The concept of bioreductive alkylation as a mechanism of action of quinone-containing anticancer agents was investigated, using electrochemical techniques. According to this concept, an electrochemical step (reduction of the quinone ring) is followed by one or more chemical steps, leading to formation of the actual alkylating species. The proper use of electrochemical analysis of potential bioreductive alkylating quinones in the design of new analogs is limited. Up to now, the only electrochemical parameter frequently used in structure-activity relationship studies, is the half-wave potential of the quinone reduction. However, reliable information can only be obtained from the found value of this parameter when the reduction mechanism has been elucidated. Furthermore, it only gives information about the first step of the model. More detailed electrochemical analysis of potential bioreductive alkylating quinones, in combination with a biological evaluation, is required to gain more insight in their mechanism of action and to yield quantitative information about substituent effects on both the electrochemical and the chemical step(s) of the model. Results of such studies of a series of aziridinylquinones indicate, that the biological activity in vitro is correlated with the ease of protonation of the aziridines after quinone reduction, which is in accordance with the concept of bioreductive activation. No correlation with the ease of protonation of the aziridines prior to quinone reduction or with the quinone reduction step itself can be found.