Concordance analysis of an in vitro micronucleus screening assay and the regulatory chromosome aberration assay using pharmaceutical drug candidates.

The in vitro micronucleus assay is under consideration by regulatory agencies as a suitable alternative to the in vitro chromosome aberration (CA) assay. At Pfizer, we utilized a non-Good Laboratory practices cytokinesis-block in vitro micronucleus (CBMN) assay in CHO cells as a screen to predict the regulatory outcome of the human lymphocyte CA assay, and we have retrospectively analyzed a highly select set of 112 internal drug candidates to measure concordance. Overall, our exploratory CBMN correctly classified 97 of 112 (86.6%) compounds in the CA assay. Specificity was high with 87 of 92 (94.6%) CA negative compounds correctly classified by CBMN. Sensitivity was low at 50% with 10 of 20 CA positive compounds correctly classified by CBMN; this may be attributed to the low number of CA positives in the select set. In an attempt to improve sensitivity, we increased the number of CA positives by combining our internal set with an industrial data set previously published (Miller B et al. 1997: Mutat Res 392:45-59). When combined, concordance was 86.7% (143/165), specificity was 91.2% (114/125), and sensitivity increased to 72.5% (29/40). Because cytotoxicity is considered a confounding factor of in vitro test systems, we also examined, within the Pfizer data set, the influence of cytotoxicity in the CBMN assay, and the results indicated that seemingly low (<50%) or excessively high (>70%) levels of cytotoxicity did not significantly alter predicted CA outcome. These collective analyses contribute to growing evidence that the CBMN assay is a suitable regulatory option in the standard battery of genetic toxicology tests.

Improving dose selection and identification of aneugens in the in vitro chromosome aberration test by integration of flow cytometry-based methods.

Previously, this laboratory reported on the development of a flow cytometry-based method that automates the assessment of the mitotic index (MI) and numerical chromosome changes in chemically treated cultures of human lymphocytes [Muehlbauer PA and Schuler MJ, 2003, 2005]. With this method, testing design can easily include numerous well-spaced doses to better define the shape of MI dose response curves. In addition, the hypodiploid, hyperdiploid, and polyploid mitotic populations are available simultaneously to determine the biological relevance of polyploidy effects during the conduct of the assay. The current work describes the integration of this flow cytometry-based method into the routine conduct of good laboratory practice structural chromosome aberration assays in vitro, and discusses improvements in evaluating cytotoxicity and polyploidy endpoints. Additional methods for simultaneous assessment of cell death (sub-G1 DNA) are shown in combination with the MI to provide a more complete evaluation of cytotoxic conditions. A total of 30 pharmaceutical compounds were assayed in compliance with Organization for Economic Cooperation and Development and International Conference on Harmonization guidelines. The inclusion of numerous well-spaced doses improved high dose selection and resulted in fewer high dose artifacts. Only 1 compound in 30 produced a positive response in structural aberrations. In comparison, polyploidy induction was observed in 22 of 30 (73%) compounds, with no apparent increases in numerical chromosomal aberrations. These studies show that flow cytometry-based methods can be used to better characterize cytotoxicity dose-response relationships and improve the detection of aneugens.