Thermo-responsive poly(NiPAAm-co-DEGMA) substrates for gentle harvest of human corneal endothelial cell sheets

Gentle harvesting of corneal endothelial cell sheets grown in culture is of interest for the development of cornea replacement strategies. Thin films of a fast responding copolymer of N-isopropylacrylamide (NiPAAm) and diethyleneglycol methacrylate (DEGMA) with a phase transition temperature of 32 degrees C were prepared and evaluated for that purpose. The polymer layers were immobilized onto fluorocarbon substrates using low pressure argon plasma treatment. Cell culture and detachment experiments were performed with L929 mouse fibroblasts and human corneal endothelial cells (HCEC) at standard conditions. The hydrogel-coated supports were found to permit adhesion, spreading, and proliferation of both cell types. Harvesting of cell sheets was achieved upon lowering the temperature to about 30 degrees C. The formation of a closed monolayer as a crucial prerequisite for maintaining ionic pump function in HCEC was proven by ZO-1 immunostainung. Labeling of fibronectin indicated that the vast majority of the extracellular matrix is detached from the hydrogel coatings together with the cell layer. Inspired by this result, the reuse of the hydrogel-coated culture carriers was investigated confirming the suitability of the substrates for repeated cell harvesting. Altogether, the introduced thermoresponsive coating was found advantageous for the efficient generation of HCEC sheets and will be further utilized in transplantation strategies.     

The influence of biomimetic topographical features and the extracellular matrix peptide RGD on human corneal epithelial contact guidance

A major focus in the field of tissue engineering is the regulation of essential cell behaviors through biophysical and biochemical cues from the local extracellular environment. The impact of nanotopographical cues on human corneal epithelial cell (HCEC) contact guidance, proliferation, migration and adhesion have previously been demonstrated. In the current report we have expanded our study of HCEC responses to include both biophysical and controlled biochemical extracellular cues. By exploiting methods for the layer-by-layer coating of substrates with reactive poly(ethylene imine)/poly(2-vinyl-4,4-dimethylazlactone)-based multilayer thin films we have incorporated a single adhesion peptide motif, Arg–Gly–Asp (RGD), on topographically patterned substrates. This strategy eliminates protein adsorption onto the surface, thus decoupling the effects of the HCEC response to topographical cues from adsorbed proteins and soluble media proteins. The direction of cell alignment was dependent on the scale of the topographical cues and, to less of an extent, the culture medium. In EpiLife® medium cell alignment to unmodified-NOA81 topographical features, which allowed protein adsorption, differed significantly from cell alignment on RGD-modified features. These results demonstrate that the surface chemical composition significantly affects how HCECs respond to topographical cues. In summary, we have demonstrated modulation of the HCEC response to environmental cues through critical substrate and soluble parameters.     

Two clonal cell lines of immortalized human corneal endothelial cells show either differentiated or precursor cell characteristics

Access to primary human corneal endothelial cells (HCEC) is limited and donor-derived differences between cultures exacerbate the issue of data reproducibility, whereas cell lines can provide sufficient numbers of homogenous cells for multiple experiments. An immortalized HCEC population was adapted to serum-free culture medium and repeated cloning was performed. Clonally grown cells were propagated under serum-free conditions and growth curves were recorded. Cells were characterized immunocytochemically for junctional proteins, collagens, Na,K-ATPase and HCEC-specific 9.3.E-antigen. Ultrastructure was monitored by scanning and transmission electron microscopy. Two clonal cell lines, HCEC-B4G12 and HCEC-H9C1, could be isolated and expanded, which differed morphologically: B4G12 cells were polygonal, strongly adherent and formed a strict monolayer, H9C1 cells were less adherent and formed floating spheres. The generation time of B4G12 cells was 62.26 +/- 14.5 h and that of H9C1 cells 44.05 +/- 5.05 h. Scanning electron microscopy revealed that B4G12 cells had a smooth cell surface, while H9C1 cells had numerous thin filopodia. Both cell lines expressed ZO-1 and occludin adequately, and little but well detectable amounts of connexin-43. Expression of HCEC-specific 9.3.E-antigen was found commensurately in both cell lines, while expression of Na,K-ATPase alpha1 was higher in H9C1 cells than in B4G12 cells. B4G12 cells expressed collagen IV abundantly and almost no collagen III, while H9C1 cells expressed both collagens at reasonable amounts. It is concluded that the clonal cell line B4G12 represents an ideal model of differentiated HCEC, while H9C1 may reflect features of developing or transitional HCEC.     

Ocular cell monolayers cultured on biodegradable substrates.

The aim of this study was to culture retinal pigment epithelial (RPE) and corneal endothelial cells on biodegradable substrates for future use in monolayer transplantation in the eye. The biodegradable polymers, poly-l-lactic (PLLA) and poly-dl-lactic-co-glycolic acid (85:15) (PLGA) (both of molecular weight 105 kd) were the biomaterials used. All materials were seeded with either pig/human retinal pigment epithelial cells or rabbit corneal endothelial cells and were maintained in tissue culture conditions. Upon confluency, the cell density was calculated and cell viability determined. All monolayers were stained with phalloidin-rhodamine for F-actin and antibodies to the tight junction (zonula occludens) protein, ZO1, to demonstrate the presence of tight junctions. The final cell density of human RPE monolayers on PLLA films was 2950 cells/mm(2) (+/-185). The final cell density of pig RPE on PLLA and PLGA film was 2350 cells/mm(2) (+/-152 and 178, respectively). Rabbit corneal endothelial cells had a final cell density of 2650 cells/mm(2) (+/-164). F-actin staining revealed a circumferential ring of actin filaments in all of the cells grown on substrates. ZO(1) immunohistochemistry demonstrated staining along the lateral cell borders of all cell types. The successful culture of retinal pigment epithelial and corneal endothelial monolayers on these substrates may have potential for transplanting cell monolayers in the eye to improve vision.     

Investigation of Interleukin 2 Receptors on Human Endothelial Cells

Abstract

We have demonstrated that both recombinant and purified IL-2 exert a direct effect on quiescent human microvascular endothelial cells in vitro, causing the cells to enter the cell cycle and proliferate (Hicks et al., 1989). In this study we have identified IL-2 receptors (R) on both human umbilical vein (HUVEC) and neonatal foreskin (HCEC) endothelial cells. The techniques used to identify the receptors included proliferation studies, flow cytometry and immunofluorescence. Results indicate that both HUVEC and HCEC possess low numbers of receptors since both cell types proliferate in response to IL-2. The number of receptors on the cell surface vary according to passage number and culture conditions. Immunofluorescent studies show discrete areas of staining on the cell membrane. These combined results suggest that human vascular endothelial cells possess IL-2R.     

纤维蛋白胶与兔角膜3种细胞构建组织工程细胞片研究

目的： 观察兔角膜3种细胞能否在体外构建的纤维蛋白胶体上良好生长，探讨纤维蛋白胶作为组织工程细胞片支架材料的可行性。方法: 将培养扩增的兔角膜3种细胞分别接种于纤维蛋白胶表面,采用倒置显微镜,HE染色和扫描电子显微镜,观察兔角膜3种细胞在纤维蛋白胶表面生长情况。结果: 制备的薄层纤维蛋白胶支架光滑、透明，随培养细胞的生长部分降解，可获得仅带少量纤维蛋白胶的细胞片。角膜3种细胞在纤维蛋白胶表面生长良好，可保持生理状态的细胞形态。角膜上皮细胞可形成单层和复层，细胞间连接紧密。角膜内皮细胞呈圆形或多角形，细胞大小一致，排列紧密。角膜基质细胞拉长生长，呈三角形或树枝状，细胞间连接明显，可形成网状连接。结论: 体外构建的纤维蛋白胶与角膜3种细胞有组织相容性,纤维蛋白胶有望作为角膜3种细胞的生长载体构建可供移植的组织工程细胞片。     

Brain derived neurotrophic factor does not act on adult human cerebral endothelial cells

Brain derived neurotrophic factor (BDNF), known to promote survival of neurons, has recently been involved in the regulation of endothelial cells and was shown to possess immunoregulatory properties. We therefore asked whether BDNF has immunoregulating effects in human cerebral endothelial cells (HCEC). Adult HCEC expressed vascular cell adhesion molecule-1 and HLA class II following stimulation with tumor necrosis factor (TNF)-alpha and interferon (IFN)-gamma, respectively, but not after BDNF treatment. Addition of BDNF did not modulate the effects of TNF-alpha and IFN-gamma on HCEC, including TNF-alpha induced interleukin-8. Fluorescent activated cell sorting, RT-PCR, and immunohistochemistry indicated that HCEC do not express the trkB or p75 receptors involved in BDNF signaling. These results demonstrate that adult HCEC are not a likely target for BDNF. Novel factors regulating HCEC remain to be identified.     

Investigation of interleukin 2 receptors on human endothelial cells.

We have demonstrated that both recombinant and purified IL-2 exert a direct effect on quiescent human microvascular endothelial cells in vitro, causing the cells to enter the cell cycle and proliferate (Hicks et al., 1989). In this study we have identified IL-2 receptors (R) on both human umbilical vein (HUVEC) and neonatal foreskin (HCEC) endothelial cells. The techniques used to identify the receptors included proliferation studies, flow cytometry and immunofluorescence. Results indicate that both HUVEC and HCEC possess low numbers of receptors since both cell types proliferate in response to IL-2. The number of receptors on the cell surface vary according to passage number and culture conditions. Immunofluorescent studies show discrete areas of staining on the cell membrane. These combined results suggest that human vascular endothelial cells possess IL-2R.     

Structural characterization of bioengineered human corneal endothelial cell sheets fabricated on temperature-responsive culture dishes

For the purpose of corneal regenerative medicine, we fabricated human corneal endothelial cell sheets on temperature-responsive dishes, which could be non-invasively harvested as intact, transplantable sheets by simply reducing the culture temperature. Cells demonstrated hexagonal cell shape with numerous microvilli and cilia, and also exhibited abundant cytoplasmic organelles similar to these cells in vivo. Immunofluorescence for type IV collagen and fibronectin revealed that abundant extracellular matrix (ECM) was deposited on the basal surface throughout culture, and the deposited ECM was harvested along with the cell sheets by reducing culture temperature to 20 degrees C. Faint ECM remnants were observed on the dish surfaces after cell sheet detachment. Immunofluorescence for ZO-1 showed that tight junctions were established between cells, and immunoblotting indicated that intact ZO-1 was maintained during cell sheet harvest, while conventional proteolytic cell harvest methods resulted in the degradation of ZO-1. These results suggest that these transplantable corneal endothelial cell sheets can be applied to treat patients with damaged corneas.     

组织工程角膜材料研究进展

1　人工角膜材料人工角膜的发展经历了一个曲折漫长的过程 ,早在 1 789年 ,法国医生ＰｅｌｌｉｅｒｄｅＱｕｅｎｓｅｙ就提出了人工角膜的设想 ,继之而来各国的学者展开了研究 ,使用了不同的光学材料 ,如水晶、玻璃、赛璐珞、石英等 ,目前的人工角膜由二部分组成 :(1 )光柱 :一个光学透明的中心 ;(2 )支架 :周边部既具有支持光柱的功能 ,同时又能与角膜组织形成永久的固定[1] 。1 .1　光柱材料　光柱材料要求首先必须具有较好的光学性能 ,并且具有无化学毒性和良好的生物相容性。早期使用过无机玻璃 ,但因其耐受性较差而基本上被其他材料取…     

Heparin-modified dendrimer crosslinked collagen matrices for the delivery of heparin-binding epidermal growth factor

A tissue engineered corneal equivalent (TECEs) requires host integration to achieve adequate anchorage and long-term device stability. Corneal integration through epithelialization and stromal integration can be manipulated by growth factors. We investigated the potential of heparin-binding epidermal growth factor (HB-EGF) for mediating interactions with human corneal epithelial cells (HCEC) and compared its efficacy to epidermal growth factor (EGF) in vitro. Furthermore, we utilized heparinized dendrimer crosslinked collagen gels, intended for use as TECE, for delivery of HB-EGF in a sustained manner. HCEC were exposed to HB-EGF at varying concentrations between 0.1 and 1000 ng/mL. Cell proliferation increased with growth factor concentration up to a concentration of 50 ng/mL, suggesting growth factor receptor down-regulation at higher HB-EGF concentrations. Response to HB-EGF was comparable to EGF at low concentrations of 0.1 and 1 ng/mL but at a concentration of 10 ng/mL, HB-EGF induced significantly better proliferation than EGF. Proliferation was found to be dependent on the initial seeding density. Heparinized dendrimer crosslinked collagen (CHG) gels were capable of HB-EGF uptake, which was influenced by heparin concentration within the gel, growth factor concentration and exposure time to the growth factor. HB-EGF release followed first order kinetics, with ～90% of the growth factor released after 2 weeks. Growth factor stability was verified with in vitro HCEC culture studies. Bioavailability was maintained in the gels through heparin interaction. Overall, HB-EGF induced proliferation of HCEC in vitro and can be released from heparinized collagen gels making it potentially suitable for promoting epithelialization of TECEs.     

Internalization of Staphylococcus aureus by human corneal epithelial cells: role of bacterial fibronectin-binding protein and host cell factors

Wild-type Staphylococcus aureus was observed to be capable of invading human corneal epithelial cells (HCEC) in vitro. Internalization of S. aureus required expression of fibronectin-binding proteins (FnBPs); the capacity of an FnBP-deficient isogenic strain to invade HCEC was reduced by more than 99%. The binding of S. aureus to HCEC did not require viable bacteria, since UV-killed cells were observed to adhere efficiently. Invasion of HCEC by S. aureus involved active host cell mechanisms; uptake was nearly completely eliminated by cytochalasin D and genistein. These data suggest that FnBPs play a key role in host-parasite interactions and may serve as an important adhesin or invasin in ulcerative keratitis caused by S. aureus.     

Ultrathin chitosan–poly(ethylene glycol) hydrogel films for corneal tissue engineering

Due to the high demand for donor corneas and their low supply, autologous corneal endothelial cell (CEC) culture and transplantation for treatment of corneal endothelial dysfunction would be highly desirable. Many studies have shown the possibility of culturing CECs in vitro, but lack potential robust substrates for transplantation into the cornea. In this study, we investigate the properties of novel ultrathin chitosan–poly(ethylene glycol) (PEG) hydrogel films (CPHFs) for corneal tissue engineering applications. Cross-linking of chitosan films with diepoxy-PEG and cystamine was employed to prepare ～50 μm (hydrated) hydrogel films. Through variation of the PEG content (1.5–5.9 wt.%) it was possible to tailor the CPHFs to have tensile strains and ultimate stresses identical to or greater than those of human corneal tissue while retaining similar tensile moduli. Light transmission measurements in the visible spectrum (400–700 nm) revealed that the films were >95% optically transparent, above that of the human cornea (maximum ～90%), whilst in vitro degradation studies with lysozyme revealed that the CPHFs maintained the biodegradable characteristics of chitosan. Cell culture studies demonstrated the ability of the CPHFs to support the attachment and proliferation of sheep CECs. Ex vivo surgical trials on ovine eyes demonstrated that the CPHFs displayed excellent characteristics for physical manipulation and implantation purposes. The ultrathin CPHFs display desirable mechanical, optical and degradation properties whilst allowing attachment and proliferation of ovine CECs, and as such are attractive candidates for the regeneration and transplantation of CECs, as well as other corneal tissue engineering applications.     

Micro- and nanotopography with extracellular matrix coating modulate human corneal endothelial cell behavior

The human corneal endothelium plays an important role in maintaining corneal transparency. Human corneal endothelial cells have limited regenerative capability in vivo. Consequently, endothelial dysfunction can occur following corneal endothelial trauma or inherited diseases. To restore endothelial function, corneal transplantation is needed. However, there is a worldwide shortage of donor corneas, motivating the development of a tissue-engineered graft alternative using cultivated endothelial cells. To induce in vitro cell proliferation, much effort has been made to improve culture conditions and to mimic the native extracellular microenvironment. We incorporated topographical and biochemical cues in our in vitro culture of human corneal endothelial cell line B4G12 (HCEC-B4G12) and hypothesized that manipulation of the extracellular environment can modulate cell proliferation, morphometry and phenotype. The topographies tested were nanopillars, microwells and micropillars on polydimethylsiloxane, while the biochemical factors were extracellular matrix protein coatings of fibronectin-collagen I (FC), FNC® coating mix (FNC) and laminin-chondroitin sulfate (LC). Cellular morphometry, Na⁺/K⁺-ATPase and zona occludens 1 (ZO-1) gene and protein expression were analyzed 3 days after cells had formed a confluent monolayer. The cell circularity on all patterns and coatings was above 0.78. On all coatings, cell area was the lowest on micropillars. The coefficient of variation (CV) of the cell area was the lowest on nanopillars with an LC coating. With an FC coating, micropillars induced a better cellular outcome as the cells had the greatest circularity, smallest cell area and highest Na⁺/K⁺-ATPase and ZO-1 gene and protein expression. With the LC coating, HCECs grown on nanopillars resulted in the lowest CV of the cell area and the highest ZO-1 gene expression. Thus, HCEC-B4G12 morphometry and phenotype can be improved using different topographical and biochemical cues.     

Endothelial cell seeding onto various biomaterials causes superoxide-induced cell death

The seeding and/or in-growth of endothelial cells on a number of blood-contacting implants are a concern for both biomaterials and tissue engineering. While endothelialization has been viewed positively, owing to their ability to regulate both smooth muscle and blood, there is evidence which suggests that endothelial cells on a nonoptimized surface may be counterproductive. The present study describes the experimentation designed to elucidate the effect of culture substrate on intracellular superoxide (SO) levels, a marker for endothelial cell dysfunction. The adaptation of the use of dihydroethidium under physiologically relevant shearing conditions is also reported.The present study describes a standardized method for the use of dihydroethidium as a marker for intracellular oxidative stress under physiologic shear. Levels of hydrogen peroxide (oxidative stress producing agent) are optimized to a minimum of 60 microM (under static conditions) to allow for the detection of SO within the free radical scavenging environment. A flow rate of 24.4 mL/min is applied and found to produce physiologically relevant shear stress (8.2 dynes/cm(2)) within the system under study. Dihydroethidium is a useful marker for assessing intracellular oxidative stress in studies that require shear.     

In vitro biocompatibility of degradable biopolymers in cell line cultures from various ocular tissues: direct contact studies

Synthetic biodegradable polymers have many potential therapeutic applications. In ophthalmology, biodegradable polymers have been used as viscoelastic agents and surgical implants. Other potential applications include controlled release of drugs and growth factors, gene therapy, and tissue engineering. In the present study, in vitro biocompatibility of three biodegradable polymers, 50:50 PDLGA, 85:15 PDLGA, and Inion GTR membrane was evaluated in comparison to tissue culture polystyrene by investigating cell proliferation and potential acute toxicity by the WST-1 cytotoxicity/cell proliferation test, the ATP test, and the lactate dehydrogenase (LDH) test. Evaluations were conducted with cell line cultures from various ocular tissues, human corneal epithelial cells (HCE), rabbit stromal fibroblasts (SIRC), bovine corneal endothelial cells (BCE), human conjunctival epithelial cells (IOBA-NHC), and human retinal pigment epithelial cells (ARPE-19) by direct contact studies by plating the cells on the polymer film specimens in 96-wells. The proliferation results show that cell lines from various ocular tissues attached and grew on PDLGA 50:50, PDLGA 85:15, and Inion GTR membrane. Cytotoxicity experiments with the LDH and ATP tests showed no or extremely slight toxic adverse effects. These polymers have potential to be used as scaffolds in cell transplantation devices or as surgical implants.     

Fabrication of complex three-dimensional tissue architectures using a magnetic force-based cell patterning technique

We describe the fabrication of three-dimensional tissue constructs using a magnetic force-based tissue engineering technique, in which cellular organization is controlled by magnetic force. Target cells were labeled with magnetite cationic liposomes (MCLs) so that the MCL-labeled cells could be manipulated by applying a magnetic field. Line patterning of human umbilical vein endothelial cells (HUVECs) labeled with MCLs was successfully created on monolayer cells or skin tissues using a magnetic concentrator device. Multilayered cell sheets were also inducible on a culture surface by accumulating MCL-labeled cells under a uniform magnetic force. Based on these results, we attempted to construct a complex multilayered myoblast C2C12 cell sheet. Here, patterned HUVECs were embedded by alternating the processes of magnetic accumulation of C2C12 cells for cell layer formation and magnetic patterning of HUVECs on the cell layers. This technique may be applicable for the fabrication of complex tissue architectures required in tissue engineering.     

Influence of insulin immobilization to thermoresponsive culture surfaces on cell proliferation and thermally induced cell detachment

Temperature-responsive culture dishes immobilized with insulin have been fabricated and studied to shorten cell culture periods by facilitating more rapid cell proliferation. Cells are recovered as contiguous cell sheets simply by temperature changes. Functionalized culture dishes were prepared by previously reported electron beam grafting copolymerization of N-isopropylacrylamide (IPAAm) with its carboxylate-derivatized analog, 2-carboxyisopropylacrylamide (CIPAAm), having similar molecular structure to IPAAm but with carboxylate side chains to tissue culture polystyrene dishes. Insulin was then immobilized onto culture dishes through standard amide bond formation with CIPAAm carboxylate groups. Adhesion and proliferation of bovine carotid artery endothelial cells (ECs) were examined on these insulin-immobilized dishes. Insulin immobilization was shown to promote cell proliferation in serum-supplemented medium. Increasing the grafted CIPAAm content on the tissue culture surfaces reduces cell adhesion and proliferation, even though these surfaces contained increased amounts of immobilized insulin. This result implies that a discrete balance exists between the amount of CIPAAm-free carboxylate groups and immobilized insulin for optimum cell proliferative stimulation. Cells grown on the insulin-immobilized surfaces can be recovered as contiguous cell monolayers simply by lowering culture temperature, without need for exogenous enzyme or calcium chelator additions. In conclusion, insulin-modified thermoresponsive culture dishes may prove useful for advanced cell culture and tissue engineering applications since they facilitate cell proliferation, and cultured cells can be recovered as viable contiguous monolayers by merely reducing culture temperature.     

Human corneal endothelial cell growth on a silk fibroin membrane

Tissue engineering of the cornea could overcome shortages of donor corneas for transplantation and improve quality. Our aim was to grow an endothelial layer on a substratum suitable for transplant. Silkworm (Bombyx mori) fibroin was prepared as 5 μm thick transparent membranes. The B4G12 cell line was used to assess attachment and growth of human corneal endothelial cells on fibroin and compare this with a reference substratum of tissue-culture plastic. To see if cell attachment and proliferation could be improved, we assessed coatings of collagen IV, FNC Coating Mix(?) and a chondroitin sulphate-laminin mixture. All the coatings improved the final mean cell count, but consistently higher cell densities were achieved on a tissue-culture plastic rather than fibroin substratum. Collagen-coated substrata were the best of both groups and collagen-coated fibroin was comparable to uncoated tissue-culture plastic. Only fibroin with collagen coating achieved cell confluency. Primary human corneal endothelial cells were then grown using a sphere-forming technique and when seeded onto collagen-coated fibroin they grew to confluency with polygonal morphology. We report the first successful growth of primary human corneal endothelial cells on coated fibroin as a step in evaluating fibroin as a substratum for the transplantation of tissue-constructs for endothelial keratoplasty.     

Novel approach for achieving double-layered cell sheets co-culture: overlaying endothelial cell sheets onto monolayer hepatocytes utilizing temperature-responsive culture dishes

Confluent human aortic endothelial cells (HAECs) cultured on thermo-responsive culture dish grafted with poly (N-isopropylacrylamide) were recovered as a contiguous cell sheet. The double-layered co-culture was achieved by placing the recovered HAEC sheet onto the rat hepatocyte layer directly. The double-layered structure of HAEC and hepatocytes remained in tight contact during culture. Hepatocytes in the layered co-culture system with the HAEC sheet maintained the differentiated cell shape and the albumin expression for over 41 days of culture, whereas the functions disappeared within 10 days of culture in control hepatocytes without the HAEC sheet. The layered co-culture of hepatocytes and the HAEC sheets, which allows for the expression of differentiated functions of hepatocyte continuously, such as liver lobule, offers a major advancement in liver tissue engineering.