Design of a phase 0 microdosing trial for correlation of platinum-induced DNA damage to chemotherapy outcomes

Abstract

2543 Background: DNA damage is the critical step in cancer cell response to platinum (Pt) chemotherapy. We hypothesize that low levels of Pt-induced DNA damage are predictive of chemoresistance. Accelerator mass spectrometry (AMS), an ultrasensitive method for measuring radiocarbon, can detect [14C]carboplatin bound to the DNA of cancer cells from cell culture, mice bearing tumor xenografts and patients receiving subtoxic microdoses of compound. Methods: Cancer cells and mice bearing tumor xenografts were treated with one microdose (1/100th of the therapeutic dose) or one therapeutic dose of [14C]carboplatin. Relevant parameters such as drug influx/efflux, intracellular drug inactivation, DNA damage and repair, were measured and correlated with response to chemotherapy. A Phase 0 microdosing trial has been designed to study patients with non-small cell lung or bladder transitional cell cancers who are planning to receive Pt-based chemotherapy. One microdose of [14C]carboplatin is administered to these patients 4 hours before biopsy. Pt-induced DNA damage and repair in tumor biopsy specimens and other relevant parameters will be measured and correlated with the response and toxicity of chemotherapy. Results: Preclinical studies showed that AMS can detect Pt-DNA damage when cancer cells and mice with tumor xenografts are exposed to one microdose of [14C]carboplatin. The levels of microdose-induced DNA damage are directly proportional to the damage caused by a therapeutic drug dose (p<0.001); and these levels of DNA damage correlate with chemoresistance as measured by MTT assay. Measuring drug uptake/efflux and intracellular inactivation allows insights into resistance mechanisms. These data support the conclusion that the levels of DNA damage induced by microdosing can potentially predict chemoresistance in patients. Consequently, a Phase 0 microdosing trial is in progress. Conclusions: These results support a phase 0 microdosing trial employing AMS to identify chemoresistance and determine the underlying chemoresistant mechanisms for personalized therapy before patients receive cytotoxic chemotherapy. [Table: see text]