Radiation-activated prodrugs as hypoxia-selective cytotoxins: model studies with nitroarylmethyl quaternary salts.

Bioreductive drugs are designed to be activated by enzymatic reduction in hypoxic regions of tumours, but activation of these drugs is not always fully suppressed by oxygen in normal tissues. A further limitation is that bioreductive drug activation depends on suitable reductases being expressed in the hypoxic zone. This essay proposes an alternative approach in which prodrugs are reduced, and thereby activated, in hypoxic regions by ionizing radiation rather than by enzymes. This strategy is theoretically attractive, but design requirements for such radiation-activated cytotoxins are challenging. In particular, the reducing capacity of radiation at clinically relevant doses is small, which necessitates the development of prodrugs capable of releasing very potent cytotoxins efficiently in hypoxic tissue. It is shown that nitroarylmethyl quaternary (NMQ) salts possess many of the features required of a radiation-activated prodrug. In some heterocyclic NMQ compounds the cytotoxicity of the latent cytotoxic amine effector is suppressed by > 100-fold in the prodrug form, and the effector is released rapidly by fragmentation following reduction by a single electron. Appreciable cytotoxic activation of NMQ prodrugs can be achieved by irradiation at clinically relevant doses in anoxic plasma. Some of the further drug design challenges required to develop a clinical agent based on this approach are outlined.