Using fewer animals to identify chemical eye hazards: revised criteria necessary to maintain equivalent hazard classification.

U.S. Federal Hazardous Substances Act (FHSA) regulations specify eye safety testing procedures and hazard classification criteria for substances regulated by the U.S. Consumer Product Safety Commission (CPSC). Current regulations require up to three sequential 6-animal tests. Testing consistent with the Organisation for Economic Co-operation and Development (OECD) test guideline for eye irritation/corrosion, which specifies 3 animals, can also be submitted to US agencies. However, current FHSA regulations do not provide criteria to classify results from 3-animal tests. An analysis was conducted to determine criteria using results from 3-animal tests that would provide equivalent labeling to FHSA regulations. The frequency that FHSA requirements identify substances as ocular irritants was compared with the frequency that a criterion of either ≥ 1/3 or ≥ 2/3 positive animals would identify these substances. A database of rabbit eye tests was also used to estimate over- and underprediction rates for each criterion. In each instance, a criterion of ≥ 1/3 positive animals more closely matched the expected outcome based on FHSA requirements, while a criterion of ≥ 2/3 positive animals identified far fewer irritants. Using a classification criterion of ≥ 1/3 positive animals provided equivalent or greater eye hazard labeling as current FHSA requirements, while using 50-83% fewer animals.

Titration of KATP channel expression in mammalian cells utilizing recombinant baculovirus transduction.

A variety of transfection approaches have been used to deliver plasmids encoding ion channel genes into cells. We have used the baculovirus transduction system, BacMam, to demonstrate transient expression of multi-subunit KATP channels in CHO-K1 and HEK-293 EBNA cells using sulfonylurea receptor 1 (SUR), SUR2A, SUR2B, and KIR 6.2 genes. [3H]-glyburide binding, patch clamp, and DiBAC4(3) measurements of membrane potential changes were used to monitor channel expression. BacMam delivery of each SUR isoform with KIR6.2 was demonstrated based on its pharmacological profiles. Expression levels of SUR1 and KIR6.2 were titrated by varying the viral concentration or time of virus addition, with functional activity measured in as little as 4-6 hours posttransduction. Further increases in BacMam virus induced sufficient KATP expression to dominate membrane potential without pharmacological opening of the channel. Independently altering treatment with virus containing either the SUR1 or KIR6.2 gene revealed interactions among subunits during formation of functional channels in the plasma membrane. This study demonstrates the utility and versatility of BacMam as a valuable gene delivery tool for the study of ion channel function.