Evaluation of Cytotoxicity of Various Ophthalmic Drugs, Eye Drop Excipients and Cyclodextrins in an Immortalized Human Corneal Epithelial Cell Line

Purpose. An immortalized human corneal epithelial cell line (HCE) was tested as a screening tool for prediction of topical ocular irritation/ toxicity by pharmaceuticals. Methods. Effects of various drugs, excipients and cyclodextrins (CDs) on viability of HCE cells were evaluated using two in vitrocytotoxicity tests, 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) dye reduction assay and propidium iodide assay. Results. Mitochondrion-based MTT test was a more sensitive indicator of cytotoxicity than the plasma membrane-based propidium iodide test. The tests revealed following cytotoxic rankings for ophthalmic drugs: dipivefrin > timolol > pilocarpine dexamethasone; for excipients: benzalkonium chloride (BAC) > sodium edetate (NA₂EDTA) > poly-vinyl alcohol (PVA) > methylparaben; and for CDs: -CD > dimethyl--cyclodextrin (DM--CD) > sulfobutyl ether (-cyclodextrin ((SBE)_7m--CD) hydroxypropyl--cyclodextrin (HP--CD) > -CD. In consideration of the in vivoclinical situation, the short exposure time (5 min) is more relevant even though toxic effects of some test substances were seen only after longer exposure times (30 and 60 min). Conclusions. Immortalized HCE cells are a promising tool for rapid cytotoxicity assays of ocular medications. The cell line is potentially useful in predicting the in vivocorneal toxicity of ocularly applied compounds.     

Transport and Hydrolysis of Enkephalins in Cultured Alveolar Epithelial Monolayers

An in vitro cultured monolayer system of alveolar epithelial cells was used as a model to investigate transport and hydrolysis of two enkephalin peptides, Met-enkephalin (TGGPM) and [D-Ala²]Met-enkephalinamide (TAGPM), in pulmonary epithelium. Isolated alveolar type II cells formed continuous monolayers when grown on microporous tissue culture-treated polycarbonate filters in serum-free, hormonally defined medium. Transport and hydrolysis studies of enkephalins in the monolayer system obtained after 6 days in culture, using fluorescence reversed-phase HPLC, indicate a reduced but significant degradation of enkephalins in the alveolar epithelium compared to most other epithelia previously reported. Aminopeptidases and dipeptidyl carboxypeptidase represent two major hydrolytic enzymes for TGGPM, as indicated by the formation of the degradative products Tyr and Tyr-Gly-Gly, while dipeptidyl peptidase, which is responsible for the formation of Tyr-Gly, contributes much less. The enkephalinase inhibitor thiorphan failed to prevent the hydrolysis of TGGPM whereas the enkephalin analog TAGPM was relatively resistant to enzymatic cleavage. The rate of enkephalin transport across the alveolar epithelium was directly proportional to drug concentration and occurred irrespective of transport direction, suggesting passive diffusion as the major mechanism for transepithelial transport. Agents that affect paracellular transport pathways, e.g., EGTA and the calcium ionophore A-23187, greatly promoted the transport rate. The ionophore at high doses, in addition to promoting tight junction permeability, also caused cellular damage associated with a sustained rise in intracellular calcium levels, as indicated by nuclear propidium iodide fluorescence. The cultured monolayer of alveolar epithelium may be used to study pulmonary drug absorption, degradation, and toxicity.     

Functional Evaluation of Anchored Skin Equivalent Cultured in Vitro: Percutaneous Absorption Studies and Lipid Analysis

Pharmaceutical Research -     

Monolayers of Human Alveolar Epithelial Cells in Primary Culture for Pulmonary Absorption and Transport Studies

Purpose. To develop a cell culture model of human alveolar epithelial cells in primary culture for the in vitro study of pulmonary absorption and transport. Methods. Type II pneumocytes isolated from normal human distal lung tissue by enzyme treatment and subsequent purification were plated on fibronectin/collagen coated polyester filter inserts, and cultured using a low-serum growth medium. Characterization of the cell culture was achieved by bioelectric measurements, cell-specific lectin binding, immunohistochemical detection of cell junctions, and by assessment of transepithelial transport of dextrans of varying molecular weights. Results. In culture, the isolated cells spread into confluent monolayers, exhibiting peak transepithelial resistance of 2,180 ± 62 X cm² and potential difference of 13.5 ± 1.0 mV (n = 30–48), and developing tight junctions as well as desmosomes. As assessed by lectin-binding, the cell monolayers consisted of mainly type I cells with some interspersed type II cells, thus well mimicking the situation in vivo. The permeability of hydrophilic macromolecular FITC-dextrans across the cell monolayer was found to be inversely related to their molecular size, with P_app values ranging from 1.7 to 0.2 X 10^–8 cm/sec. Conclusions. A primary cell culture model of human alveolar epithelial cells has been established, which appears to be a valuable in vitro model for pulmonary drug delivery and transport studies.     

Physicochemical Factors Associated with Binding and Retention of Compounds in Ocular Melanin of Rats: Correlations Using Data from Whole-Body Autoradiography and Molecular Modeling for Multiple Linear Regression Analyses

The relationship between the physicochemical characteristics of 27 new drug candidates and their distribution into the melanin-containing structure of the rat eye, the uveal tract, was examined. Tissue distribution data were obtained from whole-body autoradiograms of pigmented Long–Evans rats sacrificed at 5 min and 96 hr after dosing. The physicochemical parameters considered include molecular weight, pK _a, degree of ionization, octanol/water partition coefficient (log P _o/w), drug-melanin binding energy, and acid/base status of the functional groups within the molecule. Multiple linear regression analysis was used to describe the best model correlating physicochemical and/or biological characteristics of these compounds to their initial distribution at 5 min and to the retention of residual radioactivity in ocular melanin at 96 hr post-injection. The early distribution was a function primarily of acid/base status, pK _a, binding energy, and log P _(o/W), whereas uveal tract retention in rats was a function of volume of distribution (V ₁), log P _(o/w), pK _a, and binding energy. Further, there was a relationship between the initial distribution of a compound into the uveal tract and its retention 96 hr later. More specifically, the structures most likely to be distributed and ultimately retained at high concentrations were those containing strongly basic functionalities, such as piperidine or piperazine moieties and other amines. Further, the more lipophilic and, hence, widely distributed the basic compound, the greater the likelihood that it interacts with ocular melanin. In summary, the use of multiple linear regression analysis was useful in distinguishing which physicochemical characteristics of a compound or group of compounds contributed to melanin binding in pigmented rats in vivo.