The treatment landscape for platinum-resistant ovarian cancer has rapidly evolved into a biomarker-driven paradigm. Clinicians must now test for and choose between therapies targeting distinct markers like folate receptor alpha (mirvetuximab), HER2 (T-DXd), and PD-L1 (pembrolizumab), requiring a sophisticated sequencing strategy.

The traditional six-month timeframe for defining platinum sensitivity is being challenged. A growing theory suggests that tumors progressing while on a PARP inhibitor have a distinct biology that responds poorly to subsequent platinum, indicating a potential need to move directly to therapies like ADCs.

The traditional practice of classifying recurrent ovarian cancer as 'platinum-sensitive' or 'platinum-resistant' based on a six-month treatment-free interval is rapidly becoming obsolete. The introduction of maintenance therapies like PARP inhibitors is changing tumor biology and response patterns, suggesting this simple time-based distinction no longer adequately reflects the clinical reality.

Real-world data shows that in platinum-sensitive ovarian cancer patients who have progressed on PARP inhibitors, subsequent platinum-based chemotherapy has a surprisingly low response rate of only 20%. This quantifies a significant opportunity for highly active ADCs to potentially replace platinum in this growing patient population.

The modest benefit of PARP inhibitors in metastatic breast cancer, compared to ovarian cancer, is likely due to resistance induced by prior exposure to DNA-damaging agents like anthracyclines. This explains the clinical rationale for moving PARP inhibitors to earlier treatment settings, such as neoadjuvant or adjuvant therapy, before resistance develops.

The selection between PARP inhibitors like olaparib and niraparib is not one-size-fits-all. It's a personalized decision based on patient preference for dosing frequency (once vs. twice daily), tolerance for side effects like hypertension, and potential drug-drug interactions.

A new wave of antibody-drug conjugates (ADCs) is transforming ovarian cancer treatment. These 'heat-seeking missiles' deliver potent chemotherapy payloads directly to tumor cells, achieving response rates from 23% to over 60% in biomarker-selected populations. This far surpasses the efficacy of conventional chemotherapy in resistant settings.

The development of PARP-1 selective inhibitors like seriparib signals a shift in drug innovation. Instead of only chasing higher efficacy, these new agents aim for a more favorable toxicity profile (less GI toxicity, fewer dose discontinuations) to improve patient quality of life and treatment adherence.

Historically, therapies for platinum-resistant ovarian cancer were so ineffective that the order of administration was irrelevant. With the advent of multiple active ADCs, the concept of treatment sequencing and potential cross-resistance based on payloads or targets has become a critical, and entirely new, clinical consideration for this disease.