Chemotherapy for advanced ovarian cancer remains suboptimal. Despite the improvements in objective response rates realized with cisplatin-based combination chemotherapeutic regimens, most patients still die of refractory cancer. Drug resistance has emerged as the single most important determinant of treatment outcome. Laboratory studies have provided substantial insights into the cellular mechanisms of resistance to the commonly used chemotherapeutic agents. Decreased drug accumulation, metabolic drug inactivation, and repair or tolerance to drug-induced cellular injury all contribute to resistance at the cellular level. Identification of these mechanisms has facilitated the development of specific treatment strategies, many of which are in or nearing clinical trials. These strategies include dose intensification, inhibition of P-glycoprotein function, inhibition of cellular glutathione synthesis, and inhibition of cellular DNA repair. The initial results from clinical trials that use these strategies provide reasonable grounds for optimism. In addition, efforts to identify new drugs with activity against resistant cells continue. One such drug, taxol, has significant activity in tumors refractory to conventional therapy. These approaches offer hope that intensive laboratory and clinical efforts ultimately will translate into real improvements in the efficacy of chemotherapy for ovarian cancer. Cancer 1993; 71:1571-80.
Resistance to chemotherapy is, perhaps, the most important therapeutic problem in medical oncology. Nearly 50% of all patients with cancer have malignancies that are intrinsically resistant to chemotherapy. In a sizable percentage of the remaining patients, their tumors develop or "acquire" resistance during the course of their treatment despite being initially responsive to