The future of advanced prostate cancer treatment may involve combining ADCs with bispecific T-cell engagers. This strategy could use ADCs for a short duration to deliver a potent hit, followed by immunotherapy to achieve durable remission, potentially reducing toxicity and enabling earlier use.

Unlike bladder cancer, prostate cancer has highly effective androgen-pathway inhibitors (ARPIs) that extend survival. This success has pushed chemotherapy and, by extension, ADC development to later treatment lines as clinicians prioritize other novel mechanisms of action first.

For antibody-drug conjugates (ADCs) to make a meaningful impact in prostate cancer, the clinical development bar is exceptionally high. Merely showing activity in late-line settings is insufficient; the true measure of success is demonstrating superiority over the established chemotherapy standard, docetaxel.

The future of medicine isn't about finding a single 'best' modality like CAR-T or gene therapy. Instead, it's about strategic convergence, choosing the right tool—be it a bispecific, ADC, or another biologic—based on the patient's specific disease stage and urgency of treatment.

Experts question the efficacy of sequencing ADCs like EV (Nectin-4 target) and DV (HER2 target) because they share the same MMAE chemo payload. Since resistance is often tied to the payload, not the target antibody, switching targets may not overcome resistance, though anecdotal responses have been observed.

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.

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.

Experts question if HER2 status truly predicts ADC efficacy in urothelial cancer. The benefit seen across low-expression levels suggests HER2's main role may be simply to target the chemo payload to cancer cells, rather than indicating a specific biological dependency.

A single degrader molecule can destroy thousands of target proteins per hour, a massive improvement over the 1-to-1 stoichiometry of traditional inhibitors. This extreme potency makes them ideal payloads for Degrader-Antibody Conjugates (DACs), combining the precision of antibodies with the power of catalytic degradation.