The use of explant lens culture to assess cataractogenic potential.

Explanted cultures of crystalline lenses have been used to investigate mechanisms of xenobiotic-induced cataract formation. However, very few studies have utilized mechanistic information to predict the cataractogenic potential of structurally diverse xenobiotics. The present investigation outlines how visual assessment of lens clarity, biochemical endpoints of toxicity, and mechanisms of lenticular opacity formation can be used to select compounds with a lower probability of causing cataract formation in vivo. The rat lens explant culture system has been used to screen thiazolidinediones against ciglitazone for their direct cataractogenic potential in vitro. The two compounds that were selected as development candidates (englitazone and darglitazone) did not produce cataracts in rats exposed daily for 3 months. The culture system has also been used to illustrate that the lens is capable of metabolizing compounds to reactive intermediates. In this example, the toxicity of S-(1,2-dichlorovinyl)-L-cysteine (DCVC), a model cataractogen, was attenuated by inhibiting lenticular cysteine conjugate beta-lyase metabolism using aminooxyacetic acid. Finally, this model was used retrospectively to investigate the cataractogenic potential of CJ-12,918 and CJ-13,454 in rats. These compounds showed differences in the incidence of cataract formation in vivo based on differences in hepatic metabolism and penetration of parent drug and metabolites into the lens. The rank order of cataractogenic potential in vitro correlated better with in vivo results when an induced S9 microsomal fraction was added to the culture media. However, the model did not correctly predict the cataractogenic potential of ZD2138, a structurally similar compound. These studies illustrate the use of explant culture to assess mechanisms of cataract formation and outline its use and limitations for predicting cataractogenic potential in vivo.

Tapetal effect of an azalide antibiotic following oral administration in beagle dogs.

An azalide antibiotic (CP-62,993) was administered at 100 mg/kg by oral gavage once daily for 35 consecutive days to 3 normal Beagle dogs (tapetal) and 3 Beagle dogs lacking a clinically apparent ocular tapetum (atapetal). The total dose delivered was approximately 100-fold the recommended clinical dose. Bilateral ophthalmoscopic changes were observed in the treated tapetal dogs on Day 36, consisting of mild to moderate tapetal decoloration with loss of the normal color change at the junction with the nontapetal fundus and muting of reflectivity of the normally highly reflective tapetum; treated atapetal and all control tapetal and atapetal dogs had no ophthalmoscopic changes. Microscopic examination of ocular tissue revealed rudimentary tapetal cell layers in the correct location in untreated, clinically atapetal eyes. Tapetal cells from treated tapetal and atapetal dogs were swollen and vacuolated, and contained intracytoplasmic, electron-dense debris but no recognizable tapetal rodlets. Lysosomal lamellar bodies were observed in the retinal ganglion cells of both treated groups and were neither enhanced nor reduced by the presence of a functional tapetum. Necrosis and inflammation were not observed in any ocular tissue. The altered ophthalmoscopic appearance of treated tapetal dogs was not influenced by the retinal changes because any effect on retinal transparency would have been seen in treated atapetal dogs. The decoloration and muting of reflectivity observed clinically in the tapetal fundus of dogs following prolonged exposure to high levels of CP-62,993 result from unique changes within the ocular tapetum itself and cannot be interpreted to be of consequence to nontapetal species including humans.