Historically, double-stranded (ds) RNAs have been largely over-looked as potentially valuable anticancer/antiviral drugs, primarily because of the many clinical toxicities and lack of efficacy associated with the first clinically tested dsRNA--polyinosinic-polycytidylic acid (rIn X rCn). However, studies summarized herein demonstrate that the therapeutic ratio of dsRNAs can be greatly enhanced by purposeful mispairing of bases. For example, a mispaired dsRNA, termed Ampligen (rIn X r(C12,U)n), shows strong antitumor activity in a variety of relevant test systems with little or none of the toxicities associated with rIn X rCn. Furthermore, Ampligen demonstrates a much wider therapeutic spectrum than that displayed to date by any single type of interferon (natural or recombinant DNA-derived). Importantly, Ampligen, the product of a straight-forward enzymatic synthesis, shows excellent lot-to-lot biological and biophysical specifications, which is often not the case with biologically derived new compounds. Furthermore, a significant fraction of human solid tumors, which are largely unresponsive to conventional chemotherapy or interferon (IFN), is sensitive to Ampligen in a fresh human tumor clonogenic assay. Indeed, whereas 50% of untreated and IFN-treated athymic mice engrafted with human renal cancer cells die within 20-22 weeks, mice treated with Ampligen survive a minimum of 32 weeks (p less than 0.0003). A summary of all animal models tested and human clinical trials to date demonstrates that Ampligen exerts a greater antitumor activity than IFN and has a superior therapeutic ratio compared to rIn X rCn.