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 B96 trial's potential approval for platinum-resistant ovarian cancer introduces a new treatment sequencing challenge. Clinicians must decide between this immunotherapy combination and the ADC mervituximab, which has a clear biomarker (foliate receptor alpha). The lack of a reliable biomarker for the B96 regimen complicates this decision-making process for patients.

A "tsunami" of antibody-drug conjugates (ADCs) are in development for ovarian cancer, but many share the same TOP1 inhibitor payload. This creates a significant future clinical challenge: after a patient progresses on one such ADC, it is unknown if another with the same payload will be effective, creating an urgent need for sequencing data.

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.

Unlike early ADCs requiring high biomarker expression (e.g., mirvetuximab), next-generation agents show efficacy even in low-expressing tumors. This allows for broader, "all-comer" clinical trial inclusion criteria instead of biomarker-gated entry, potentially expanding patient access to these novel therapies.

The ADC mirvetuximab is the first drug to demonstrate an overall survival benefit for platinum-resistant ovarian cancer. This groundbreaking result establishes a higher efficacy standard that subsequent therapies will likely need to meet for regulatory approval and clinical adoption, raising the bar for future drug development.

To mitigate the severe toxicity of promising pan-RAS inhibitors, companies are adopting antibody-drug conjugate (ADC) technology. This marks a strategic expansion for ADCs, moving beyond traditional cytotoxic chemotherapy payloads to delivering highly specific targeted therapies, aiming to improve the therapeutic window of potent new drug classes.

Patients whose ovarian cancer progresses on the folate-targeted ADC mirvetuximab may still respond to a subsequent folate-targeted ADC with a different cytotoxic payload. This suggests that the folate receptor alpha target remains viable and that resistance may be payload-specific, opening new sequencing strategies.

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.