Evaluation of the cytotoxic effects of ophthalmic solutions containing benzalkonium chloride on corneal epithelium using an organotypic 3-D model.

BACKGROUND: Benzalkonium chloride (BAC) is a common preservative used in ophthalmic solutions. The aim of this study was to compare the cytotoxic effects of BAC-containing ophthalmic solutions with a BAC-free ophthalmic solution using an organotypic 3-dimensional (3-D) corneal epithelial model and to determine the effects of latanoprost ophthalmic solution and its BAC-containing vehicle on corneal thickness in a monkey model. METHODS: The cytotoxicity of commercially available BAC-containing ophthalmic formulations of latanoprost (0.02% BAC) and olopatadine (0.01% BAC) was compared to that of BAC-free travoprost and saline in a corneal organotypic 3-D model using incubation times of 10 and 25 minutes. To compare the extent of differentiation of 3-D corneal cultures to monolayer transformed human corneal epithelial (HCE-T) cell cultures, expression levels (mRNA and protein) of the corneal markers epidermal growth factor receptor, transglutaminase 1 and involucrin were quantified. Finally, latanoprost ophthalmic solution or its vehicle was administered at suprapharmacologic doses (two 30 microL drops twice daily in 1 eye for 1 year) in monkey eyes, and corneal pachymetry was performed at baseline and at weeks 4, 13, 26 and 52. RESULTS: In the 3-D corneal epithelial culture assays, there were no significant differences in cytotoxicity between the BAC-containing latanoprost and olopatadine ophthalmic solutions and BAC-free travoprost ophthalmic solution at either the 10- or 25-minute time points. The 3-D cultures expressed higher levels of corneal epithelial markers than the HCE-T monolayers, indicating a greater degree of differentiation. There were no significant differences between the corneal thickness of monkey eyes treated with latanoprost ophthalmic solution or its vehicle (both containing 0.02% BAC) and untreated eyes. CONCLUSION: The lack of cytotoxicity demonstrated in 3-D corneal cultures and in monkey studies suggests that the levels of BAC contained in ophthalmic solutions are not likely to cause significant direct toxicity to epithelium of otherwise normal corneas.

Intestinal Toxicity in Rats Following Administration of CDK4/6 Inhibitors Is Independent of Primary Pharmacology.

Recently three different cyclin-dependent kinase 4 and 6 (CDK4/6) dual inhibitors were approved for the treatment of breast cancer (palbociclib, ribociclib, and abemaciclib), all of which offer comparable therapeutic benefits. Their safety profiles, however, are different. For example, neutropenia is observed at varying incidences in patients treated with these drugs; however, it is the most common adverse event for palbociclib and ribociclib, whereas diarrhea is the most common adverse event observed in patients treated with abemaciclib. To understand the mechanism of diarrhea observed with these drugs and in an effort to guide the development of safer drugs, we compared the effects of oral administration of palbociclib, ribociclib, and abemaciclib on the gastrointestinal tract of rats using doses intended to produce comparable CDK4/6 inhibition. Rats administered abemaciclib, but not palbociclib or ribociclib, had fecal alterations, unique histopathologic findings, and distinctive changes in intestinal gene expression. Morphologic changes in the intestine were characterized by proliferation of crypt cells, loss of goblet cells, poorly differentiated and degenerating enterocytes with loss of microvilli, and mucosal inflammation. In the jejunum of abemaciclib-treated rats, downregulation of enterocyte membrane transporters and upregulation of genes associated with cell proliferation were observed, consistent with activation of the Wnt pathway and downstream transcriptional regulation. Among these CDK4/6 inhibitors, intestinal toxicity was unique to rats treated with abemaciclib, suggesting a mechanism of toxicity not due to primary pharmacology (CDK4/6 inhibition), but to activity at secondary pharmacologic targets.

Contribution of membrane trafficking perturbation to retinal toxicity.

The retina is a highly structured tissue that is formed by layers containing 7 different cell types. The photoreceptor cell is a specialized type of neuron in the retina that is capable of absorbing and converting light into electrophysiological signals. There is a constant renewal process for photoreceptors consisting of intermittent shedding of the distal tips of the photosensitive outer segment and subsequent phagocytosis (uptake, degradation and recycling) by retinal pigmented epithelial (RPE) cells. This rebuilding process is essential for vision and the survival of photoreceptors and RPE cells. Drugs with a basic moiety have the potential to accumulate in the lysosome and impair its functions including the phagocytosis process, which could hinder clearance of outer segments and ultimately induce retinopathy. To determine the prevalence of this cellular mechanism in retinal toxicity, a collection of proprietary compounds associated with retinal toxicity were subjected to a battery of in vitro tests using the human adult retinal pigmented epithelium cell line, ARPE-19. The tests included a phagocytosis assay, and lysosomal and autophagosomal staining. The compounds that induced retinopathy clustered in the basic and lipophilic region, which drives lysosomal sequestration. This accumulation coincided with phagocytosis inhibition and an increase in autophagosome staining, suggesting a blockage of the membrane trafficking process. A correlation between the physicochemical properties and in vitro lysosomal pathway effects was established. These data reveal the importance of physicochemical properties of compounds and lysosome accumulation as a potential mechanism for drug-induced retinopathy and demonstrate the usefulness of in vitro screening in predicting this liability.

Investigation of ocular events associated with taprenepag isopropyl, a topical EP2 agonist in development for treatment of glaucoma.

PURPOSE: Taprenepag isopropyl is an EP2 receptor agonist that is in development for the treatment of glaucoma. Iritis, photophobia, and increased corneal thickness observed in a Phase 2 clinical trial with taprenepag isopropyl were not previously observed in topical ocular toxicity studies in rabbits and dogs. In vivo studies using cynomolgus monkeys and in vitro models were used to elucidate the mechanisms underlying these ocular events. METHODS: Monkeys were dosed daily for 28 days in 1 eye with taprenepag and in the other with vehicle control. Complete ophthalmic examinations were performed at baseline and weekly thereafter. Serial sections of eyes were examined histopathologically at the end of the study. Recovery after the discontinuation of taprenepag was assessed for 28 days in the monkeys in the high-dose group. In vitro studies evaluated cell viability, paracellular permeability, and cytokine induction with human corneal epithelial or endothelial cell cultures. RESULTS: Monkeys demonstrated a dose-related incidence of iritis and increased corneal thickness that resolved within 28 days of discontinuing taprenepag. There was no evidence in vivo of taprenepag toxicity to the corneal endothelium or epithelium. Cell viability of stratified epithelial cells was primarily affected by excipients and was similar to Xalatan(®). The viability of HCEC-12 cells was not affected by taprenepag at concentrations up to 100 µM. CONCLUSIONS: The lack of in vivo or in vitro endothelial cytotoxicity and the reversibility of the increase in corneal thickness and iritis in the monkey provide confidence to permit further clinical development of taprenepag.

Comparison of preservative-induced toxicity on monolayer and stratified Chang conjunctival cells.

Preservatives are used in ocular medications to prevent microbial contamination. The use of benzalkonium chloride (BAC), the most widely used preservative in ocular medications, has been scrutinized with a number of studies indicating its toxicity to monolayer cultures of corneal and conjunctival epithelial cells. The purpose of this study was to evaluate and compare the toxicity of BAC and other preservatives and common components of ocular formulations on monolayer and stratified air-lifted cultures of Chang conjunctival cells. Air-lifting Chang cells grown on transwell filters increased stratification as assessed by transepithelial electrical resistance and histology. Unlike monolayer cultures in which ocular medications containing BAC caused near complete loss of cell viability, stratified, air-lifted cultures were not affected by the presence of BAC in ocular medications with up to 30-min exposures. Stratification shifted the dose-response curve to the right for benzalkonium chloride, thimerosal, chlorhexidine digluconate, potassium sorbate and EDTA. These results demonstrate that stratification significantly affects cell viability of Chang conjunctival cells in response to preservatives and additives of ophthalmic preparations.