In vitro eye irritation testing using the open source reconstructed hemicornea - a ring trial.

The aim of the present ring trial was to test whether two new methodological approaches for the in vitro classification of eye irritating chemicals can be reliably transferred from the developers' laboratories to other sites. Both test methods are based on the well-established open source reconstructed 3D hemicornea models. In the first approach, the initial depth of injury after chemical treatment in the hemicornea model is derived from the quantitative analysis of histological sections. In the second approach, tissue viability, as a measure for corneal damage after chemical treatment, is analyzed separately for epithelium and stroma of the hemicornea model. The three independent laboratories that participated in the ring trial produced their own hemicornea models according to the test producer's instructions, thus supporting the open source concept. A total of 9 chemicals with different physicochemical and eye-irritating properties were tested to assess the between-laboratory reproducibility (BLR), the predictive performance, as well as possible limitations of the test systems. The BLR was 62.5% for the first and 100% for the second method. Both methods enabled to discriminate Cat. 1 chemicals from all non-Cat. 1 substances, which qualifies them to be used in a top-down approach. However, the selectivity between No Cat. and Cat. 2 chemicals still needs optimization.

Determining the Depth of Injury in Bioengineered Tissue Models of Cornea and Conjunctiva for the Prediction of All Three Ocular GHS Categories.

The depth of injury (DOI) is a mechanistic correlate to the ocular irritation response. Attempts to quantitatively determine the DOI in alternative tests have been limited to ex vivo animal eyes by fluorescent staining for biomarkers of cell death and viability in histological cross sections. It was the purpose of this study to assess whether DOI could also be measured by means of cell viability detected by the MTT assay using 3-dimensional (3D) reconstructed models of cornea and conjunctiva. The formazan-free area of metabolically inactive cells in the tissue after topical substance application is used as the visible correlate of the DOI. Areas of metabolically active or inactive cells are quantitatively analyzed on cryosection images with ImageJ software analysis tools. By incorporating the total tissue thickness, the relative MTT-DOI (rMTT-DOI) was calculated. Using the rMTT-DOI and human reconstructed cornea equivalents, we developed a prediction model based on suitable viability cut-off values. We tested 25 chemicals that cover the whole range of eye irritation potential based on the globally harmonized system of classification and labelling of chemicals (GHS). Principally, the MTT-DOI test method allows distinguishing between the cytotoxic effects of the different chemicals in accordance with all 3 GHS categories for eye irritation. Although the prediction model is slightly over-predictive with respect to non-irritants, it promises to be highly valuable to discriminate between severe irritants (Cat. 1), and mild to moderate irritants (Cat. 2). We also tested 3D conjunctiva models with the aim to specifically address conjunctiva-damaging substances. Using the MTT-DOI method in this model delivers comparable results as the cornea model, but does not add additional information. However, the MTT-DOI method using reconstructed cornea models already provided good predictability that was superior to the already existing established in vitro/ex vivo methods.

A miniaturized solid contact test with Arthrobacter globiformis for the assessment of the environmental impact of silver nanoparticles.

Silver nanoparticles (AgNPs) are widely applied for their antibacterial activity. Their increasing use in consumer products implies that they will find their way into the environment via wastewater-treatment plants. The aim of the present study was to compare the ecotoxicological impact of 2 differently designed AgNPs using the solid contact test for the bacterial strain Arthrobacter globiformis. In addition, a miniaturized version of this test system was established, which requires only small-sized samples because AgNPs are produced in small quantities during the design level. The results demonstrate that the solid contact test can be performed in 24-well microplates and that the miniaturized test system fulfills the validity criterion. Soils spiked with AgNPs showed a concentration-dependent reduction of Arthrobacter dehydrogenase activity for both AgNPs and Ag ions (Ag(+)). The toxic effect of the investigated AgNPs on the bacterial viability differed by 1 order of magnitude and can be related to the release of dissolved Ag(+). The release of dissolved Ag(+) can be attributed to particle size and surface area or to the fact that AgNPs are in either metallic or oxide form. Environ

SV40-transformed human corneal keratocytes: optimisation of serum-free culture conditions.

Aiming at the replacement of animal experiments in eye irritation testing, we have established a multilay ered cornea model comprising the co-culture of all three corneal cell types. It was the objective of this study to optimise serum-free culture conditions to preserve both growth and phenotype of an SV40-immortalised human corneal keratocyte cell line (HCK). Our results revealed that HCK continue to proliferate in both monolayer cultures as well as after seeding in a collagen matrix and resemble primary corneal keratocytes in morphology and functional characteristics under defined serum-free conditions. Furthermore, HCK were shown to transform into activated corneal fibroblast phenotypes in response to serum and TGF(beta)1. In summary, HCK cells mimic their in vivo (primary) precursors, both in sustaining the quiescent keratocyte phenotype (serum-starved conditions) and in responding to growth factor stimulation. Hence, this cell line may provide a useful tool to study the toxicity and wound healing response of corneal keratocytes in vitro.

Characterisation of human corneal epithelial cell cultures maintained under serum-free conditions.

Three-dimensional tissue constructs have been proposed as in vitro screening models for ocular irritancy. Based on our previous studies, in which a full-thickness corneal model based exclusively on SV40-immortalised cell lines was generated, we have currently evaluated the effects of a range of commercially-available cell culture media on several cellular parameters in cultures of a human corneal epithelial (HCE) cell line. This cell line was used in an attempt to establish a rational basis for the development of serum-free culture media for the assembly and long-term tissue culture of full-thickness corneal models. Briefly, we investigated the impact of serum-free culture on the proliferation, morphology, barrier function and cytokine expression of HCE cells. The number of cell layers and the epithelial differentiation were evaluated by histology. Barrier properties were characterised via the determination of transepithelial electrical resistance (TEER), fluorescein permeation, and the expression of the tight junction-related protein, zona occludin 1 (ZO-1). The cytokine expression pattern in response to serum-free culture was measured by using an antibody array system. Our results revealed that both the morphology and the barrier function of the epithelial constructs were comparable to those of human donor corneas, when serum-free media were supplemented with ascorbic acid, calcium, hydrocortisone and retinoic acid. Under these conditions, the artificial epithelium based on serum-free HCE cultures represented a valid model for the natural ocular surface.

A human corneal equivalent constructed from SV40-immortalised corneal cell lines.

Within the last decade, extensive research in the field of tissue and organ engineering has focused on the development of in vitro models of the cornea. The use of organotypic, three-dimensional corneal equivalents has several advantages over simple monolayer cultures. The aim of this study was to develop a corneal equivalent model composed of the same cell types as in the natural human tissue, but by using immortalised cell lines to ensure reproducibility and to minimise product variation. We report our success in the establishment of an SV40-immortalised human corneal keratocyte cell line (designated HCK). A collagen matrix, built up with these cells, displayed the morphological characteristics of the human stromal tissue and served as a biomatrix for the immortalised human corneal epithelial and endothelial cells. Histological cross-sections of the whole-cornea equivalents resemble human corneas in tissue structure. This organotypic in vitro model may serve as a research tool for the ophthalmic science community, as well as a model system for testing for eye irritancy and drug efficacy.

Comparison of human corneal cell cultures in cytotoxicity testing.

The cytotoxic pattern of cosmetic or pharmaceutical compounds within different layers of the human cornea is of special interest with respect to ocular safety testing. The aim of this study was to evaluate the ability of a newly developed human corneal keratocyte (HCK) cell line as an in vitro model to predict toxicity towards keratocytes in the corneal stroma. The cytotoxic response of immortalised HCK cultures towards different surfactants was compared to that of primary cultures of human corneal keratocytes. Our studies revealed comparable results for immortalised and primary keratocytes. Furthermore, we quantified surfactant-induced cytotoxic effects on immortalised cultures of corneal epithelium and endothelium. In conclusion, the HCK cell line represents an appropriate model to test keratocyte-specific toxicity and may serve as a useful building block in the construction of three-dimensional human cornea equivalent models.

Assessment of ocular irritation by image processed quantification of cell injury in human corneal cell cultures and in corneal constructs.

Currently, there are no accepted alternative tests for the replacement of animals in ocular irritation testing. This study focused on the quantification of cellular viability as a measure of toxic events in immortalised human corneal cell cultures and a three-dimensional corneal construct. Simultaneous vital dye staining by calcein AM and ethidium homodimer-1 was used to provide "live" and "dead" probes, respectively. For further quantification, we have developed image processing tools to evaluate digital images obtained from confocal fluorescence scanning microscopy measurements. Based on the finding that ocular irritation can be related to the extent of cell injury at the various cell layers of the cornea, we extended our studies from corneal cell cultures to an in vitro human corneal equivalent system comprising epithelial, stromal keratocyte and endothelial layers. Our results showed that the microscopic measurement of cellular injury by using either cell cultures or in vitro corneal constructs, combined with image processed quantification, can provide insight into the extent of the toxic effects.

Staurosporine-induced apoptosis in human cornea epithelial cells in vitro.

BACKGROUND: Apoptosis is a an important process in corneal development, homeostasis, and disease. This study was performed to determine for the first time basic temporal apoptotic features of SV-40 immortalized human corneal epithelial (HCE) cells. Additionally, we introduce a sensitive analysis of confocal microscopic images to measure the kinetics of staurosporine (STS) induced phosphatidylserine (PS) membrane translocation and early nuclear morphological changes. METHODS: HCE cells were cultured in the presence of STS to induce apoptosis. Caspase-3 activity was measured with the fluorogenic substrate z-DEVD-rhodamine 110. We determined mitochondrial viability with a 4-[3-(4-iodophenyl)-2-(4-nitrophenyl)-2H-5-tetrazolio]-1,3-benzenedisulfonate reduction assay, and chromatin degradation with a fluorometric method using 4,6-diamidino-2-phenylindole (DAPI). Membrane translocation of PS and nuclear alterations were assessed by quantitative fluorescence microscopy. Image processing routines were written in interactive data language (IDL). RESULTS: Nuclear alterations like hyperchromicity, pyknosis, and active chromatin reorganization evolved instantly after STS induction. They were followed by PS translocation, DNA fragmentation, mitochondrial breakdown, and caspase-3 activation, which were detected between approximately 90 min and 4 h. CONCLUSIONS: Morphological and texture sensitive descriptors proved to be highly susceptible for the quantification of early apoptotic nuclear characteristics in HCE cells. We propose this method to be considered for the detection of subtle nuclear reorganization in cellular studies.

A collaborative evaluation of the cytotoxicity of two surfactants by using the human corneal epithelial cell line and the WST-1 test.

This study was undertaken to investigate the use of the in vitro test WST-1, an assay of cell proliferation and viability, for a preliminary safety evaluation of topical ophthalmic preparations. The cytotoxicity of two surfactants, benzalkonium chloride (BAC) and polyoxyethylene-20-stearyl ether (Brij78, PSE) was independently investigated in four laboratories in the EU by using an immortalized human corneal epithelial (HCE) cell line. The HCE cells were exposed to BAC and PSE for 5 min, 15 min, and 1 hour, and the results of the HCE-WST-1 tests were collected and compared. After one-hour exposure, the EC(50) values in BAC-treated cells in the presence of serum ranged between 0.0650 +/- 0.0284 (mean +/- SD) mM, and those in the absence of serum 0.0296 +/- 0.0081 mM. The corresponding values for PSE were 0.0581 +/-.0300 mM and 0.0228 +/-.0063 mM. There were variations in the results between different laboratories, with coefficients of variation ranging from 31 to 121%, mean 58%. The use of one-hour exposure time is to be preferred, and the elimination of serum in the culture medium is recommended to avoid both underestimation of toxic effects and variability of the test results.

Tamoxifen induces changes in the lipid composition of the retinal pigment epithelium cell line D407.

Tamoxifen, the antioestrogenic drug prescribed for long-term, low-dose therapy of breast cancer, induces retinopathy. This study evaluates the effects of tamoxifen on the human retinal pigment epithelial cell line D407, attempting to identify the underlying mechanisms on tamoxifen-induced retinopathy and the involvement of cellular membranes in the cytotoxic action mechanism. We demonstrate that the tamoxifen-induced decrease in the cell growth of the D407 cell line results from pyknosis and cell cycle arrest rather than from necrosis. Furthermore, D407 cells influence the lipid composition of both plasma membrane and intracellular membranes in response to tamoxifen. Tamoxifen increases the physical order of the lipid bilayer. We observed a compensatory decrease in the cholesterol content of the plasma membrane which results in an increase of the plasma membrane fluidity. In intracellular membranes the phosphatidylcholine content is reduced to 50% of the controls. This reduction may be related to the formation of a second messenger via phospholipase pathway and sustained activation of protein kinase C. Since increased plasma membrane fluidity as well as sustained activation of protein kinase C influence the rod outer segments binding and/or ingestion by retinal pigment epithelial cells, our results suggest that membrane-mediated pathways contribute to the tamoxifen-induced retinopathy.