Correlation of chemical structure with reproductive and developmental toxicity as it relates to the use of the threshold of toxicological concern.

In the absence of toxicological data on a chemical, the threshold of toxicological concern (TTC) approach provides a system to estimate a conservative exposure below which there is a low probability of risk for adverse health effects. The original toxicology dataset underlying the TTC was based on NOELs from repeat dose studies. Subsequently there have been several efforts to assess whether or not these limits are also protective for reproductive/developmental effects. This work expands the database of chemicals with reproductive and developmental data, presents these data in a comprehensive and transparent format and groups the chemicals according to the TTC "Cramer Class" rules. Distributions of NOAELs from each of these classes were used to assess whether the previously proposed TTC values based on repeat dose data are protective for reproductive/developmental toxicity endpoints as well. The present analysis indicates that, for each Cramer Class, the reproductive and developmental endpoints would be protected at the corresponding general TTC tiers derived by Munro et al. (1996).

Development of an ultraperformance liquid chromatography/mass spectrometry method to quantify cisplatin 1,2 intrastrand guanine-guanine adducts.

Platinum chemotherapeutic agents have been widely used in the treatment of cancer. Cisplatin was the first of the platinum-based chemotherapeutic agents and therefore has been extensively studied as an antitumor agent since the late 1960s. Because this agent forms several DNA adducts, a highly sensitive and specific quantitative assay is needed to correlate the molecular dose of individual adducts with the effects of treatment. An ultraperformance liquid chromatography tandem mass spectrometry (UPLC-MS/MS) assay for quantification of 1,2 guanine-guanine intrastrand cisplatin adducts [CP-d(GpG)], using (15)N(10) CP-d(GpG) as an internal standard, was developed. The internal standard was characterized by MS/MS, and its concentration was validated by inductively coupled plasma mass spectrometry. Samples containing CP-d(GpG) in DNA were purified by enzyme hydrolysis, centrifugal filtration, and HPLC with fraction collection prior to quantification by UPLC-MS/MS in the selective reaction monitoring mode [m/z 412.5-->248.1 for CP-d(GpG); m/z 417.5-->253.1 for [(15)N(10)] CP-d(GpG)]. The recovery of standards was >90%, and quantification was unaffected by increasing concentrations of calf thymus DNA. This method utilizes 25 mug of DNA per injection. The limit of quantification was 3 fmol or 3.7 adducts per 10(8) nucleotides, which approaches the sensitivity of the (32)P postlabeling method for this adduct. These data suggested that this method is suitable for in vitro and in vivo assessment of CP-d(GpG) adducts formed by cisplatin and carboplatin. Subsequently, the method was applied to studies using ovarian carcinoma cell lines and C57/BL6 mice to illustrate that this method is capable of quantifying CP-d(GpG) adducts using biologically relevant systems and doses. The development of biomarkers to determine tissue-specific molecular dosimetry during treatment will lead to a more complete understanding of both therapeutic and adverse effects of cisplatin and carboplatin. This will support the refinement of therapeutic regimes and appropriate individualized treatment protocols.