is an urgent need to address one of the most well-established problems associated with their use: the loss of integrity of the endothelium following cryopreservation. The partial lack of endothelium causes contact between the extracellular matrix and blood flow, which, in turn, often gives rise to thrombosis and/or restenosis. Our objective was first to attempt to replace the arterial endothelial cells lost during the cryopreservation process by seeding autologous venous endothelial cells, and to evaluate the behaviour of venous and arterial endothelial cells in co-culture. The idea was to establish whether venous endothelial cells would be accepted by arterial endothelial cells and could therefore be used to restore the endothelial lining for the subsequent use of these vessels in in vivo grafting procedures. For the co-culture experiments, endothelial cells were obtained from the jugular vein and both iliac arteries of the minipig by treatment with 0.1% type I collagenase. The venous endothelial cells were fluorescently labelled with the membrane intercalating dye PKH26. Equal numbers of venous and arterial endothelial cells were mixed and co-cultured for 24h, 48h or 4 days. Cell viability, determined by 2% trypan blue staining and the TUNEL method, was established before and after fluorescence labelling. Cellular activity was determined by estimating PGI2 levels in the cultures. The proliferation index was established by [H(3)]thymidine (1muCi/ml) in the cell culture medium. For the in vivo tests, 5 cm length segments of minipig iliac artery were used to establish the groups: control (n = 6), fresh arterial segments; group I (n = 16), cryopreserved arterial segments and group II (n = 16), cryopreserved arterial segments seeded with autologous venous endothelial cells. The cryopreserved vessels in group II were seeded by flooding with a labelled venous endothelial cell suspension. Once seeded, the arterial segments were included in an in vitro flow circuit. All the specimens were processed for fluorescence and light microscopy, and scanning electron microscopy. The denuded endothelial surface was determined in each group. Cell death was evaluated by the TUNEL method. We confirmed the existence of intercellular PECAM1-type junctions between venous (PKH26+) and arterial cells in co-culture and the functional activity of the cells. The cryopreserved arterial segments showed a well-preserved wall structure. However, different size areas of marked endothelial denudation were detected. After seeding with labelled cells (PKH26+), these denuded areas of the cryopreserved artery were entirely covered by fluorescent cells. After seeding, a drop in the proportion of damaged endothelial cells was recorded. Despite some loss of seeded cells after inclusion in the in vitro flow circuit, the endothelial cell count was not significantly different to those recorded for control, non-cryopreserved specimens. In conclusion arterial and venous endothelial cells growing in co-culture modify their behaviour to form multilayers. The two cell populations form normal PECAM1 junctions and preserve their functional properties. Seeding autologous venous endothelial cells on the luminal surface of cryopreserved arterial segments serves to restore the integrity of the endothelial layer.     

Expansion and cryopreservation of porcine and human corneal endothelial cells

Impairment of the corneal endothelium causes blindness that afflicts millions worldwide and constitutes the most often cited indication for corneal transplants. The scarcity of donor corneas has prompted the alternative use of tissue-engineered grafts which requires the ex vivo expansion and cryopreservation of corneal endothelial cells. The aims of this study are to culture and identify the conditions that will yield viable and functional corneal endothelial cells after cryopreservation. Previously, using human umbilical vein endothelial cells (HUVECs), we employed a systematic approach to optimize the post-thaw recovery of cells with high membrane integrity and functionality. Here, we investigated whether improved protocols for HUVECs translate to the cryopreservation of corneal endothelial cells, despite the differences in function and embryonic origin of these cell types. First, we isolated endothelial cells from pig corneas and then applied an interrupted slow cooling protocol in the presence of dimethyl sulfoxide (Me₂SO), with or without hydroxyethyl starch (HES). Next, we isolated and expanded endothelial cells from human corneas and applied the best protocol verified using porcine cells. We found that slow cooling at 1 °C/min in the presence of 5% Me₂SO and 6% HES, followed by rapid thawing after liquid nitrogen storage, yields membrane-intact cells that could form monolayers expressing the tight junction marker ZO-1 and cytoskeleton F-actin, and could form tubes in reconstituted basement membrane matrix. Thus, we show that a cryopreservation protocol optimized for HUVECs can be applied successfully to corneal endothelial cells, and this could provide a means to address the need for off-the-shelf cryopreserved cells for corneal tissue engineering and regenerative medicine.     

Validation of an endothelial roll preparation for Descemet Membrane Endothelial Keratoplasty by a cornea bank using “no touch” dissection technique

Descemet Membrane Endothelial Keratoplasty (DMEK) selectively replaces the damaged posterior part of the cornea. However, the DMEK technique relies on a manually-performed dissection that is time-consuming, requires training and presents a potential risk of endothelial graft damages leading to surgery postponement when performed by surgeons in the operative room. To validate precut corneal tissue preparation for DMEK provided by a cornea bank in order to supply a quality and security precut endothelial tissue. The protocol was a technology transfer from the Netherlands Institute for Innovative Ocular Surgery (NIIOS) to Lyon Cornea Bank, after formation in NIIOS to the DMEK “no touch” dissection technique. The technique has been validated in selected conditions (materials, microscope) and after a learning curve, cornea bank technicians prepared endothelial tissue for DMEK. Endothelial cells densities (ECD) were evaluated before and after preparation, after storage and transport to the surgery room. Microbiological and histological controls have been done. Twenty corneas were manually dissected; 18 without tears. Nineteen endothelial grafts formed a double roll. The ECD loss after cutting was 3.3 % (n = 19). After transportation 7 days later, we found an ECD loss of 25 % (n = 12). Three days after cutting and transportation, we found 2.1 % of ECD loss (n = 7). Histology found an endothelial cells monolayer lying on Descemet membrane. The mean thickness was 12 ± 2.2 µm (n = 4). No microbial contamination was found (n = 19). Endothelial roll stability has been validated at 3 days in our cornea bank. Cornea bank technicians trained can deliver to surgeons an ECD controlled, safety and ready to use endothelial tissue, for DMEK by “no touch” technique, allowing time saving, quality and security for surgeons.     

New uses for endothelial cell culture

Endothelial cells in culture have, in the past, been a valuable but capricious tool to test hypotheses on the role of components of the blood vessel wall in such functions as blood pressure homeostasis, hemostasis, permeability, transport of macromolecules and the processing of circulating biologically active substances. Now techniques are becoming available for raising long-term, large-scale cultures that can be maintained reproducibly and without loss of phenotypic characteristics. The outlook for establishing endothelial cell factories invites speculation on some far-reaching possibilities, such as endothelial cell banks that could be used for seeding autogenous cells on vascular prostheses, artificial kidney tubing, heart valves, or corneas, or for virus production, or for synthesis by endothelial cells of products at present beyond the reach of bacterial cells.     

Cryopreservation of human endothelial cells for vascular tissue engineering

To investigate the influence of cryopreservation on endothelial cell growth, morphology, and function human umbilical vein endothelial cells (HUVECs) were frozen following a standard protocol. Cell suspensions were exposed to 10% dimethyl sulfoxide in a high-potassium solution, cooled to -80 degrees C at 1 degrees C/min and stored in liquid nitrogen for 7-36 days. Samples were thawed in a 37 degrees C water bath and the cryoprotectant was removed by serial dilution. The growth of cell suspensions was assayed by culturing 7300 cells/cm2 for 3-5 days in order to determine the cell multiplication factor. Fresh and cryopreserved/thawed cells were analyzed for their growth, and their anti-inflammatory and anti-coagulant function by using cellular ELISA. Cryopreservation resulted in a retrieval of 66 +/- 5% and a viability of 79 +/- 3%. Cryopreserved/thawed and fresh cells showed identical doubling times and identical cell counts in the confluent monolayers. However, the lag phase of thawed HUVECs was approximately 36 h longer, resulting in significant differences in the cell multiplication factor at 3 and 5 days after seeding. After expansion to a sufficient cell count the lag phases were identical. Fresh and cryopreserved/thawed cells showed comparable anti-inflammatory and anti-coagulant activity, as judged by the basal and TNF-induced VCAM-1, ICAM-1, E-selectin, and thrombomodulin expression. Cryopreserved/thawed and recultivated endothelial cells are suitable for endothelialization of autologous allograft veins. Such tissue-engineered grafts will offer the necessary clinical safety for those patients who lack autologous material.     

Long-lasting priming of endothelial cells by plasma melatonin levels

Background

Endothelial cells are of great interest for cell therapy and tissue engineering. Understanding the heterogeneity among cell lines originating from different sources and culture protocols may allow more standardized material to be obtained. In a recent paper, we showed that adrenalectomy interferes with the expression of membrane adhesion molecules on endothelial cells maintained in culture for 16 to 18 days. In addition, the pineal hormone, melatonin, reduces the adhesion of neutrophils to post-capillary veins in rats. Here, we evaluated whether the reactivity of cultured endothelial cells maintained for more than two weeks in culture is inversely correlated to plasma melatonin concentration.

Methodology/Principal Findings

The nocturnal levels of melatonin were manipulated by treating rats with LPS. Nocturnal plasma melatonin, significantly reduced two hours after LPS treatment, returned to control levels after six hours. Endothelial cells obtained from animals that had lower nocturnal melatonin levels significantly express enhanced adhesion molecules and iNOS, and have more leukocytes adhered than cells from animals that had normal nocturnal levels of melatonin (naïve or injected with vehicle). Endothelial cells from animals sacrificed two hours after a simultaneous injection of LPS and melatonin present similar phenotype and function than those obtained from control animals. Analyzing together all the data, taking into account the plasma melatonin concentration versus the expression of adhesion molecules or iNOS we detected a significant inverse correlation.

Conclusions/Significance

Our data strongly suggest that the plasma melatonin level primes endothelial cells “in vivo,” indicating that the state of the donor animal is translated to cells in culture and therefore, should be considered for establishing cell banks in ideal conditions.     

Cryopreservation of Specific Pathogen-Free (SPF) Pig Islet Cells: Effect of Culture Time before Cryopreservation and after Thawing

The aim of this study was to determine the optimal conditions (effect of culture time before and after cryopreservation) for cryopreservation of specific pathogen-free pig islet cells. METHODS: (1) Glucose-induced insulin secretion by fresh islet cells cultured for 10 days was compared to that by islet cells cryopreserved 7 days after isolation and cultured 3 days after thawing. (2) Islet cells were cryopreserved 1, 7, or 14 days after isolation and cultured 3, 7, 14, or 21 days after thawing. Islet cell number, insulin content, and insulin response under perifusion tests were investigated. RESULTS: (1) Insulin response by cryopreserved islet cells was identical to that by fresh islet cells (basal/stimulation index: 2. 13 +/- 0.19 vs 2.17 +/- 0.16, n = 4, NS), although the amount of secreted insulin was reduced by 40% (area under the curve: 2136 +/- 198 pM/10(4) cells/180 min vs 3564 +/- 636 pM/10(4) cells/180 min, P = 0.104). (2) Cell number 6 days after thawing was reduced by 54, 40, and 63% when cryopreservations were carried out at D1, D7, and D14. (3) Insulin content in cultured or cryopreserved islet cells increased between 7 and 14 days of culture. (4) Whatever the culture time before and after cryopreservation, insulin secretion in response to glucose was maintained. The insulin release was the highest for islet cells cryopreserved 14 days after isolation and cultured 14 days after thawing (stimulation index: 6.19 +/- 2.68). CONCLUSIONS: SPF pig islet cells remained functional after cryopreservation in polyethylene glycol and it may be important to culture islet cells over 14 days before and after cryopreservation.     

Response of swine skin microvasculature to acute single exposures of X rays: quantification of endothelial changes

An acute single X-ray exposure of 2300 R produces in swine skin a moist reaction (ulceration) that appears at 17 days, heals by 32 days, and may break down again between 42 and 70 days. Initial studies quantified the epidermal population density changes during this 70-day period. This study was designed to quantify the density changes occurring in the endothelial cell population of the dermal microvasculature. While the basal population decreases to a nadir of 10% control by 24 days, the endothelial population remains at control levels. Beyond 24 days, the endothelial cell density decreases abruptly to 50% as the epidermal cell density returns to control levels and overshoots by 20% at 32 days. Subsequently, both populations decrease to zero by 57 days. Endothelial cell loss parallels a similar decrease in vascular lumen density. These findings indicate that the initial moist reaction results from a radiation-induced loss of epidermal cells, while the second reaction results from the loss of dermal microvasculature.     

New approach to improving endothelial preservation in cryopreserved arterial substitutes

The endothelial loss provoked by the methods of vascular cryopreservation used at most human vessel banks is one of the main factors leading to the failure of grafting procedures performed using cryopreserved vessel substitutes. This study evaluates the effects of the storage temperature and thawing protocol on the endothelial cell loss suffered by cryopreserved vessels, and optimises the thawing temperature and protocol for cryopreserving arterial grafts in terms of that producing least endothelial loss. Segments of the common iliac artery of the minipig (n = 20) were frozen at a temperature reduction rate of 1 degrees C/min in a biological freezer. After storing the arterial fragments for 30 days, study groups were established according to the storage temperature (-80, -145 or -196 degrees C) and subsequent thawing procedure (slow or rapid thawing). Fresh vessel segments served as the control group. Once thawed, the specimens were examined by light, transmission, and scanning electron microscopy. The covered endothelial surface was determined by image analysis. Data for the different groups were compared by one way ANOVA. When cryopreservation at each of the storage temperatures was followed by slow thawing, the endothelial cells showed improved morphological features and viability over those of specimens subjected to rapid thawing. Rapidly thawed endothelial cells showed irreversible ultrastructural damage such as mitochondrial dilation and rupture, reticular fragmentation, and peripheral nuclear condensation. In contrast, slow thawing gave rise to changes compatible with reversible damage in a large proportion of the endothelial cells: general swelling, reticular dilation, mitochondrial swelling, and nuclear chromatin condensation. Gradually thawed cryopreserved arteries showed a lower proportion of damaged cells identified by the TUNEL method compared to the corresponding rapidly thawed specimens (p < 0.05, for all temperatures). In all the groups in which vessels underwent rapid thawing (except at -145 degrees C), significant differences (p < 0.05) in endothelial cover values were recorded with respect to control groups. Storage of cryopreserved vessels at -80 degrees C followed by rapid thawing led to greatest endothelial cell loss (61.36+/-9.06% covered endothelial surface), while a temperature of -145 degrees C followed by slow thawing was best at preserving the endothelium of the vessel wall (89.38+/-16.67% surface cover). In conclusion, storage at a temperature of -145 degrees C in nitrogen vapour followed by gradual automated thawing seems to be the best way of preserving the endothelial surface of the arterial cryograft. This method gives rise to best endothelial cell viability and cover values, with obvious benefits for subsequent grafting.     

大鼠主动脉内皮细胞和平滑肌细胞的原代培养及生物学特性比较

目的培养大鼠主动脉平滑肌细胞和内皮细胞,细胞纯化与鉴定,比较生物学特性的差异。方法采用血管环贴壁法培养动脉内皮细胞,组织块贴壁法培养动脉平滑肌细胞,并采用有限稀释法挑选内皮细胞单克隆,免疫细胞荧光鉴定二者的特异性标志,相差显微镜观察二者单个细胞及细胞群体在形态上的差异性,CCK-8试剂盒检测细胞的增殖,比较二者对胰酶消化,粘附,冻存后复苏的情况。结果血管环贴壁法成功培养血管内皮细胞,组织块培养法成功培养出血管平滑肌细胞,内皮细胞能够形成单克隆集落,培养的细胞均表达相应的特异性标志,内皮细胞增殖速度和平滑肌细胞有差异,内皮细胞对胰酶的耐受性较差,内皮细胞粘附所需时间短,对冻存后的耐受性较好。结论组织块贴壁法适合内皮细胞和平滑肌细胞的培养,有限稀释法能够纯化原代培养的内皮细胞,大鼠主动脉平滑肌细胞和内皮细胞在细胞形态、增殖、粘附、对胰酶的反应、冻存后复苏均存在差异。     

The potential of an equimolar combination of propane-1,2-diol and glycerol as a vitrification solution for corneas

Corneas must first be equilibrated with multimolar concentrations of cryoprotectants if the formation of ice during cryopreservation is to be avoided by vitrification at practicable cooling rates. Rabbit corneas were exposed to equimolar mixtures of the cryoprotectants propane-1,2-diol and glycerol in a Hepes-buffered Ringer's solution containing glutathione, adenosine, 5 mmol/liter sodium bicarbonate, and 6% w/v bovine serum albumin. Endothelial function was assessed by monitoring its ability to control stromal hydration during perfusion of the endothelial surface at 34 degrees C for 6 h. Endothelial morphology was observed by specular microscopy during perfusion and by scanning electron microscopy after perfusion. Endothelial pump activity and structural integrity of the endothelial layer were demonstrated after 20 min exposure at 4 degrees C to a total concentration of 1.4 mol/liter cryoprotectant (i.e., 0.7 mol/liter propane-1,2-diol + 0.7 mol/liter glycerol). Exposure to 2.0 and 3.4 mol/liter cryoprotectant for 20 min at 4 degrees and -5 degrees C, respectively, resulted in initial endothelial damage; but this repaired and a functioning endothelial pump was subsequently demonstrated. Although exposure to 4.1 mol/liter cryoprotectant for 10 min at -10 degrees C caused irreparable damage to 2/4 corneas, reduced dilution temperatures together with increased dilution time allowed exposure to 4.8 and 5.5 mol/liter cryoprotectant with retention of endothelial pump activity. Exposure to 6.1 mol/liter cryoprotectant for 10 min at -15 degrees C caused endothelial damage which was not mitigated by the presence of 2.5% w/v chondroitin sulfate. Endothelial function may be improved by further modification of addition and dilution protocols or by exposure to the cryoprotectants at lower temperatures.     

Role of apoptotic signaling pathway in metabolic disturbances occurring in liver tissue after cryopreservation: Study on rat precision-cut liver slices

Precision-cut liver slices in culture (PCLS) appears as a useful and widely used model for metabolic studies; the interest to develop an adequate cryopreservation procedure, which would allow maintaining cell integrity upon incubation, is needed to extend its use for human tissues. We have previously shown that cryopreservation of rat PCLS leads to caspase-3 activation and early alterations of their K+ content upon incubation. In this study, we tested the hypothesis that counteracting intracellular K+ loss and/or interfering with cell death signaling pathways could improve the viability of cryopreserved PCLS. PCLS were prepared from male Wistar rat liver and cryopreserved by rapid freezing before incubation. The addition of a caspase inhibitor-Z-DEVD-FMK (2.5 microM)-in the culture medium did not improve viability of cryopreserved PCLS. Incubation of cryopreserved PCLS in a K+ rich medium (135 mM) increased K+ content and avoided caspase-3 activation, but did not improve cell viability. Caspase-3 inhibition, a decrease in cell lysis, and improvement of glycogen content were observed in cryopreserved PCLS after addition of LiCl (100 mM) in the incubation medium. These results indicate that, even if caspase-3 activation is linked to the K+ loss in cryopreserved PCLS, its inhibition does not allow restoring the metabolic capacities. LiCl, acting on a target upstream of caspase-3 inhibition, improves cell viability and allows glycogen accumulation when added in culture medium of cryopreserved PCLS; and could thus be considered as an interesting adjuvant in the culture of cryopreserved PCLS.     

Passage-dependent changes in baboon endothelial cells--relevance to in vitro aging

In vitro cell culture system is a useful model for aging-related changes in a wide spectrum of biomedical research. In this study, we explored the passage and donor age-dependent changes in baboon macrovascular endothelial cells that are relevant to both in vitro cell culture aging models and experiments using cell culture techniques. We collected baboon femoral arterial samples from nine baboons ranging in age from 6 months to 30 years (equivalent to humans approximately 18 months to 90 years of age). We then cultured baboon femoral artery endothelial cells (BFAECs) in standard DMEM medium with 20% fetal calf serum with 1:3 split for subculture. Endothelial functions were documented by morphology, Dil-LDL uptake and expression of eNOS, MCP-1, vWF, VCAM-1, ICAM-1, and E-Selectin with or without cytokine stimulation. Most of the cells became nonmitotic after 30 population doublings, or 10 passages, when they became flattened, enlarged, and senescent. While it took approximately 3 days to reach confluence from three-dilution seeding at early passages (<6), confluence was not achieved even after 7 days of culture for cells after the 9th or 10th passage. There was a linear decline in eNOS expression with passage. However, this decline was significantly less in endothelial cells from a young baboon (6 months) than those from an old baboon (30 years). While basal expression of adhesion molecules was not changed with passaging, responses to cytokine stimulation appeared to be increased in later passaged cells. Our study has provided evidence for passage-related changes in key endothelial functions. The donor age-related differences in this in vitro aging process suggests that in vitro endothelial culture can serve as a biomarker for in vivo aging. Nonhuman primates can provide a model for investigating such aging-related biological characteristics.     

Keratocyte injury in human corneas cryopreserved under standard conditions

This study was conducted to characterize ultrastructural damage to human corneas cryopreserved by a standard protocol. The materials used were seven human corneas that were unsuitable for transplantation due to the presence of positive bacteriological cultures; they were cryopreserved according the standard procedure. After freezing and thawing, samples were obtained for scanning and transmission electron microscopy studies. Marked damage was observed in keratocytes with signs of apoptotic cellular injury. However our observations have shown that apoptosis contribute less significantly than necrosis to cellular death in keratocytes of human corneas and although the control of apoptosis is clearly desirable, in order to improve the success of cryopreserved corneas for transplant, we need to continue our investigation to reduce the effects of the necrotic process. This revised version was published online in July 2006 with corrections to the Cover Date.     

Serum- and albumin-free cryopreservation of endothelial monolayers with a new solution

Cryopreservation is the only long-term storage option for the storage of vessels and vascular constructs. However, endothelial barrier function is almost completely lost after cryopreservation in most established cryopreservation solutions. We here aimed to improve endothelial function after cryopreservation using the 2D-model of porcine aortic endothelial cell monolayers.?The monolayers were cryopreserved in cell culture medium or cold storage solutions based on the 4°C vascular preservation solution TiProtec^®, all supplemented with 10% DMSO, using different temperature gradients. After short-term storage at ?80°C, monolayers were rapidly thawed and re-cultured in cell culture medium.?Thawing after cryopreservation in cell culture medium caused both immediate and delayed cell death, resulting in 11 ± 5% living cells after 24 h of re-culture. After cryopreservation in TiProtec and chloride-poor modifications thereof, the proportion of adherent viable cells was markedly increased compared to cryopreservation in cell culture medium (TiProtec: 38 ± 11%, modified TiProtec solutions ≥ 50%). Using these solutions, cells cryopreserved in a sub-confluent state were able to proliferate during re-culture. Mitochondrial fragmentation was observed in all solutions, but was partially reversible after cryopreservation in TiProtec and almost completely reversible in modified solutions within 3 h of re-culture. The superior protection of TiProtec and its modifications was apparent at all temperature gradients; however, best results were achieved with a cooling rate of ?1°C/min.?In conclusion, the use of TiProtec or modifications thereof as base solution for cryopreservation greatly improved cryopreservation results for endothelial monolayers in terms of survival and of monolayer and mitochondrial integrity.