Even within a single patient, tumor lesions exhibit significant heterogeneity in PSMA expression, with some being "hot" and others "not." This ensures that a standard dose of radioligand therapy will not be delivered uniformly across all disease sites, creating an inherent mechanism for resistance and incomplete response.

Data from a novel Nectin-4 ADC trial showed zero responses in patients with prior topoisomerase therapy. This strongly suggests that payload resistance, not just the ADC target, is a critical mechanism that will dictate future treatment sequencing.

The future of advanced prostate cancer treatment is shifting towards therapies that target cell surface markers. This new era will be defined by a growing arsenal of radioligands, T-cell engaging bispecific antibodies (BiTEs), and antibody-drug conjugates (ADCs) aimed at targets like PSMA, B7-H3, and HK2.

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.

The primary reason Antibody-Drug Conjugates (ADCs) stop working is payload resistance, a shift from the traditional belief that failure stems from tumors losing the target antigen. This insight drives development of multi-payload ADCs to overcome this resistance mechanism.

Even when an ARPI is no longer effective as a standalone therapy, continuing it may be beneficial. By maintaining pressure on the androgen receptor pathway, the drug can upregulate downstream targets like PSMA, potentially enhancing the efficacy of subsequent PSMA-targeted therapies like radioligands or ADCs.

When sequencing antibody-drug conjugates (ADCs) for SCLC, resistance may be driven more by the cytotoxic payload (e.g., a topoisomerase 1 inhibitor) than the antibody's target antigen. This suggests prior exposure to a similar payload class could predict non-response, even when using an ADC with a different target.

Unlike chemotherapy, radioligand therapy's effectiveness wanes as tumors shrink. With less PSMA target for the drug to bind to, less radiation is delivered to the cancer. This physical reality supports "adaptive dosing"—stopping treatment in high-responders to spare healthy tissue and resume later if needed.

An antibody-drug conjugate's (ADC) effectiveness is capped by its chemotherapy payload. In prostate cancer, topoisomerase inhibitors have a poor track record. Therefore, ADCs using this payload face an uphill battle compared to those with proven payloads like microtubule inhibitors (taxanes).