The introduction of ADCs into frontline ovarian cancer treatment creates a new challenge: conflicting biomarkers. A patient's tumor might be positive for both HER2 (an ADC target) and a BRCA mutation (a PARP inhibitor target), forcing clinicians to choose between two effective targeted therapies without clear guidance.

A novel strategy involves combining antibody-drug conjugates (ADCs) with PARP inhibitors. This approach could potentially overcome the need for a germline BRCA mutation, significantly broadening the patient population that could benefit from PARP inhibitor therapy in triple-negative breast cancer.

While platinum chemotherapy is considered the standard treatment after a patient progresses on a first-line ADC-IO combination, experts admit this is a standard "based on nothing." There is no clinical trial data to prove its efficacy in this specific setting; it serves only as a placeholder for new clinical trials.

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.

Real-world data suggests that using one antibody-drug conjugate (ADC) immediately after another is often ineffective. A potential strategy to overcome this resistance is to administer a different class of chemotherapy before starting the second ADC.

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.

Rather than moving through distinct lines of therapy, a future strategy could involve an "ADC switch." When a patient progresses on an ADC-IO combination, the IO backbone would remain while the ADC is swapped for one with a different, non-cross-resistant mechanism, adapting the treatment in real-time.

As multiple effective Antibody-Drug Conjugates (ADCs) become available, the primary clinical challenge is no longer *if* they work, but *how* to use them best. Key unanswered questions involve optimal sequencing, dosing for treatment versus maintenance, and overall length of therapy, mirroring issues already seen in breast cancer.